ZunZunSite3 Curve Fitting and Surface Fitting

ZunZunSite3 List Of All 2D Equations

2D Astrophysics

King 14 With Exponential Decay And Offset 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) / exp(x) + Offset [web citation]
King 14 With Exponential Decay 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) / exp(x) [web citation]



King 14 With Exponential Growth And Offset 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) * exp(x) + Offset [web citation]



King 14 With Exponential Growth 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) * exp(x) [web citation]



King 14 With Linear Decay And Offset 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) / x + Offset [web citation]



King 14 With Linear Decay 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) / x [web citation]



King 14 With Linear Growth And Offset 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) * x + Offset [web citation]



King 14 With Linear Growth 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 f(x) = f(x) * x [web citation]



King 14 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 [web citation]



King 14 With Offset 2D		f(x) = k * [1/sqrt(1 + (x/r_c) 2) - 1/sqrt(1 + (r_t/r_c) 2)] ** 2 + Offset [web citation]

2D BioScience

Aphid Population Growth With Exponential Decay And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) / exp(x) + Offset [web citation]
Beverton-Holt A With Exponential Decay And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y / exp(x) + Offset
Beverton-Holt B With Exponential Decay And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y / exp(x) + Offset
BioScience A With Exponential Decay And Offset 2D		y = a * (1.0 - (b * c^x)) y = y / exp(x) + Offset
BioScience B With Exponential Decay And Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y / exp(x) + Offset
Cellular Conductance With Exponential Decay And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g / (g exp(x)) + Offset [web citation]
Derek Duncan Custom Equation With Exponential Decay And Offset 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = y / exp(x) + Offset
Generalized Negative Exponential With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y / exp(x) + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Decay And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (f * exp(x)) + Offset
High-Low Affinity Double With Exponential Decay And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (f * exp(x)) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Decay And Offset 2D		y = ab / (1+bx) y = y / exp(x) + Offset
High-Low Affinity With Exponential Decay And Offset 2D		y = abx / (1+bx) y = y / exp(x) + Offset
Hyperbolic A With Exponential Decay And Offset 2D		y = (a + x) / (b + x) y = y / (c * exp(x)) + Offset
Hyperbolic B With Exponential Decay And Offset 2D		y = (a + bx) / (c + x) y = y / (d * exp(x)) + Offset
Hyperbolic C With Exponential Decay And Offset 2D		y = (a + x) / (b + cx) y = y / (d * exp(x)) + Offset
Hyperbolic D With Exponential Decay And Offset 2D		y = (a + bx) / (c + dx) y = y / (f * exp(x)) + Offset
Hyperbolic E With Exponential Decay And Offset 2D		y = ax / (b + x) y = y / exp(x) + Offset
Hyperbolic F With Exponential Decay And Offset 2D		y = ax / (b + x) + cx y = y / (d * exp(x)) + Offset
Hyperbolic G With Exponential Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * exp(x)) + Offset
Hyperbolic H With Exponential Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (g * exp(x)) + Offset
Hyperbolic I With Exponential Decay And Offset 2D		y = ab / (b + x) y = y / exp(x) + Offset
Hyperbolic J With Exponential Decay And Offset 2D		y = x / (a + bx) y = y / (c * exp(x)) + Offset
Hyperbolic Logistic With Exponential Decay And Offset 2D		y = ax^b / (c + x^b) y = y / exp(x) + Offset
Jorge Rabinovich Population Growth With Exponential Decay And Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y / (d exp(x)) + Offset
Membrane Transport With Exponential Decay And Offset 2D		y = a(x-b) / (x² + cx + d) y = y / exp(x) + Offset
Michaelis-Menten Double With Exponential Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * exp(x)) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Decay And Offset 2D		y = a / (b + x) y = y / exp(x) + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Decay And Offset 2D		y = a / (b + x) + c / (d + x) y = y / (f * exp(x)) + Offset
Michaelis-Menten Product Accumulation With Exponential Decay And Offset 2D		y = a(b-x) / (c + (b-x)) y = y / exp(x) + Offset
Michaelis-Menten With Exponential Decay And Offset 2D		y = ax / (b + x) y = y / exp(x) + Offset
Negative Exponential With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x) + Offset
Plant Disease Exponential Model With Exponential Decay And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / exp(x) + Offset [web citation]
Plant Disease Gompertz Model With Exponential Decay And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (c * exp(x)) + Offset [web citation]
Plant Disease Logistic Model With Exponential Decay And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (c * exp(x)) + Offset [web citation]
Plant Disease Monomolecular Model With Exponential Decay And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (c * exp(x)) + Offset [web citation]
Plant Disease Weibull Model Scaled With Exponential Decay And Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y / exp(x) + Offset [web citation]
Plant Disease Weibull Model With Exponential Decay And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence / (d * exp(x)) + Offset [web citation]
Scaled Log Transform With Exponential Decay And Offset 2D		y = a * log(bx + c) y = y / exp(x) + Offset
Scaled Log With Exponential Decay And Offset 2D		y = a * log(x) y = y / exp(x) + Offset
Scaled Power Transform With Exponential Decay And Offset 2D		y = a * (cx + d)^b y = y / exp(x) + Offset
Scaled Power With Exponential Decay And Offset 2D		y = a * x^b y = y / exp(x) + Offset
Weibull With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y / exp(x) + Offset
Xiaogang Peng Immunoassay With Exponential Decay And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / exp(x) + Offset
von Bertalanffy Growth With Exponential Decay And Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) / exp(x) + Offset



Aphid Population Growth With Exponential Decay 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) / exp(x) [web citation]
Beverton-Holt A With Exponential Decay 2D		y = r / (1 + ((r-1)/K) * x) y = y / exp(x)
Beverton-Holt B With Exponential Decay 2D		y = rx / (1 + ((r-1)/K) * x) y = y / exp(x)
BioScience A With Exponential Decay 2D		y = a * (1.0 - (b * c^x)) y = y / exp(x)
BioScience B With Exponential Decay 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y / exp(x)
Cellular Conductance With Exponential Decay 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g / (g exp(x)) [web citation]
Derek Duncan Custom Equation With Exponential Decay 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = y / exp(x)
Dose-Response A With Exponential Decay 2D		y = b + (a-b) / (1 + 10^x-c) y = y / (d * exp(x))
Dose-Response B With Exponential Decay 2D		y = b + (a-b) / (1 + 10^c-x) y = y / (d * exp(x))
Dose-Response C With Exponential Decay 2D		y = b + (a-b) / (1 + 10^d(x-c)) y = y / (f exp(x))
Dose-Response D With Exponential Decay 2D		y = b + (a-b) / (1 + 10^d(c-x)) y = y / (f exp(x))
Dose-Response E With Exponential Decay 2D		y = b + (a-b) / (1 + (x/c)^d) y = y / (f * exp(x))
Generalized Negative Exponential With Exponential Decay 2D		y = a * (1.0 - exp(-bx))^c y = y / exp(x)
Generalized Product Accumulation With Exponential Decay 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y / (g * exp(x))
Generalized Substrate Depletion With Exponential Decay 2D		y = ax / (b + x) - cx - d y = y / (f * exp(x))
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Decay 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (f * exp(x))
High-Low Affinity Double With Exponential Decay 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (f * exp(x))
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Decay 2D		y = ab / (1+bx) y = y / exp(x)
High-Low Affinity With Exponential Decay 2D		y = abx / (1+bx) y = y / exp(x)
Hyperbolic A With Exponential Decay 2D		y = (a + x) / (b + x) y = y / (c * exp(x))
Hyperbolic B With Exponential Decay 2D		y = (a + bx) / (c + x) y = y / (d * exp(x))
Hyperbolic C With Exponential Decay 2D		y = (a + x) / (b + cx) y = y / (d * exp(x))
Hyperbolic D With Exponential Decay 2D		y = (a + bx) / (c + dx) y = y / (f * exp(x))
Hyperbolic E With Exponential Decay 2D		y = ax / (b + x) y = y / exp(x)
Hyperbolic F With Exponential Decay 2D		y = ax / (b + x) + cx y = y / (d * exp(x))
Hyperbolic G With Exponential Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * exp(x))
Hyperbolic H With Exponential Decay 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (g * exp(x))
Hyperbolic I With Exponential Decay 2D		y = ab / (b + x) y = y / exp(x)
Hyperbolic J With Exponential Decay 2D		y = x / (a + bx) y = y / (c * exp(x))
Hyperbolic Logistic With Exponential Decay 2D		y = ax^b / (c + x^b) y = y / exp(x)
Jorge Rabinovich Population Growth With Exponential Decay 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y / (d exp(x))
Membrane Transport With Exponential Decay 2D		y = a(x-b) / (x² + cx + d) y = y / exp(x)
Michaelis-Menten Double With Exponential Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * exp(x))
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Decay 2D		y = a / (b + x) y = y / exp(x)
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Decay 2D		y = a / (b + x) + c / (d + x) y = y / (f * exp(x))
Michaelis-Menten Product Accumulation With Exponential Decay 2D		y = a(b-x) / (c + (b-x)) y = y / exp(x)
Michaelis-Menten With Exponential Decay 2D		y = ax / (b + x) y = y / exp(x)
Negative Exponential With Exponential Decay 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x)
New Zealand Ecology Logistic 1 With Exponential Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3))) n = n / (f * exp(x))
New Zealand Ecology Logistic 2 With Exponential Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3))) n = n / (g * exp(x))
Plant Disease Exponential Model With Exponential Decay 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / exp(x) [web citation]
Plant Disease Gompertz Model With Exponential Decay 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (c * exp(x)) [web citation]
Plant Disease Logistic Model With Exponential Decay 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (c * exp(x)) [web citation]
Plant Disease Monomolecular Model With Exponential Decay 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (c * exp(x)) [web citation]
Plant Disease Weibull Model Scaled With Exponential Decay 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y / exp(x) [web citation]
Plant Disease Weibull Model With Exponential Decay 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence / (d * exp(x)) [web citation]
Preece And Baines Growth With Exponential Decay 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y / (g * exp(x))
Scaled Log Transform With Exponential Decay 2D		y = a * log(bx + c) y = y / exp(x)
Scaled Log With Exponential Decay 2D		y = a * log(x) y = y / exp(x)
Scaled Power Transform With Exponential Decay 2D		y = a * (cx + d)^b y = y / exp(x)
Scaled Power With Exponential Decay 2D		y = a * x^b y = y / exp(x)
Standard 3-Parameter Logistic Equation With Exponential Decay 2D		y = d + (a - d) / (1 + (x / c)) y = y / (d * exp(x))
Standard 4-Parameter Logistic Equation With Exponential Decay 2D		y = d + (a - d) / (1 + (x / c)^b) y = y / (f * exp(x))
Standard 5-Parameter Logistic Equation With Exponential Decay 2D		y = d + (a - d) / (1 + (x / c)^b )^f y = y / (g * exp(x))
Weibull With Exponential Decay 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y / exp(x)
Xiaogang Peng Immunoassay With Exponential Decay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / exp(x)
von Bertalanffy Growth With Exponential Decay 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) / exp(x)



Aphid Population Growth With Exponential Growth And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) * exp(x) + Offset [web citation]
Beverton-Holt A With Exponential Growth And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y * exp(x) + Offset
Beverton-Holt B With Exponential Growth And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y * exp(x) + Offset
BioScience A With Exponential Growth And Offset 2D		y = a * (1.0 - (b * c^x)) y = y * exp(x) + Offset
BioScience B With Exponential Growth And Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y * exp(x) + Offset
Cellular Conductance With Exponential Growth And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g (g * exp(x)) + Offset [web citation]
Derek Duncan Custom Equation With Exponential Growth And Offset 2D		y = a / (1 + exp(-1/b(x-c)))^d y = y exp(x) + Offset
Generalized Negative Exponential With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y * exp(x) + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Growth And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (f * exp(x)) + Offset
High-Low Affinity Double With Exponential Growth And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (f * exp(x)) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Growth And Offset 2D		y = ab / (1+bx) y = y * exp(x) + Offset
High-Low Affinity With Exponential Growth And Offset 2D		y = abx / (1+bx) y = y * exp(x) + Offset
Hyperbolic A With Exponential Growth And Offset 2D		y = (a + x) / (b + x) y = y * (c * exp(x)) + Offset
Hyperbolic B With Exponential Growth And Offset 2D		y = (a + bx) / (c + x) y = y * (d * exp(x)) + Offset
Hyperbolic C With Exponential Growth And Offset 2D		y = (a + x) / (b + cx) y = y * (d * exp(x)) + Offset
Hyperbolic D With Exponential Growth And Offset 2D		y = (a + bx) / (c + dx) y = y * (f * exp(x)) + Offset
Hyperbolic E With Exponential Growth And Offset 2D		y = ax / (b + x) y = y * exp(x) + Offset
Hyperbolic F With Exponential Growth And Offset 2D		y = ax / (b + x) + cx y = y * (d * exp(x)) + Offset
Hyperbolic G With Exponential Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * exp(x)) + Offset
Hyperbolic H With Exponential Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (g * exp(x)) + Offset
Hyperbolic I With Exponential Growth And Offset 2D		y = ab / (b + x) y = y * exp(x) + Offset
Hyperbolic J With Exponential Growth And Offset 2D		y = x / (a + bx) y = y * (c * exp(x)) + Offset
Hyperbolic Logistic With Exponential Growth And Offset 2D		y = ax^b / (c + x^b) y = y * exp(x) + Offset
Jorge Rabinovich Population Growth With Exponential Growth And Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y (d * exp(x)) + Offset
Membrane Transport With Exponential Growth And Offset 2D		y = a(x-b) / (x² + cx + d) y = y * exp(x) + Offset
Michaelis-Menten Double With Exponential Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * exp(x)) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Growth And Offset 2D		y = a / (b + x) y = y * exp(x) + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Growth And Offset 2D		y = a / (b + x) + c / (d + x) y = y * (f * exp(x)) + Offset
Michaelis-Menten Product Accumulation With Exponential Growth And Offset 2D		y = a(b-x) / (c + (b-x)) y = y * exp(x) + Offset
Michaelis-Menten With Exponential Growth And Offset 2D		y = ax / (b + x) y = y * exp(x) + Offset
Negative Exponential With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x) + Offset
Plant Disease Exponential Model With Exponential Growth And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * exp(x) + Offset [web citation]
Plant Disease Gompertz Model With Exponential Growth And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (c * exp(x)) + Offset [web citation]
Plant Disease Logistic Model With Exponential Growth And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (c * exp(x)) + Offset [web citation]
Plant Disease Monomolecular Model With Exponential Growth And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (c * exp(x)) + Offset [web citation]
Plant Disease Weibull Model Scaled With Exponential Growth And Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y * exp(x) + Offset [web citation]
Plant Disease Weibull Model With Exponential Growth And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence * (d * exp(x)) + Offset [web citation]
Scaled Log Transform With Exponential Growth And Offset 2D		y = a * log(bx + c) y = y * exp(x) + Offset
Scaled Log With Exponential Growth And Offset 2D		y = a * log(x) y = y * exp(x) + Offset
Scaled Power Transform With Exponential Growth And Offset 2D		y = a * (cx + d)^b y = y * exp(x) + Offset
Scaled Power With Exponential Growth And Offset 2D		y = a * x^b y = y * exp(x) + Offset
Weibull With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y * exp(x) + Offset
Xiaogang Peng Immunoassay With Exponential Growth And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * exp(x) + Offset
von Bertalanffy Growth With Exponential Growth And Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) * exp(x) + Offset



Aphid Population Growth With Exponential Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) * exp(x) [web citation]
Beverton-Holt A With Exponential Growth 2D		y = r / (1 + ((r-1)/K) * x) y = y * exp(x)
Beverton-Holt B With Exponential Growth 2D		y = rx / (1 + ((r-1)/K) * x) y = y * exp(x)
BioScience A With Exponential Growth 2D		y = a * (1.0 - (b * c^x)) y = y * exp(x)
BioScience B With Exponential Growth 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y * exp(x)
Cellular Conductance With Exponential Growth 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g (g * exp(x)) [web citation]
Derek Duncan Custom Equation With Exponential Growth 2D		y = a / (1 + exp(-1/b(x-c)))^d y = y exp(x)
Dose-Response A With Exponential Growth 2D		y = b + (a-b) / (1 + 10^x-c) y = y * (d * exp(x))
Dose-Response B With Exponential Growth 2D		y = b + (a-b) / (1 + 10^c-x) y = y * (d * exp(x))
Dose-Response C With Exponential Growth 2D		y = b + (a-b) / (1 + 10^d(x-c)) y = y (f * exp(x))
Dose-Response D With Exponential Growth 2D		y = b + (a-b) / (1 + 10^d(c-x)) y = y (f * exp(x))
Dose-Response E With Exponential Growth 2D		y = b + (a-b) / (1 + (x/c)^d) y = y * (f * exp(x))
Generalized Negative Exponential With Exponential Growth 2D		y = a * (1.0 - exp(-bx))^c y = y * exp(x)
Generalized Product Accumulation With Exponential Growth 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y * (g * exp(x))
Generalized Substrate Depletion With Exponential Growth 2D		y = ax / (b + x) - cx - d y = y * (f * exp(x))
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Growth 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (f * exp(x))
High-Low Affinity Double With Exponential Growth 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (f * exp(x))
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Growth 2D		y = ab / (1+bx) y = y * exp(x)
High-Low Affinity With Exponential Growth 2D		y = abx / (1+bx) y = y * exp(x)
Hyperbolic A With Exponential Growth 2D		y = (a + x) / (b + x) y = y * (c * exp(x))
Hyperbolic B With Exponential Growth 2D		y = (a + bx) / (c + x) y = y * (d * exp(x))
Hyperbolic C With Exponential Growth 2D		y = (a + x) / (b + cx) y = y * (d * exp(x))
Hyperbolic D With Exponential Growth 2D		y = (a + bx) / (c + dx) y = y * (f * exp(x))
Hyperbolic E With Exponential Growth 2D		y = ax / (b + x) y = y * exp(x)
Hyperbolic F With Exponential Growth 2D		y = ax / (b + x) + cx y = y * (d * exp(x))
Hyperbolic G With Exponential Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * exp(x))
Hyperbolic H With Exponential Growth 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (g * exp(x))
Hyperbolic I With Exponential Growth 2D		y = ab / (b + x) y = y * exp(x)
Hyperbolic J With Exponential Growth 2D		y = x / (a + bx) y = y * (c * exp(x))
Hyperbolic Logistic With Exponential Growth 2D		y = ax^b / (c + x^b) y = y * exp(x)
Jorge Rabinovich Population Growth With Exponential Growth 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y (d * exp(x))
Membrane Transport With Exponential Growth 2D		y = a(x-b) / (x² + cx + d) y = y * exp(x)
Michaelis-Menten Double With Exponential Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * exp(x))
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Growth 2D		y = a / (b + x) y = y * exp(x)
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Growth 2D		y = a / (b + x) + c / (d + x) y = y * (f * exp(x))
Michaelis-Menten Product Accumulation With Exponential Growth 2D		y = a(b-x) / (c + (b-x)) y = y * exp(x)
Michaelis-Menten With Exponential Growth 2D		y = ax / (b + x) y = y * exp(x)
Negative Exponential With Exponential Growth 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x)
New Zealand Ecology Logistic 1 With Exponential Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3))) n = n * (f * exp(x))
New Zealand Ecology Logistic 2 With Exponential Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3))) n = n * (g * exp(x))
Plant Disease Exponential Model With Exponential Growth 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * exp(x) [web citation]
Plant Disease Gompertz Model With Exponential Growth 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (c * exp(x)) [web citation]
Plant Disease Logistic Model With Exponential Growth 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (c * exp(x)) [web citation]
Plant Disease Monomolecular Model With Exponential Growth 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (c * exp(x)) [web citation]
Plant Disease Weibull Model Scaled With Exponential Growth 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y * exp(x) [web citation]
Plant Disease Weibull Model With Exponential Growth 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence * (d * exp(x)) [web citation]
Preece And Baines Growth With Exponential Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y * (g * exp(x))
Scaled Log Transform With Exponential Growth 2D		y = a * log(bx + c) y = y * exp(x)
Scaled Log With Exponential Growth 2D		y = a * log(x) y = y * exp(x)
Scaled Power Transform With Exponential Growth 2D		y = a * (cx + d)^b y = y * exp(x)
Scaled Power With Exponential Growth 2D		y = a * x^b y = y * exp(x)
Standard 3-Parameter Logistic Equation With Exponential Growth 2D		y = d + (a - d) / (1 + (x / c)) y = y * (d * exp(x))
Standard 4-Parameter Logistic Equation With Exponential Growth 2D		y = d + (a - d) / (1 + (x / c)^b) y = y * (f * exp(x))
Standard 5-Parameter Logistic Equation With Exponential Growth 2D		y = d + (a - d) / (1 + (x / c)^b )^f y = y * (g * exp(x))
Weibull With Exponential Growth 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y * exp(x)
Xiaogang Peng Immunoassay With Exponential Growth 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * exp(x)
von Bertalanffy Growth With Exponential Growth 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) * exp(x)



Inverse Aphid Population Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = x / N(t) [web citation]
Inverse Beverton-Holt A 2D		y = r / (1 + ((r-1)/K) * x) y = x / y
Inverse BioScience A 2D		y = a * (1.0 - (b * c^x)) y = x / y
Inverse BioScience B 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = x / y
Inverse Cellular Conductance 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = x / g [web citation]
Inverse Derek Duncan Custom Equation 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = x / y
Inverse Dose-Response A 2D		y = b + (a-b) / (1 + 10^x-c) y = x / y
Inverse Dose-Response B 2D		y = b + (a-b) / (1 + 10^c-x) y = x / y
Inverse Dose-Response C 2D		y = b + (a-b) / (1 + 10^d*(x-c)) y = x / y
Inverse Dose-Response D 2D		y = b + (a-b) / (1 + 10^d*(c-x)) y = x / y
Inverse Dose-Response E 2D		y = b + (a-b) / (1 + (x/c)^d) y = x / y
Inverse Generalized Negative Exponential 2D		y = a * (1.0 - exp(-bx))^c y = x / y
Inverse Generalized Product Accumulation 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = x / y
Inverse Generalized Substrate Depletion 2D		y = ax / (b + x) - cx - d y = x / y
Inverse High-Low Affinity 2D		y = abx / (1+bx) y = x / y
Inverse High-Low Affinity Double 2D		y = abx / (1+bx) + cdx / (1+dx) y = x / y
Inverse High-Low Affinity Double Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) + cd / (1+dx) y = x / y
Inverse High-Low Affinity Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) y = x / y
Inverse Hyperbolic A 2D		y = (a + x) / (b + x) y = x / y
Inverse Hyperbolic B 2D		y = (a + bx) / (c + x) y = x / y
Inverse Hyperbolic C 2D		y = (a + x) / (b + cx) y = x / y
Inverse Hyperbolic D 2D		y = (a + bx) / (c + dx) y = x / y
Inverse Hyperbolic E 2D		y = ax / (b + x) y = x / y
Inverse Hyperbolic F 2D		y = ax / (b + x) + cx y = x / y
Inverse Hyperbolic G 2D		y = ax / (b + x) + cx / (d + x) y = x / y
Inverse Hyperbolic H 2D		y = ax / (b + x) + cx / (d + x) + fx y = x / y
Inverse Hyperbolic I 2D		y = ab / (b + x) y = x / y
Inverse Hyperbolic Logistic 2D		y = ax^b / (c + x^b) y = x / y
Inverse Jorge Rabinovich Population Growth 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-R*X)) Y = x / Y
Inverse Membrane Transport 2D		y = a(x-b) / (x² + cx + d) y = x / y
Inverse Michaelis-Menten 2D		y = ax / (b + x) y = x / y
Inverse Michaelis-Menten Double 2D		y = ax / (b + x) + cx / (d + x) y = x / y
Inverse Michaelis-Menten Isotope Displacement ([Hot] subsumed) 2D		y = a / (b + x) y = x / y
Inverse Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) 2D		y = a / (b + x) + c / (d + x) y = x / y
Inverse Michaelis-Menten Product Accumulation 2D		y = a(b-x) / (c + (b-x)) y = x / y
Inverse Negative Exponential 2D		y = a * (1.0 - exp(-bx)) y = x / y
Inverse New Zealand Ecology Logistic 1 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3))) n = x / n
Inverse New Zealand Ecology Logistic 2 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3))) n = x / n
Inverse Plant Disease Exponential Model 2D		Incidence = y0 * exp(r * time) Incidence = x / Incidence [web citation]
Inverse Plant Disease Gompertz Model 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = x / Incidence [web citation]
Inverse Plant Disease Logistic Model 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = x / Incidence [web citation]
Inverse Plant Disease Monomolecular Model 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = x / Incidence [web citation]
Inverse Plant Disease Weibull Model 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = x / Incidence [web citation]
Inverse Plant Disease Weibull Model Scaled 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = x / y [web citation]
Inverse Preece And Baines Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = x / y
Inverse Scaled Log 2D		y = a * log(x) y = x / y
Inverse Scaled Log Transform 2D		y = a * log(bx + c) y = x / y
Inverse Scaled Power Transform 2D		y = a * (cx + d)^b y = x / y
Inverse Standard 3-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)) y = x / y
Inverse Standard 4-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)^b) y = x / y
Inverse Standard 5-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)^b )^f y = x / y
Inverse Weibull 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = x / y
Inverse Xiaogang Peng Immunoassay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = x / y
Inverse von Bertalanffy Growth 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = x / L(t)



Inverse Aphid Population Growth With Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = x / N(t) + Offset [web citation]
Inverse Beverton-Holt A With Offset 2D		y = r / (1 + ((r-1)/K) * x) y = x / y + Offset
Inverse BioScience A With Offset 2D		y = a * (1.0 - (b * c^x)) y = x / y + Offset
Inverse BioScience B With Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = x / y + Offset
Inverse Cellular Conductance With Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = x / g + Offset [web citation]
Inverse Derek Duncan Custom Equation With Offset 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = x / y + Offset
Inverse Generalized Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx))^c y = x / y + Offset
Inverse High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = x / y + Offset
Inverse High-Low Affinity Double With Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = x / y + Offset
Inverse High-Low Affinity Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) y = x / y + Offset
Inverse High-Low Affinity With Offset 2D		y = abx / (1+bx) y = x / y + Offset
Inverse Hyperbolic A With Offset 2D		y = (a + x) / (b + x) y = x / y + Offset
Inverse Hyperbolic B With Offset 2D		y = (a + bx) / (c + x) y = x / y + Offset
Inverse Hyperbolic C With Offset 2D		y = (a + x) / (b + cx) y = x / y + Offset
Inverse Hyperbolic D With Offset 2D		y = (a + bx) / (c + dx) y = x / y + Offset
Inverse Hyperbolic E With Offset 2D		y = ax / (b + x) y = x / y + Offset
Inverse Hyperbolic F With Offset 2D		y = ax / (b + x) + cx y = x / y + Offset
Inverse Hyperbolic G With Offset 2D		y = ax / (b + x) + cx / (d + x) y = x / y + Offset
Inverse Hyperbolic H With Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = x / y + Offset
Inverse Hyperbolic I With Offset 2D		y = ab / (b + x) y = x / y + Offset
Inverse Hyperbolic Logistic With Offset 2D		y = ax^b / (c + x^b) y = x / y + Offset
Inverse Jorge Rabinovich Population Growth With Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-R*X)) Y = x / Y + Offset
Inverse Membrane Transport With Offset 2D		y = a(x-b) / (x² + cx + d) y = x / y + Offset
Inverse Michaelis-Menten Double With Offset 2D		y = ax / (b + x) + cx / (d + x) y = x / y + Offset
Inverse Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Offset 2D		y = a / (b + x) y = x / y + Offset
Inverse Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Offset 2D		y = a / (b + x) + c / (d + x) y = x / y + Offset
Inverse Michaelis-Menten Product Accumulation With Offset 2D		y = a(b-x) / (c + (b-x)) y = x / y + Offset
Inverse Michaelis-Menten With Offset 2D		y = ax / (b + x) y = x / y + Offset
Inverse Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx)) y = x / y + Offset
Inverse Plant Disease Exponential Model With Offset 2D		Incidence = y0 * exp(r * time) Incidence = x / Incidence + Offset [web citation]
Inverse Plant Disease Gompertz Model With Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = x / Incidence + Offset [web citation]
Inverse Plant Disease Logistic Model With Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = x / Incidence + Offset [web citation]
Inverse Plant Disease Monomolecular Model With Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = x / Incidence + Offset [web citation]
Inverse Plant Disease Weibull Model Scaled With Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = x / y + Offset [web citation]
Inverse Plant Disease Weibull Model With Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = x / Incidence + Offset [web citation]
Inverse Scaled Log Transform With Offset 2D		y = a * log(bx + c) y = x / y + Offset
Inverse Scaled Log With Offset 2D		y = a * log(x) y = x / y + Offset
Inverse Scaled Power Transform With Offset 2D		y = a * (cx + d)^b y = x / y + Offset
Inverse Weibull With Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = x / y + Offset
Inverse Xiaogang Peng Immunoassay With Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = x / y + Offset
Inverse von Bertalanffy Growth With Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = x / L(t) + Offset



Aphid Population Growth With Linear Decay And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) / x + Offset [web citation]
Beverton-Holt A With Linear Decay And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y / x + Offset
Beverton-Holt B With Linear Decay And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y / x + Offset
BioScience A With Linear Decay And Offset 2D		y = a * (1.0 - (b * c^x)) y = y / x + Offset
BioScience B With Linear Decay And Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y / x + Offset
Cellular Conductance With Linear Decay And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g / (g x) + Offset [web citation]
Derek Duncan Custom Equation With Linear Decay And Offset 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = y / x + Offset
Generalized Negative Exponential With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y / x + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Decay And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (f * x) + Offset
High-Low Affinity Double With Linear Decay And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (f * x) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Decay And Offset 2D		y = ab / (1+bx) y = y / x + Offset
High-Low Affinity With Linear Decay And Offset 2D		y = abx / (1+bx) y = y / x + Offset
Hyperbolic A With Linear Decay And Offset 2D		y = (a + x) / (b + x) y = y / (c * x) + Offset
Hyperbolic B With Linear Decay And Offset 2D		y = (a + bx) / (c + x) y = y / (d * x) + Offset
Hyperbolic C With Linear Decay And Offset 2D		y = (a + x) / (b + cx) y = y / (d * x) + Offset
Hyperbolic D With Linear Decay And Offset 2D		y = (a + bx) / (c + dx) y = y / (f * x) + Offset
Hyperbolic E With Linear Decay And Offset 2D		y = ax / (b + x) y = y / x + Offset
Hyperbolic F With Linear Decay And Offset 2D		y = ax / (b + x) + cx y = y / (d * x) + Offset
Hyperbolic G With Linear Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * x) + Offset
Hyperbolic H With Linear Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (g * x) + Offset
Hyperbolic I With Linear Decay And Offset 2D		y = ab / (b + x) y = y / x + Offset
Hyperbolic J With Linear Decay And Offset 2D		y = x / (a + bx) y = y / (c * x) + Offset
Hyperbolic Logistic With Linear Decay And Offset 2D		y = ax^b / (c + x^b) y = y / x + Offset
Jorge Rabinovich Population Growth With Linear Decay And Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y / (d x) + Offset
Membrane Transport With Linear Decay And Offset 2D		y = a(x-b) / (x² + cx + d) y = y / x + Offset
Michaelis-Menten Double With Linear Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Decay And Offset 2D		y = a / (b + x) y = y / x + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Decay And Offset 2D		y = a / (b + x) + c / (d + x) y = y / (f * x) + Offset
Michaelis-Menten Product Accumulation With Linear Decay And Offset 2D		y = a(b-x) / (c + (b-x)) y = y / x + Offset
Michaelis-Menten With Linear Decay And Offset 2D		y = ax / (b + x) y = y / x + Offset
Negative Exponential With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / x + Offset
Plant Disease Exponential Model With Linear Decay And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / x + Offset [web citation]
Plant Disease Gompertz Model With Linear Decay And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (c * x) + Offset [web citation]
Plant Disease Logistic Model With Linear Decay And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (c * x) + Offset [web citation]
Plant Disease Monomolecular Model With Linear Decay And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (c * x) + Offset [web citation]
Plant Disease Weibull Model Scaled With Linear Decay And Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y / x + Offset [web citation]
Plant Disease Weibull Model With Linear Decay And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence / (d * x) + Offset [web citation]
Scaled Log Transform With Linear Decay And Offset 2D		y = a * log(bx + c) y = y / x + Offset
Scaled Log With Linear Decay And Offset 2D		y = a * log(x) y = y / x + Offset
Scaled Power Transform With Linear Decay And Offset 2D		y = a * (cx + d)^b y = y / x + Offset
Scaled Power With Linear Decay And Offset 2D		y = a * x^b y = y / x + Offset
Weibull With Linear Decay And Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y / x + Offset
Xiaogang Peng Immunoassay With Linear Decay And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / x + Offset
von Bertalanffy Growth With Linear Decay And Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) / x + Offset



Aphid Population Growth With Linear Decay 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) / x [web citation]
Beverton-Holt A With Linear Decay 2D		y = r / (1 + ((r-1)/K) * x) y = y / x
Beverton-Holt B With Linear Decay 2D		y = rx / (1 + ((r-1)/K) * x) y = y / x
BioScience A With Linear Decay 2D		y = a * (1.0 - (b * c^x)) y = y / x
BioScience B With Linear Decay 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y / x
Cellular Conductance With Linear Decay 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g / (g x) [web citation]
Derek Duncan Custom Equation With Linear Decay 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = y / x
Dose-Response A With Linear Decay 2D		y = b + (a-b) / (1 + 10^x-c) y = y / (d * x)
Dose-Response B With Linear Decay 2D		y = b + (a-b) / (1 + 10^c-x) y = y / (d * x)
Dose-Response C With Linear Decay 2D		y = b + (a-b) / (1 + 10^d(x-c)) y = y / (f x)
Dose-Response D With Linear Decay 2D		y = b + (a-b) / (1 + 10^d(c-x)) y = y / (f x)
Dose-Response E With Linear Decay 2D		y = b + (a-b) / (1 + (x/c)^d) y = y / (f * x)
Generalized Negative Exponential With Linear Decay 2D		y = a * (1.0 - exp(-bx))^c y = y / x
Generalized Product Accumulation With Linear Decay 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y / (g * x)
Generalized Substrate Depletion With Linear Decay 2D		y = ax / (b + x) - cx - d y = y / (f * x)
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Decay 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (f * x)
High-Low Affinity Double With Linear Decay 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (f * x)
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Decay 2D		y = ab / (1+bx) y = y / x
High-Low Affinity With Linear Decay 2D		y = abx / (1+bx) y = y / x
Hyperbolic A With Linear Decay 2D		y = (a + x) / (b + x) y = y / (c * x)
Hyperbolic B With Linear Decay 2D		y = (a + bx) / (c + x) y = y / (d * x)
Hyperbolic C With Linear Decay 2D		y = (a + x) / (b + cx) y = y / (d * x)
Hyperbolic D With Linear Decay 2D		y = (a + bx) / (c + dx) y = y / (f * x)
Hyperbolic E With Linear Decay 2D		y = ax / (b + x) y = y / x
Hyperbolic F With Linear Decay 2D		y = ax / (b + x) + cx y = y / (d * x)
Hyperbolic G With Linear Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * x)
Hyperbolic H With Linear Decay 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (g * x)
Hyperbolic I With Linear Decay 2D		y = ab / (b + x) y = y / x
Hyperbolic J With Linear Decay 2D		y = x / (a + bx) y = y / (c * x)
Hyperbolic Logistic With Linear Decay 2D		y = ax^b / (c + x^b) y = y / x
Jorge Rabinovich Population Growth With Linear Decay 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y / (d x)
Membrane Transport With Linear Decay 2D		y = a(x-b) / (x² + cx + d) y = y / x
Michaelis-Menten Double With Linear Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (f * x)
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Decay 2D		y = a / (b + x) y = y / x
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Decay 2D		y = a / (b + x) + c / (d + x) y = y / (f * x)
Michaelis-Menten Product Accumulation With Linear Decay 2D		y = a(b-x) / (c + (b-x)) y = y / x
Michaelis-Menten With Linear Decay 2D		y = ax / (b + x) y = y / x
Negative Exponential With Linear Decay 2D		y = a * (1.0 - exp(-bx)) y = y / x
New Zealand Ecology Logistic 1 With Linear Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3))) n = n / (f * x)
New Zealand Ecology Logistic 2 With Linear Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3))) n = n / (g * x)
Plant Disease Exponential Model With Linear Decay 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / x [web citation]
Plant Disease Gompertz Model With Linear Decay 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (c * x) [web citation]
Plant Disease Logistic Model With Linear Decay 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (c * x) [web citation]
Plant Disease Monomolecular Model With Linear Decay 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (c * x) [web citation]
Plant Disease Weibull Model Scaled With Linear Decay 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y / x [web citation]
Plant Disease Weibull Model With Linear Decay 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence / (d * x) [web citation]
Preece And Baines Growth With Linear Decay 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y / (g * x)
Scaled Log Transform With Linear Decay 2D		y = a * log(bx + c) y = y / x
Scaled Log With Linear Decay 2D		y = a * log(x) y = y / x
Scaled Power Transform With Linear Decay 2D		y = a * (cx + d)^b y = y / x
Scaled Power With Linear Decay 2D		y = a * x^b y = y / x
Standard 3-Parameter Logistic Equation With Linear Decay 2D		y = d + (a - d) / (1 + (x / c)) y = y / (d * x)
Standard 4-Parameter Logistic Equation With Linear Decay 2D		y = d + (a - d) / (1 + (x / c)^b) y = y / (f * x)
Standard 5-Parameter Logistic Equation With Linear Decay 2D		y = d + (a - d) / (1 + (x / c)^b )^f y = y / (g * x)
Weibull With Linear Decay 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y / x
Xiaogang Peng Immunoassay With Linear Decay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / x
von Bertalanffy Growth With Linear Decay 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) / x



Aphid Population Growth With Linear Growth And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) * x + Offset [web citation]
Beverton-Holt A With Linear Growth And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y * x + Offset
Beverton-Holt B With Linear Growth And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y * x + Offset
BioScience A With Linear Growth And Offset 2D		y = a * (1.0 - (b * c^x)) y = y * x + Offset
BioScience B With Linear Growth And Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y * x + Offset
Cellular Conductance With Linear Growth And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g (g * x) + Offset [web citation]
Derek Duncan Custom Equation With Linear Growth And Offset 2D		y = a / (1 + exp(-1/b(x-c)))^d y = y x + Offset
Generalized Negative Exponential With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y * x + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Growth And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (f * x) + Offset
High-Low Affinity Double With Linear Growth And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (f * x) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Growth And Offset 2D		y = ab / (1+bx) y = y * x + Offset
High-Low Affinity With Linear Growth And Offset 2D		y = abx / (1+bx) y = y * x + Offset
Hyperbolic A With Linear Growth And Offset 2D		y = (a + x) / (b + x) y = y * (c * x) + Offset
Hyperbolic B With Linear Growth And Offset 2D		y = (a + bx) / (c + x) y = y * (d * x) + Offset
Hyperbolic C With Linear Growth And Offset 2D		y = (a + x) / (b + cx) y = y * (d * x) + Offset
Hyperbolic D With Linear Growth And Offset 2D		y = (a + bx) / (c + dx) y = y * (f * x) + Offset
Hyperbolic E With Linear Growth And Offset 2D		y = ax / (b + x) y = y * x + Offset
Hyperbolic F With Linear Growth And Offset 2D		y = ax / (b + x) + cx y = y * (d * x) + Offset
Hyperbolic G With Linear Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * x) + Offset
Hyperbolic H With Linear Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (g * x) + Offset
Hyperbolic I With Linear Growth And Offset 2D		y = ab / (b + x) y = y * x + Offset
Hyperbolic J With Linear Growth And Offset 2D		y = x / (a + bx) y = y * (c * x) + Offset
Hyperbolic Logistic With Linear Growth And Offset 2D		y = ax^b / (c + x^b) y = y * x + Offset
Jorge Rabinovich Population Growth With Linear Growth And Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y (d * x) + Offset
Membrane Transport With Linear Growth And Offset 2D		y = a(x-b) / (x² + cx + d) y = y * x + Offset
Michaelis-Menten Double With Linear Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Growth And Offset 2D		y = a / (b + x) y = y * x + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Growth And Offset 2D		y = a / (b + x) + c / (d + x) y = y * (f * x) + Offset
Michaelis-Menten Product Accumulation With Linear Growth And Offset 2D		y = a(b-x) / (c + (b-x)) y = y * x + Offset
Michaelis-Menten With Linear Growth And Offset 2D		y = ax / (b + x) y = y * x + Offset
Negative Exponential With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * x + Offset
Plant Disease Exponential Model With Linear Growth And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * x + Offset [web citation]
Plant Disease Gompertz Model With Linear Growth And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (c * x) + Offset [web citation]
Plant Disease Logistic Model With Linear Growth And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (c * x) + Offset [web citation]
Plant Disease Monomolecular Model With Linear Growth And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (c * x) + Offset [web citation]
Plant Disease Weibull Model Scaled With Linear Growth And Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y * x + Offset [web citation]
Plant Disease Weibull Model With Linear Growth And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence * (d * x) + Offset [web citation]
Scaled Log Transform With Linear Growth And Offset 2D		y = a * log(bx + c) y = y * x + Offset
Scaled Log With Linear Growth And Offset 2D		y = a * log(x) y = y * x + Offset
Scaled Power Transform With Linear Growth And Offset 2D		y = a * (cx + d)^b y = y * x + Offset
Scaled Power With Linear Growth And Offset 2D		y = a * x^b y = y * x + Offset
Weibull With Linear Growth And Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y * x + Offset
Xiaogang Peng Immunoassay With Linear Growth And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * x + Offset
von Bertalanffy Growth With Linear Growth And Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) * x + Offset



Aphid Population Growth With Linear Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = N(t) * x [web citation]
Beverton-Holt A With Linear Growth 2D		y = r / (1 + ((r-1)/K) * x) y = y * x
Beverton-Holt B With Linear Growth 2D		y = rx / (1 + ((r-1)/K) * x) y = y * x
BioScience A With Linear Growth 2D		y = a * (1.0 - (b * c^x)) y = y * x
BioScience B With Linear Growth 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = y * x
Cellular Conductance With Linear Growth 2D		g = p3/(1+exp((v-p1)/p2)) + p4exp((v-45)/p5) g = g (g * x) [web citation]
Derek Duncan Custom Equation With Linear Growth 2D		y = a / (1 + exp(-1/b(x-c)))^d y = y x
Dose-Response A With Linear Growth 2D		y = b + (a-b) / (1 + 10^x-c) y = y * (d * x)
Dose-Response B With Linear Growth 2D		y = b + (a-b) / (1 + 10^c-x) y = y * (d * x)
Dose-Response C With Linear Growth 2D		y = b + (a-b) / (1 + 10^d(x-c)) y = y (f * x)
Dose-Response D With Linear Growth 2D		y = b + (a-b) / (1 + 10^d(c-x)) y = y (f * x)
Dose-Response E With Linear Growth 2D		y = b + (a-b) / (1 + (x/c)^d) y = y * (f * x)
Generalized Negative Exponential With Linear Growth 2D		y = a * (1.0 - exp(-bx))^c y = y * x
Generalized Product Accumulation With Linear Growth 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y * (g * x)
Generalized Substrate Depletion With Linear Growth 2D		y = ax / (b + x) - cx - d y = y * (f * x)
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Growth 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (f * x)
High-Low Affinity Double With Linear Growth 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (f * x)
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Growth 2D		y = ab / (1+bx) y = y * x
High-Low Affinity With Linear Growth 2D		y = abx / (1+bx) y = y * x
Hyperbolic A With Linear Growth 2D		y = (a + x) / (b + x) y = y * (c * x)
Hyperbolic B With Linear Growth 2D		y = (a + bx) / (c + x) y = y * (d * x)
Hyperbolic C With Linear Growth 2D		y = (a + x) / (b + cx) y = y * (d * x)
Hyperbolic D With Linear Growth 2D		y = (a + bx) / (c + dx) y = y * (f * x)
Hyperbolic E With Linear Growth 2D		y = ax / (b + x) y = y * x
Hyperbolic F With Linear Growth 2D		y = ax / (b + x) + cx y = y * (d * x)
Hyperbolic G With Linear Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * x)
Hyperbolic H With Linear Growth 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (g * x)
Hyperbolic I With Linear Growth 2D		y = ab / (b + x) y = y * x
Hyperbolic J With Linear Growth 2D		y = x / (a + bx) y = y * (c * x)
Hyperbolic Logistic With Linear Growth 2D		y = ax^b / (c + x^b) y = y * x
Jorge Rabinovich Population Growth With Linear Growth 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-RX)) Y = Y (d * x)
Membrane Transport With Linear Growth 2D		y = a(x-b) / (x² + cx + d) y = y * x
Michaelis-Menten Double With Linear Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (f * x)
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Growth 2D		y = a / (b + x) y = y * x
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Growth 2D		y = a / (b + x) + c / (d + x) y = y * (f * x)
Michaelis-Menten Product Accumulation With Linear Growth 2D		y = a(b-x) / (c + (b-x)) y = y * x
Michaelis-Menten With Linear Growth 2D		y = ax / (b + x) y = y * x
Negative Exponential With Linear Growth 2D		y = a * (1.0 - exp(-bx)) y = y * x
New Zealand Ecology Logistic 1 With Linear Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3))) n = n * (f * x)
New Zealand Ecology Logistic 2 With Linear Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3))) n = n * (g * x)
Plant Disease Exponential Model With Linear Growth 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * x [web citation]
Plant Disease Gompertz Model With Linear Growth 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (c * x) [web citation]
Plant Disease Logistic Model With Linear Growth 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (c * x) [web citation]
Plant Disease Monomolecular Model With Linear Growth 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (c * x) [web citation]
Plant Disease Weibull Model Scaled With Linear Growth 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = y * x [web citation]
Plant Disease Weibull Model With Linear Growth 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = Incidence * (d * x) [web citation]
Preece And Baines Growth With Linear Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y * (g * x)
Scaled Log Transform With Linear Growth 2D		y = a * log(bx + c) y = y * x
Scaled Log With Linear Growth 2D		y = a * log(x) y = y * x
Scaled Power Transform With Linear Growth 2D		y = a * (cx + d)^b y = y * x
Scaled Power With Linear Growth 2D		y = a * x^b y = y * x
Standard 3-Parameter Logistic Equation With Linear Growth 2D		y = d + (a - d) / (1 + (x / c)) y = y * (d * x)
Standard 4-Parameter Logistic Equation With Linear Growth 2D		y = d + (a - d) / (1 + (x / c)^b) y = y * (f * x)
Standard 5-Parameter Logistic Equation With Linear Growth 2D		y = d + (a - d) / (1 + (x / c)^b )^f y = y * (g * x)
Weibull With Linear Growth 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = y * x
Xiaogang Peng Immunoassay With Linear Growth 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * x
von Bertalanffy Growth With Linear Growth 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = L(t) * x



Reciprocal Aphid Population Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = 1.0 / N(t) [web citation]
Reciprocal Beverton-Holt A 2D		y = r / (1 + ((r-1)/K) * x) y = 1.0 / y
Reciprocal Beverton-Holt B 2D		y = rx / (1 + ((r-1)/K) * x) y = 1.0 / y
Reciprocal BioScience A 2D		y = a * (1.0 - (b * c^x)) y = 1.0 / y
Reciprocal BioScience B 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = 1.0 / y
Reciprocal Cellular Conductance 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = 1.0 / g [web citation]
Reciprocal Derek Duncan Custom Equation 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = 1.0 / y
Reciprocal Dose-Response A 2D		y = b + (a-b) / (1 + 10^x-c) y = 1.0 / y
Reciprocal Dose-Response B 2D		y = b + (a-b) / (1 + 10^c-x) y = 1.0 / y
Reciprocal Dose-Response C 2D		y = b + (a-b) / (1 + 10^d*(x-c)) y = 1.0 / y
Reciprocal Dose-Response D 2D		y = b + (a-b) / (1 + 10^d*(c-x)) y = 1.0 / y
Reciprocal Dose-Response E 2D		y = b + (a-b) / (1 + (x/c)^d) y = 1.0 / y
Reciprocal Generalized Negative Exponential 2D		y = a * (1.0 - exp(-bx))^c y = 1.0 / y
Reciprocal Generalized Product Accumulation 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = 1.0 / y
Reciprocal Generalized Substrate Depletion 2D		y = ax / (b + x) - cx - d y = 1.0 / y
Reciprocal High-Low Affinity 2D		y = abx / (1+bx) y = 1.0 / y
Reciprocal High-Low Affinity Double 2D		y = abx / (1+bx) + cdx / (1+dx) y = 1.0 / y
Reciprocal High-Low Affinity Double Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) + cd / (1+dx) y = 1.0 / y
Reciprocal High-Low Affinity Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) y = 1.0 / y
Reciprocal Hyperbolic B 2D		y = (a + bx) / (c + x) y = 1.0 / y
Reciprocal Hyperbolic C 2D		y = (a + x) / (b + cx) y = 1.0 / y
Reciprocal Hyperbolic E 2D		y = ax / (b + x) y = 1.0 / y
Reciprocal Hyperbolic F 2D		y = ax / (b + x) + cx y = 1.0 / y
Reciprocal Hyperbolic G 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y
Reciprocal Hyperbolic H 2D		y = ax / (b + x) + cx / (d + x) + fx y = 1.0 / y
Reciprocal Hyperbolic I 2D		y = ab / (b + x) y = 1.0 / y
Reciprocal Hyperbolic J 2D		y = x / (a + bx) y = 1.0 / y
Reciprocal Hyperbolic Logistic 2D		y = ax^b / (c + x^b) y = 1.0 / y
Reciprocal Jorge Rabinovich Population Growth 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-R*X)) Y = 1.0 / Y
Reciprocal Membrane Transport 2D		y = a(x-b) / (x² + cx + d) y = 1.0 / y
Reciprocal Michaelis-Menten 2D		y = ax / (b + x) y = 1.0 / y
Reciprocal Michaelis-Menten Double 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y
Reciprocal Michaelis-Menten Isotope Displacement ([Hot] subsumed) 2D		y = a / (b + x) y = 1.0 / y
Reciprocal Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) 2D		y = a / (b + x) + c / (d + x) y = 1.0 / y
Reciprocal Michaelis-Menten Product Accumulation 2D		y = a(b-x) / (c + (b-x)) y = 1.0 / y
Reciprocal Negative Exponential 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y
Reciprocal New Zealand Ecology Logistic 1 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3))) n = 1.0 / n
Reciprocal New Zealand Ecology Logistic 2 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3))) n = 1.0 / n
Reciprocal Plant Disease Exponential Model 2D		Incidence = y0 * exp(r * time) Incidence = 1.0 / Incidence [web citation]
Reciprocal Plant Disease Gompertz Model 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = 1.0 / Incidence [web citation]
Reciprocal Plant Disease Monomolecular Model 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = 1.0 / Incidence [web citation]
Reciprocal Plant Disease Weibull Model 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = 1.0 / Incidence [web citation]
Reciprocal Plant Disease Weibull Model Scaled 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = 1.0 / y [web citation]
Reciprocal Preece And Baines Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = 1.0 / y
Reciprocal Scaled Log 2D		y = a * log(x) y = 1.0 / y
Reciprocal Scaled Log Transform 2D		y = a * log(bx + c) y = 1.0 / y
Reciprocal Scaled Power 2D		y = a * x^b y = 1.0 / y
Reciprocal Scaled Power Transform 2D		y = a * (cx + d)^b y = 1.0 / y
Reciprocal Standard 3-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)) y = 1.0 / y
Reciprocal Standard 4-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)^b) y = 1.0 / y
Reciprocal Standard 5-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)^b )^f y = 1.0 / y
Reciprocal Weibull 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = 1.0 / y
Reciprocal Xiaogang Peng Immunoassay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = 1.0 / y
Reciprocal von Bertalanffy Growth 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = 1.0 / L(t)



Reciprocal Aphid Population Growth With Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 N(t) = 1.0 / N(t) + Offset [web citation]
Reciprocal Beverton-Holt A With Offset 2D		y = r / (1 + ((r-1)/K) * x) y = 1.0 / y + Offset
Reciprocal Beverton-Holt B With Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = 1.0 / y + Offset
Reciprocal BioScience A With Offset 2D		y = a * (1.0 - (b * c^x)) y = 1.0 / y + Offset
Reciprocal BioScience B With Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) y = 1.0 / y + Offset
Reciprocal Cellular Conductance With Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = 1.0 / g + Offset [web citation]
Reciprocal Derek Duncan Custom Equation With Offset 2D		y = a / (1 + exp(-1/b*(x-c)))^d y = 1.0 / y + Offset
Reciprocal Generalized Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx))^c y = 1.0 / y + Offset
Reciprocal High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = 1.0 / y + Offset
Reciprocal High-Low Affinity Double With Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = 1.0 / y + Offset
Reciprocal High-Low Affinity Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) y = 1.0 / y + Offset
Reciprocal High-Low Affinity With Offset 2D		y = abx / (1+bx) y = 1.0 / y + Offset
Reciprocal Hyperbolic B With Offset 2D		y = (a + bx) / (c + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic C With Offset 2D		y = (a + x) / (b + cx) y = 1.0 / y + Offset
Reciprocal Hyperbolic E With Offset 2D		y = ax / (b + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic F With Offset 2D		y = ax / (b + x) + cx y = 1.0 / y + Offset
Reciprocal Hyperbolic G With Offset 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic H With Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = 1.0 / y + Offset
Reciprocal Hyperbolic I With Offset 2D		y = ab / (b + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic J With Offset 2D		y = x / (a + bx) y = 1.0 / y + Offset
Reciprocal Hyperbolic Logistic With Offset 2D		y = ax^b / (c + x^b) y = 1.0 / y + Offset
Reciprocal Jorge Rabinovich Population Growth With Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-R*X)) Y = 1.0 / Y + Offset
Reciprocal Membrane Transport With Offset 2D		y = a(x-b) / (x² + cx + d) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Double With Offset 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Offset 2D		y = a / (b + x) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Offset 2D		y = a / (b + x) + c / (d + x) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Product Accumulation With Offset 2D		y = a(b-x) / (c + (b-x)) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten With Offset 2D		y = ax / (b + x) y = 1.0 / y + Offset
Reciprocal Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y + Offset
Reciprocal Plant Disease Exponential Model With Offset 2D		Incidence = y0 * exp(r * time) Incidence = 1.0 / Incidence + Offset [web citation]
Reciprocal Plant Disease Gompertz Model With Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = 1.0 / Incidence + Offset [web citation]
Reciprocal Plant Disease Monomolecular Model With Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = 1.0 / Incidence + Offset [web citation]
Reciprocal Plant Disease Weibull Model Scaled With Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) y = 1.0 / y + Offset [web citation]
Reciprocal Plant Disease Weibull Model With Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) Incidence = 1.0 / Incidence + Offset [web citation]
Reciprocal Scaled Log Transform With Offset 2D		y = a * log(bx + c) y = 1.0 / y + Offset
Reciprocal Scaled Log With Offset 2D		y = a * log(x) y = 1.0 / y + Offset
Reciprocal Scaled Power Transform With Offset 2D		y = a * (cx + d)^b y = 1.0 / y + Offset
Reciprocal Scaled Power With Offset 2D		y = a * x^b y = 1.0 / y + Offset
Reciprocal Weibull With Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) y = 1.0 / y + Offset
Reciprocal Xiaogang Peng Immunoassay With Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = 1.0 / y + Offset
Reciprocal von Bertalanffy Growth With Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) L(t) = 1.0 / L(t) + Offset



Aphid Population Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 [web citation]
Beverton-Holt A 2D		y = r / (1 + ((r-1)/K) * x)
Beverton-Holt B 2D		y = rx / (1 + ((r-1)/K) * x)
BioScience A 2D		y = a * (1.0 - (b * c^x))
BioScience B 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d})
Cellular Conductance 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) [web citation]
Derek Duncan Custom Equation 2D		y = a / (1 + exp(-1/b*(x-c)))^d
Dose-Response A 2D		y = b + (a-b) / (1 + 10^x-c)
Dose-Response B 2D		y = b + (a-b) / (1 + 10^c-x)
Dose-Response C 2D		y = b + (a-b) / (1 + 10^d*(x-c))
Dose-Response D 2D		y = b + (a-b) / (1 + 10^d*(c-x))
Dose-Response E 2D		y = b + (a-b) / (1 + (x/c)^d)
Generalized Negative Exponential 2D		y = a * (1.0 - exp(-bx))^c
Generalized Product Accumulation 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f
Generalized Substrate Depletion 2D		y = ax / (b + x) - cx - d
High-Low Affinity 2D		y = abx / (1+bx)
High-Low Affinity Double 2D		y = abx / (1+bx) + cdx / (1+dx)
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) + cd / (1+dx)
High-Low Affinity Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx)
Hyperbolic A 2D		y = (a + x) / (b + x)
Hyperbolic B 2D		y = (a + bx) / (c + x)
Hyperbolic C 2D		y = (a + x) / (b + cx)
Hyperbolic D 2D		y = (a + bx) / (c + dx)
Hyperbolic E 2D		y = ax / (b + x)
Hyperbolic F 2D		y = ax / (b + x) + cx
Hyperbolic G 2D		y = ax / (b + x) + cx / (d + x)
Hyperbolic H 2D		y = ax / (b + x) + cx / (d + x) + fx
Hyperbolic I 2D		y = ab / (b + x)
Hyperbolic J 2D		y = x / (a + bx)
Hyperbolic Logistic 2D		y = ax^b / (c + x^b)
Jorge Rabinovich Population Growth 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-R*X))
Membrane Transport 2D		y = a(x-b) / (x² + cx + d)
Michaelis-Menten 2D		y = ax / (b + x)
Michaelis-Menten Double 2D		y = ax / (b + x) + cx / (d + x)
Michaelis-Menten Isotope Displacement ([Hot] subsumed) 2D		y = a / (b + x)
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) 2D		y = a / (b + x) + c / (d + x)
Michaelis-Menten Product Accumulation 2D		y = a(b-x) / (c + (b-x))
Negative Exponential 2D		y = a * (1.0 - exp(-bx))
New Zealand Ecology Logistic 1 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D) * B3)))
New Zealand Ecology Logistic 2 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 + D + (B4D²)) B3)))
Plant Disease Exponential Model 2D		Incidence = y0 * exp(r * time) [web citation]
Plant Disease Gompertz Model 2D		Incidence = exp(ln(y0) * exp(-r * time)) [web citation]
Plant Disease Logistic Model 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) [web citation]
Plant Disease Monomolecular Model 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) [web citation]
Plant Disease Weibull Model 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) [web citation]
Plant Disease Weibull Model Scaled 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) [web citation]
Preece And Baines Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d)))
Scaled Log 2D		y = a * log(x)
Scaled Log Transform 2D		y = a * log(bx + c)
Scaled Power 2D		y = a * x^b
Scaled Power Transform 2D		y = a * (cx + d)^b
Standard 3-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c))
Standard 4-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)^b)
Standard 5-Parameter Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)^b )^f
Weibull 2D		y = a * (1.0 - exp(-b * (x - c)^d))
Xiaogang Peng Immunoassay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx)))
von Bertalanffy Growth 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero)))



Aphid Population Growth With Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))^-2 + Offset [web citation]
Beverton-Holt A With Offset 2D		y = r / (1 + ((r-1)/K) * x) + Offset
Beverton-Holt B With Offset 2D		y = rx / (1 + ((r-1)/K) * x) + Offset
BioScience A With Offset 2D		y = a * (1.0 - (b * c^x)) + Offset
BioScience B With Offset 2D		y = a * (1.0 -(1.0 + (x/b)^c)^{-1.0 * d}) + Offset
Cellular Conductance With Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) + Offset [web citation]
Derek Duncan Custom Equation With Offset 2D		y = a / (1 + exp(-1/b*(x-c)))^d + Offset
Generalized Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx))^c + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + cd / (1+dx) + Offset
High-Low Affinity Double With Offset 2D		y = abx / (1+bx) + cdx / (1+dx) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + Offset
High-Low Affinity With Offset 2D		y = abx / (1+bx) + Offset
Hyperbolic A With Offset 2D		y = (a + x) / (b + x) + Offset
Hyperbolic B With Offset 2D		y = (a + bx) / (c + x) + Offset
Hyperbolic C With Offset 2D		y = (a + x) / (b + cx) + Offset
Hyperbolic D With Offset 2D		y = (a + bx) / (c + dx) + Offset
Hyperbolic E With Offset 2D		y = ax / (b + x) + Offset
Hyperbolic F With Offset 2D		y = ax / (b + x) + cx + Offset
Hyperbolic G With Offset 2D		y = ax / (b + x) + cx / (d + x) + Offset
Hyperbolic H With Offset 2D		y = ax / (b + x) + cx / (d + x) + fx + Offset
Hyperbolic I With Offset 2D		y = ab / (b + x) + Offset
Hyperbolic J With Offset 2D		y = x / (a + bx) + Offset
Hyperbolic Logistic With Offset 2D		y = ax^b / (c + x^b) + Offset
Jorge Rabinovich Population Growth With Offset 2D		Y = (P1CC) / (P1 + (CC-P1)exp(-R*X)) + Offset
Membrane Transport With Offset 2D		y = a(x-b) / (x² + cx + d) + Offset
Michaelis-Menten Double With Offset 2D		y = ax / (b + x) + cx / (d + x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Offset 2D		y = a / (b + x) + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Offset 2D		y = a / (b + x) + c / (d + x) + Offset
Michaelis-Menten Product Accumulation With Offset 2D		y = a(b-x) / (c + (b-x)) + Offset
Michaelis-Menten With Offset 2D		y = ax / (b + x) + Offset
Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx)) + Offset
Plant Disease Exponential Model With Offset 2D		Incidence = y0 * exp(r * time) + Offset [web citation]
Plant Disease Gompertz Model With Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) + Offset [web citation]
Plant Disease Logistic Model With Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) + Offset [web citation]
Plant Disease Monomolecular Model With Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) + Offset [web citation]
Plant Disease Weibull Model Scaled With Offset 2D		y = Scale * (1 - exp(-1.0 * ((time - a) / b)^c)) + Offset [web citation]
Plant Disease Weibull Model With Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)^c) + Offset [web citation]
Scaled Log Transform With Offset 2D		y = a * log(bx + c) + Offset
Scaled Log With Offset 2D		y = a * log(x) + Offset
Scaled Power Transform With Offset 2D		y = a * (cx + d)^b + Offset
Scaled Power With Offset 2D		y = a * x^b + Offset
Weibull With Offset 2D		y = a * (1.0 - exp(-b * (x - c)^d)) + Offset
Xiaogang Peng Immunoassay With Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) + Offset
von Bertalanffy Growth With Offset 2D		L(t) = L_inf * (1.0 - exp(-K * (t-t_zero))) + Offset



Beverton-Holt A Plus Line 2D		y = r / (1 + ((r-1)/K) * x) y = y + (c * x) + d
Beverton-Holt B Plus Line 2D		y = rx / (1 + ((r-1)/K) * x) y = y + (c * x) + d
High-Low Affinity Isotope Displacement ([Hot] subsumed) Plus Line 2D		y = ab / (1+bx) y = y + (c * x) + d
High-Low Affinity Plus Line 2D		y = abx / (1+bx) y = y + (c * x) + d
Hyperbolic A Plus Line 2D		y = (a + x) / (b + x) y = y + (c * x) + d
Hyperbolic E Plus Line 2D		y = ax / (b + x) y = y + (c * x) + d
Hyperbolic I Plus Line 2D		y = ab / (b + x) y = y + (c * x) + d
Hyperbolic J Plus Line 2D		y = x / (a + bx) y = y + (c * x) + d
Michaelis-Menten Isotope Displacement ([Hot] subsumed) Plus Line 2D		y = a / (b + x) y = y + (c * x) + d
Michaelis-Menten Plus Line 2D		y = ax / (b + x) y = y + (c * x) + d
Negative Exponential Plus Line 2D		y = a * (1.0 - exp(-bx)) y = y + (c * x) + d
Plant Disease Exponential Model Plus Line 2D		Incidence = y0 * exp(r * time) Incidence = Incidence + (c * x) + d [web citation]
Plant Disease Gompertz Model Plus Line 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence + (c * x) + d [web citation]
Plant Disease Logistic Model Plus Line 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence + (c * x) + d [web citation]
Plant Disease Monomolecular Model Plus Line 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence + (c * x) + d [web citation]
Scaled Log Plus Line 2D		y = a * log(x) y = y + (b * x) + c
Scaled Power Plus Line 2D		y = a * x^b y = y + (c * x) + d

2D BurkardtCollectionBased

Arcsin CDF Based With Exponential Decay And Offset 2D		y = a * asin( (bx+c) / d) y = y / exp(x) + Offset [web citation]
Arcsin PDF Based With Exponential Decay And Offset 2D		y = a / sqrt( b² - x²) y = y / exp(x) + Offset [web citation]
Bradford CDF Based A With Exponential Decay And Offset 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y / (d exp(x)) + Offset [web citation]
Bradford CDF Based B With Exponential Decay And Offset 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = y / exp(x) + Offset [web citation]
Bradford PDF Based With Exponential Decay And Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y / exp(x) + Offset [web citation]
Burr CDF Based A With Exponential Decay And Offset 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y / (f * exp(x)) + Offset [web citation]
Burr CDF Based B With Exponential Decay And Offset 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y / exp(x) + Offset [web citation]
Burr PDF Based With Exponential Decay And Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y / (f * exp(x)) + Offset [web citation]
Dipole CDF Based With Exponential Decay And Offset 2D		y = a * arctan(x) + b/x y = y / (c * exp(x)) + Offset [web citation]
Exponential PDF Based Scaled With Exponential Decay And Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y / exp(x) + Offset [web citation]
Exponential PDF Based With Exponential Decay And Offset 2D		y = (1.0/b) * exp((a-x)/b) y = y / (c * exp(x)) + Offset [web citation]
Extreme Values CDF Based A With Exponential Decay And Offset 2D		y = exp(-exp(-((x-a)/b))) y = y / (c * exp(x)) + Offset [web citation]
Extreme Values CDF Based B With Exponential Decay And Offset 2D		y = c * exp(-exp(-((x-a)/b))) y = y / exp(x) + Offset [web citation]
Extreme Values PDF Based With Exponential Decay And Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y / (c * exp(x)) + Offset [web citation]
Fisk CDF Based A With Exponential Decay And Offset 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y / (d * exp(x)) + Offset [web citation]
Fisk CDF Based B With Exponential Decay And Offset 2D		y = d / (1.0+(b/(x-a))^c) y = y / exp(x) + Offset [web citation]
Fisk PDF Based With Exponential Decay And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y / (d * exp(x)) + Offset [web citation]
Folded Normal PDF Based With Exponential Decay And Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y / exp(x) + Offset [web citation]
Frechet CDF Based A With Exponential Decay And Offset 2D		y = exp(-1.0 / x^a) y = y / (b * exp(x)) + Offset [web citation]
Frechet CDF Based B With Exponential Decay And Offset 2D		y = b * exp(-1.0 / x^a) y = y / exp(x) + Offset [web citation]
Frechet PDF Based A With Exponential Decay And Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / (b * exp(x)) + Offset [web citation]
Frechet PDF Based B With Exponential Decay And Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / exp(x) + Offset [web citation]
Genlogistic CDF Based A With Exponential Decay And Offset 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y / (d * exp(x)) + Offset [web citation]
Genlogistic CDF Based B With Exponential Decay And Offset 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y / exp(x) + Offset [web citation]
Genlogistic PDF Based With Exponential Decay And Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y / (d * exp(x)) + Offset [web citation]
Gompertz CDF Based Scaled With Exponential Decay And Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y / exp(x) + Offset [web citation]
Gompertz CDF Based With Exponential Decay And Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y / (c * exp(x)) + Offset [web citation]
Gumbel CDF Based With Exponential Decay And Offset 2D		y = a * exp(-exp(-x)) y = y / exp(x) + Offset [web citation]
Gumbel PDF Based With Exponential Decay And Offset 2D		y = a * exp(-x-exp(-x)) y = y / exp(x) + Offset [web citation]
Half Normal PDF Based With Exponential Decay And Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y / exp(x) + Offset [web citation]
Inverse_gaussian PDF Based A With Exponential Decay And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y / (d exp(x)) + Offset [web citation]
Inverse_gaussian PDF Based B With Exponential Decay And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = y / exp(x) + Offset [web citation]
Levy PDF Based Scaled With Exponential Decay And Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = y / exp(x) + Offset [web citation]
Levy PDF Based With Exponential Decay And Offset 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y / (c exp(x)) + Offset [web citation]
Log Normal PDF Based With Exponential Decay And Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y / (c * exp(x)) + Offset [web citation]
Logistic PDF Based With Exponential Decay And Offset 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y / (c exp(x)) + Offset [web citation]
Pareto PDF Based With Exponential Decay And Offset 2D		y = b * a^b / x^(b+1.0) y = y / (c * exp(x)) + Offset [web citation]
Power PDF Based With Exponential Decay And Offset 2D		y = (a/b) * (x/b)^(a-1.0) y = y / (c * exp(x)) + Offset [web citation]
Rayleigh CDF Based A With Exponential Decay And Offset 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y / (b exp(x)) + Offset [web citation]
Rayleigh CDF Based B With Exponential Decay And Offset 2D		y = b * exp(-x²/(2.0*a²)) y = y / exp(x) + Offset [web citation]
Rayleigh PDF Based Scaled With Exponential Decay And Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = y / exp(x) + Offset [web citation]
Rayleigh PDF Based With Exponential Decay And Offset 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y / (b exp(x)) + Offset [web citation]
Reciprocal CDF Based With Exponential Decay And Offset 2D		y = ln(a/x) / ln(a/b) y = y / (c * exp(x)) + Offset [web citation]
Sech CDF Based With Exponential Decay And Offset 2D		y = c * atan(exp((x-a)/b)) y = y / exp(x) + Offset [web citation]
Weibull CDF Based A With Exponential Decay And Offset 2D		y = 1.0 / exp(((x-a)/b)^c) y = y / (d * exp(x)) + Offset [web citation]
Weibull CDF Based B With Exponential Decay And Offset 2D		y = d / exp(((x-a)/b)^c) y = y / exp(x) + Offset [web citation]
Weibull PDF Based With Exponential Decay And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y / (d * exp(x)) + Offset [web citation]



Arcsin CDF Based With Exponential Decay 2D		y = a * asin( (bx+c) / d) y = y / exp(x) [web citation]
Arcsin PDF Based With Exponential Decay 2D		y = a / sqrt( b² - x²) y = y / exp(x) [web citation]
Bradford CDF Based A With Exponential Decay 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y / (d exp(x)) [web citation]
Bradford CDF Based B With Exponential Decay 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = y / exp(x) [web citation]
Bradford PDF Based With Exponential Decay 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y / exp(x) [web citation]
Burr CDF Based A With Exponential Decay 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y / (f * exp(x)) [web citation]
Burr CDF Based B With Exponential Decay 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y / exp(x) [web citation]
Burr PDF Based With Exponential Decay 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y / (f * exp(x)) [web citation]
Dipole CDF Based With Exponential Decay 2D		y = a * arctan(x) + b/x y = y / (c * exp(x)) [web citation]
Exponential PDF Based Scaled With Exponential Decay 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y / exp(x) [web citation]
Exponential PDF Based With Exponential Decay 2D		y = (1.0/b) * exp((a-x)/b) y = y / (c * exp(x)) [web citation]
Extreme Values CDF Based A With Exponential Decay 2D		y = exp(-exp(-((x-a)/b))) y = y / (c * exp(x)) [web citation]
Extreme Values CDF Based B With Exponential Decay 2D		y = c * exp(-exp(-((x-a)/b))) y = y / exp(x) [web citation]
Extreme Values PDF Based With Exponential Decay 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y / (c * exp(x)) [web citation]
Fisk CDF Based A With Exponential Decay 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y / (d * exp(x)) [web citation]
Fisk CDF Based B With Exponential Decay 2D		y = d / (1.0+(b/(x-a))^c) y = y / exp(x) [web citation]
Fisk PDF Based With Exponential Decay 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y / (d * exp(x)) [web citation]
Folded Normal PDF Based With Exponential Decay 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y / exp(x) [web citation]
Frechet CDF Based A With Exponential Decay 2D		y = exp(-1.0 / x^a) y = y / (b * exp(x)) [web citation]
Frechet CDF Based B With Exponential Decay 2D		y = b * exp(-1.0 / x^a) y = y / exp(x) [web citation]
Frechet PDF Based A With Exponential Decay 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / (b * exp(x)) [web citation]
Frechet PDF Based B With Exponential Decay 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / exp(x) [web citation]
Genlogistic CDF Based A With Exponential Decay 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y / (d * exp(x)) [web citation]
Genlogistic CDF Based B With Exponential Decay 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y / exp(x) [web citation]
Genlogistic PDF Based With Exponential Decay 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y / (d * exp(x)) [web citation]
Gompertz CDF Based Scaled With Exponential Decay 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y / exp(x) [web citation]
Gompertz CDF Based With Exponential Decay 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y / (c * exp(x)) [web citation]
Gumbel CDF Based With Exponential Decay 2D		y = a * exp(-exp(-x)) y = y / exp(x) [web citation]
Gumbel PDF Based With Exponential Decay 2D		y = a * exp(-x-exp(-x)) y = y / exp(x) [web citation]
Half Normal PDF Based With Exponential Decay 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y / exp(x) [web citation]
Inverse_gaussian PDF Based A With Exponential Decay 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y / (d exp(x)) [web citation]
Inverse_gaussian PDF Based B With Exponential Decay 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = y / exp(x) [web citation]
Levy PDF Based Scaled With Exponential Decay 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = y / exp(x) [web citation]
Levy PDF Based With Exponential Decay 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y / (c exp(x)) [web citation]
Log Normal PDF Based With Exponential Decay 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y / (c * exp(x)) [web citation]
Logistic PDF Based With Exponential Decay 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y / (c exp(x)) [web citation]
Pareto PDF Based With Exponential Decay 2D		y = b * a^b / x^(b+1.0) y = y / (c * exp(x)) [web citation]
Power PDF Based With Exponential Decay 2D		y = (a/b) * (x/b)^(a-1.0) y = y / (c * exp(x)) [web citation]
Rayleigh CDF Based A With Exponential Decay 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y / (b exp(x)) [web citation]
Rayleigh CDF Based B With Exponential Decay 2D		y = b * exp(-x²/(2.0*a²)) y = y / exp(x) [web citation]
Rayleigh PDF Based Scaled With Exponential Decay 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = y / exp(x) [web citation]
Rayleigh PDF Based With Exponential Decay 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y / (b exp(x)) [web citation]
Reciprocal CDF Based With Exponential Decay 2D		y = ln(a/x) / ln(a/b) y = y / (c * exp(x)) [web citation]
Sech CDF Based With Exponential Decay 2D		y = c * atan(exp((x-a)/b)) y = y / exp(x) [web citation]
Weibull CDF Based A With Exponential Decay 2D		y = 1.0 / exp(((x-a)/b)^c) y = y / (d * exp(x)) [web citation]
Weibull CDF Based B With Exponential Decay 2D		y = d / exp(((x-a)/b)^c) y = y / exp(x) [web citation]
Weibull PDF Based With Exponential Decay 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y / (d * exp(x)) [web citation]



Arcsin CDF Based With Exponential Growth And Offset 2D		y = a * asin( (bx+c) / d) y = y * exp(x) + Offset [web citation]
Arcsin PDF Based With Exponential Growth And Offset 2D		y = a / sqrt( b² - x²) y = y * exp(x) + Offset [web citation]
Bradford CDF Based A With Exponential Growth And Offset 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y (d * exp(x)) + Offset [web citation]
Bradford CDF Based B With Exponential Growth And Offset 2D		y = d * ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y exp(x) + Offset [web citation]
Bradford PDF Based With Exponential Growth And Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y * exp(x) + Offset [web citation]
Burr CDF Based A With Exponential Growth And Offset 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y * (f * exp(x)) + Offset [web citation]
Burr CDF Based B With Exponential Growth And Offset 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y * exp(x) + Offset [web citation]
Burr PDF Based With Exponential Growth And Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y * (f * exp(x)) + Offset [web citation]
Dipole CDF Based With Exponential Growth And Offset 2D		y = a * arctan(x) + b/x y = y * (c * exp(x)) + Offset [web citation]
Exponential PDF Based Scaled With Exponential Growth And Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y * exp(x) + Offset [web citation]
Exponential PDF Based With Exponential Growth And Offset 2D		y = (1.0/b) * exp((a-x)/b) y = y * (c * exp(x)) + Offset [web citation]
Extreme Values CDF Based A With Exponential Growth And Offset 2D		y = exp(-exp(-((x-a)/b))) y = y * (c * exp(x)) + Offset [web citation]
Extreme Values CDF Based B With Exponential Growth And Offset 2D		y = c * exp(-exp(-((x-a)/b))) y = y * exp(x) + Offset [web citation]
Extreme Values PDF Based With Exponential Growth And Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y * (c * exp(x)) + Offset [web citation]
Fisk CDF Based A With Exponential Growth And Offset 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y * (d * exp(x)) + Offset [web citation]
Fisk CDF Based B With Exponential Growth And Offset 2D		y = d / (1.0+(b/(x-a))^c) y = y * exp(x) + Offset [web citation]
Fisk PDF Based With Exponential Growth And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y * (d * exp(x)) + Offset [web citation]
Folded Normal PDF Based With Exponential Growth And Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y * exp(x) + Offset [web citation]
Frechet CDF Based A With Exponential Growth And Offset 2D		y = exp(-1.0 / x^a) y = y * (b * exp(x)) + Offset [web citation]
Frechet CDF Based B With Exponential Growth And Offset 2D		y = b * exp(-1.0 / x^a) y = y * exp(x) + Offset [web citation]
Frechet PDF Based A With Exponential Growth And Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * (b * exp(x)) + Offset [web citation]
Frechet PDF Based B With Exponential Growth And Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * exp(x) + Offset [web citation]
Genlogistic CDF Based A With Exponential Growth And Offset 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y * (d * exp(x)) + Offset [web citation]
Genlogistic CDF Based B With Exponential Growth And Offset 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y * exp(x) + Offset [web citation]
Genlogistic PDF Based With Exponential Growth And Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y * (d * exp(x)) + Offset [web citation]
Gompertz CDF Based Scaled With Exponential Growth And Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y * exp(x) + Offset [web citation]
Gompertz CDF Based With Exponential Growth And Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y * (c * exp(x)) + Offset [web citation]
Gumbel CDF Based With Exponential Growth And Offset 2D		y = a * exp(-exp(-x)) y = y * exp(x) + Offset [web citation]
Gumbel PDF Based With Exponential Growth And Offset 2D		y = a * exp(-x-exp(-x)) y = y * exp(x) + Offset [web citation]
Half Normal PDF Based With Exponential Growth And Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y * exp(x) + Offset [web citation]
Inverse_gaussian PDF Based A With Exponential Growth And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y (d * exp(x)) + Offset [web citation]
Inverse_gaussian PDF Based B With Exponential Growth And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y exp(x) + Offset [web citation]
Levy PDF Based Scaled With Exponential Growth And Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y exp(x) + Offset [web citation]
Levy PDF Based With Exponential Growth And Offset 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y (c * exp(x)) + Offset [web citation]
Log Normal PDF Based With Exponential Growth And Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y * (c * exp(x)) + Offset [web citation]
Logistic PDF Based With Exponential Growth And Offset 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y (c * exp(x)) + Offset [web citation]
Pareto PDF Based With Exponential Growth And Offset 2D		y = b * a^b / x^(b+1.0) y = y * (c * exp(x)) + Offset [web citation]
Power PDF Based With Exponential Growth And Offset 2D		y = (a/b) * (x/b)^(a-1.0) y = y * (c * exp(x)) + Offset [web citation]
Rayleigh CDF Based A With Exponential Growth And Offset 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y (b * exp(x)) + Offset [web citation]
Rayleigh CDF Based B With Exponential Growth And Offset 2D		y = b * exp(-x²/(2.0a²)) y = y exp(x) + Offset [web citation]
Rayleigh PDF Based Scaled With Exponential Growth And Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0a²)) y = y exp(x) + Offset [web citation]
Rayleigh PDF Based With Exponential Growth And Offset 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y (b * exp(x)) + Offset [web citation]
Reciprocal CDF Based With Exponential Growth And Offset 2D		y = ln(a/x) / ln(a/b) y = y * (c * exp(x)) + Offset [web citation]
Sech CDF Based With Exponential Growth And Offset 2D		y = c * atan(exp((x-a)/b)) y = y * exp(x) + Offset [web citation]
Weibull CDF Based A With Exponential Growth And Offset 2D		y = 1.0 / exp(((x-a)/b)^c) y = y * (d * exp(x)) + Offset [web citation]
Weibull CDF Based B With Exponential Growth And Offset 2D		y = d / exp(((x-a)/b)^c) y = y * exp(x) + Offset [web citation]
Weibull PDF Based With Exponential Growth And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y * (d * exp(x)) + Offset [web citation]



Arcsin CDF Based With Exponential Growth 2D		y = a * asin( (bx+c) / d) y = y * exp(x) [web citation]
Arcsin PDF Based With Exponential Growth 2D		y = a / sqrt( b² - x²) y = y * exp(x) [web citation]
Bradford CDF Based A With Exponential Growth 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y (d * exp(x)) [web citation]
Bradford CDF Based B With Exponential Growth 2D		y = d * ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y exp(x) [web citation]
Bradford PDF Based With Exponential Growth 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y * exp(x) [web citation]
Burr CDF Based A With Exponential Growth 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y * (f * exp(x)) [web citation]
Burr CDF Based B With Exponential Growth 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y * exp(x) [web citation]
Burr PDF Based With Exponential Growth 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y * (f * exp(x)) [web citation]
Dipole CDF Based With Exponential Growth 2D		y = a * arctan(x) + b/x y = y * (c * exp(x)) [web citation]
Exponential PDF Based Scaled With Exponential Growth 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y * exp(x) [web citation]
Exponential PDF Based With Exponential Growth 2D		y = (1.0/b) * exp((a-x)/b) y = y * (c * exp(x)) [web citation]
Extreme Values CDF Based A With Exponential Growth 2D		y = exp(-exp(-((x-a)/b))) y = y * (c * exp(x)) [web citation]
Extreme Values CDF Based B With Exponential Growth 2D		y = c * exp(-exp(-((x-a)/b))) y = y * exp(x) [web citation]
Extreme Values PDF Based With Exponential Growth 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y * (c * exp(x)) [web citation]
Fisk CDF Based A With Exponential Growth 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y * (d * exp(x)) [web citation]
Fisk CDF Based B With Exponential Growth 2D		y = d / (1.0+(b/(x-a))^c) y = y * exp(x) [web citation]
Fisk PDF Based With Exponential Growth 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y * (d * exp(x)) [web citation]
Folded Normal PDF Based With Exponential Growth 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y * exp(x) [web citation]
Frechet CDF Based A With Exponential Growth 2D		y = exp(-1.0 / x^a) y = y * (b * exp(x)) [web citation]
Frechet CDF Based B With Exponential Growth 2D		y = b * exp(-1.0 / x^a) y = y * exp(x) [web citation]
Frechet PDF Based A With Exponential Growth 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * (b * exp(x)) [web citation]
Frechet PDF Based B With Exponential Growth 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * exp(x) [web citation]
Genlogistic CDF Based A With Exponential Growth 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y * (d * exp(x)) [web citation]
Genlogistic CDF Based B With Exponential Growth 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y * exp(x) [web citation]
Genlogistic PDF Based With Exponential Growth 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y * (d * exp(x)) [web citation]
Gompertz CDF Based Scaled With Exponential Growth 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y * exp(x) [web citation]
Gompertz CDF Based With Exponential Growth 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y * (c * exp(x)) [web citation]
Gumbel CDF Based With Exponential Growth 2D		y = a * exp(-exp(-x)) y = y * exp(x) [web citation]
Gumbel PDF Based With Exponential Growth 2D		y = a * exp(-x-exp(-x)) y = y * exp(x) [web citation]
Half Normal PDF Based With Exponential Growth 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y * exp(x) [web citation]
Inverse_gaussian PDF Based A With Exponential Growth 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y (d * exp(x)) [web citation]
Inverse_gaussian PDF Based B With Exponential Growth 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y exp(x) [web citation]
Levy PDF Based Scaled With Exponential Growth 2D		y = Scale * b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y exp(x) [web citation]
Levy PDF Based With Exponential Growth 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y (c * exp(x)) [web citation]
Log Normal PDF Based With Exponential Growth 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y * (c * exp(x)) [web citation]
Logistic PDF Based With Exponential Growth 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y (c * exp(x)) [web citation]
Pareto PDF Based With Exponential Growth 2D		y = b * a^b / x^(b+1.0) y = y * (c * exp(x)) [web citation]
Power PDF Based With Exponential Growth 2D		y = (a/b) * (x/b)^(a-1.0) y = y * (c * exp(x)) [web citation]
Rayleigh CDF Based A With Exponential Growth 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y (b * exp(x)) [web citation]
Rayleigh CDF Based B With Exponential Growth 2D		y = b * exp(-x²/(2.0a²)) y = y exp(x) [web citation]
Rayleigh PDF Based Scaled With Exponential Growth 2D		y = Scale * (x/a²) * exp(-x²/(2.0a²)) y = y exp(x) [web citation]
Rayleigh PDF Based With Exponential Growth 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y (b * exp(x)) [web citation]
Reciprocal CDF Based With Exponential Growth 2D		y = ln(a/x) / ln(a/b) y = y * (c * exp(x)) [web citation]
Sech CDF Based With Exponential Growth 2D		y = c * atan(exp((x-a)/b)) y = y * exp(x) [web citation]
Weibull CDF Based A With Exponential Growth 2D		y = 1.0 / exp(((x-a)/b)^c) y = y * (d * exp(x)) [web citation]
Weibull CDF Based B With Exponential Growth 2D		y = d / exp(((x-a)/b)^c) y = y * exp(x) [web citation]
Weibull PDF Based With Exponential Growth 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y * (d * exp(x)) [web citation]



Inverse Arcsin CDF Based 2D		y = a * asin( (bx+c) / d) y = x / y [web citation]
Inverse Arcsin PDF Based 2D		y = a / sqrt( b² - x²) y = x / y [web citation]
Inverse Bradford CDF Based A 2D		y = ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = x / y [web citation]
Inverse Bradford CDF Based B 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = x / y [web citation]
Inverse Bradford PDF Based 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = x / y [web citation]
Inverse Burr PDF Based 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = x / y [web citation]
Inverse Dipole CDF Based 2D		y = a * arctan(x) + b/x y = x / y [web citation]
Inverse Exponential PDF Based 2D		y = (1.0/b) * exp((a-x)/b) y = x / y [web citation]
Inverse Exponential PDF Based Scaled 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = x / y [web citation]
Inverse Extreme Values CDF Based A 2D		y = exp(-exp(-((x-a)/b))) y = x / y [web citation]
Inverse Extreme Values CDF Based B 2D		y = c * exp(-exp(-((x-a)/b))) y = x / y [web citation]
Inverse Extreme Values PDF Based 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = x / y [web citation]
Inverse Folded Normal PDF Based 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = x / y [web citation]
Inverse Frechet CDF Based A 2D		y = exp(-1.0 / x^a) y = x / y [web citation]
Inverse Frechet CDF Based B 2D		y = b * exp(-1.0 / x^a) y = x / y [web citation]
Inverse Frechet PDF Based A 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = x / y [web citation]
Inverse Frechet PDF Based B 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = x / y [web citation]
Inverse Genlogistic PDF Based 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = x / y [web citation]
Inverse Gompertz CDF Based 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = x / y [web citation]
Inverse Gompertz CDF Based Scaled 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = x / y [web citation]
Inverse Gumbel CDF Based 2D		y = a * exp(-exp(-x)) y = x / y [web citation]
Inverse Gumbel PDF Based 2D		y = a * exp(-x-exp(-x)) y = x / y [web citation]
Inverse Half Normal PDF Based 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = x / y [web citation]
Inverse Inverse_gaussian PDF Based A 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = x / y [web citation]
Inverse Inverse_gaussian PDF Based B 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = x / y [web citation]
Inverse Levy PDF Based 2D		y = b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = x / y [web citation]
Inverse Levy PDF Based Scaled 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = x / y [web citation]
Inverse Log Normal PDF Based 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = x / y [web citation]
Inverse Logistic PDF Based 2D		y = exp((a-x)/b) / (b*(1.0+exp((a-x)/b))²) y = x / y [web citation]
Inverse Pareto PDF Based 2D		y = b * a^b / x^(b+1.0) y = x / y [web citation]
Inverse Power PDF Based 2D		y = (a/b) * (x/b)^(a-1.0) y = x / y [web citation]
Inverse Rayleigh CDF Based A 2D		y = 1.0 - exp(-x²/(2.0*a²)) y = x / y [web citation]
Inverse Rayleigh CDF Based B 2D		y = b * exp(-x²/(2.0*a²)) y = x / y [web citation]
Inverse Rayleigh PDF Based 2D		y = (x/a²) * exp(-x²/(2.0*a²)) y = x / y [web citation]
Inverse Rayleigh PDF Based Scaled 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = x / y [web citation]
Inverse Reciprocal CDF Based 2D		y = ln(a/x) / ln(a/b) y = x / y [web citation]
Inverse Sech CDF Based 2D		y = c * atan(exp((x-a)/b)) y = x / y [web citation]
Inverse Weibull PDF Based 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = x / y [web citation]



Inverse Arcsin CDF Based With Offset 2D		y = a * asin( (bx+c) / d) y = x / y + Offset [web citation]
Inverse Arcsin PDF Based With Offset 2D		y = a / sqrt( b² - x²) y = x / y + Offset [web citation]
Inverse Bradford CDF Based A With Offset 2D		y = ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = x / y + Offset [web citation]
Inverse Bradford CDF Based B With Offset 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = x / y + Offset [web citation]
Inverse Bradford PDF Based With Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = x / y + Offset [web citation]
Inverse Burr PDF Based With Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = x / y + Offset [web citation]
Inverse Dipole CDF Based With Offset 2D		y = a * arctan(x) + b/x y = x / y + Offset [web citation]
Inverse Exponential PDF Based Scaled With Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = x / y + Offset [web citation]
Inverse Exponential PDF Based With Offset 2D		y = (1.0/b) * exp((a-x)/b) y = x / y + Offset [web citation]
Inverse Extreme Values CDF Based A With Offset 2D		y = exp(-exp(-((x-a)/b))) y = x / y + Offset [web citation]
Inverse Extreme Values CDF Based B With Offset 2D		y = c * exp(-exp(-((x-a)/b))) y = x / y + Offset [web citation]
Inverse Extreme Values PDF Based With Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = x / y + Offset [web citation]
Inverse Folded Normal PDF Based With Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = x / y + Offset [web citation]
Inverse Frechet CDF Based A With Offset 2D		y = exp(-1.0 / x^a) y = x / y + Offset [web citation]
Inverse Frechet CDF Based B With Offset 2D		y = b * exp(-1.0 / x^a) y = x / y + Offset [web citation]
Inverse Frechet PDF Based A With Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = x / y + Offset [web citation]
Inverse Frechet PDF Based B With Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = x / y + Offset [web citation]
Inverse Genlogistic PDF Based With Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = x / y + Offset [web citation]
Inverse Gompertz CDF Based Scaled With Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = x / y + Offset [web citation]
Inverse Gompertz CDF Based With Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = x / y + Offset [web citation]
Inverse Gumbel CDF Based With Offset 2D		y = a * exp(-exp(-x)) y = x / y + Offset [web citation]
Inverse Gumbel PDF Based With Offset 2D		y = a * exp(-x-exp(-x)) y = x / y + Offset [web citation]
Inverse Half Normal PDF Based With Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = x / y + Offset [web citation]
Inverse Inverse_gaussian PDF Based A With Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = x / y + Offset [web citation]
Inverse Inverse_gaussian PDF Based B With Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = x / y + Offset [web citation]
Inverse Levy PDF Based Scaled With Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = x / y + Offset [web citation]
Inverse Levy PDF Based With Offset 2D		y = b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = x / y + Offset [web citation]
Inverse Log Normal PDF Based With Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = x / y + Offset [web citation]
Inverse Logistic PDF Based With Offset 2D		y = exp((a-x)/b) / (b*(1.0+exp((a-x)/b))²) y = x / y + Offset [web citation]
Inverse Pareto PDF Based With Offset 2D		y = b * a^b / x^(b+1.0) y = x / y + Offset [web citation]
Inverse Power PDF Based With Offset 2D		y = (a/b) * (x/b)^(a-1.0) y = x / y + Offset [web citation]
Inverse Rayleigh CDF Based A With Offset 2D		y = 1.0 - exp(-x²/(2.0*a²)) y = x / y + Offset [web citation]
Inverse Rayleigh CDF Based B With Offset 2D		y = b * exp(-x²/(2.0*a²)) y = x / y + Offset [web citation]
Inverse Rayleigh PDF Based Scaled With Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = x / y + Offset [web citation]
Inverse Rayleigh PDF Based With Offset 2D		y = (x/a²) * exp(-x²/(2.0*a²)) y = x / y + Offset [web citation]
Inverse Reciprocal CDF Based With Offset 2D		y = ln(a/x) / ln(a/b) y = x / y + Offset [web citation]
Inverse Sech CDF Based With Offset 2D		y = c * atan(exp((x-a)/b)) y = x / y + Offset [web citation]
Inverse Weibull PDF Based With Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = x / y + Offset [web citation]



Arcsin CDF Based With Linear Decay And Offset 2D		y = a * asin( (bx+c) / d) y = y / x + Offset [web citation]
Arcsin PDF Based With Linear Decay And Offset 2D		y = a / sqrt( b² - x²) y = y / x + Offset [web citation]
Bradford CDF Based A With Linear Decay And Offset 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y / (d x) + Offset [web citation]
Bradford CDF Based B With Linear Decay And Offset 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = y / x + Offset [web citation]
Bradford PDF Based With Linear Decay And Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y / x + Offset [web citation]
Burr CDF Based A With Linear Decay And Offset 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y / (f * x) + Offset [web citation]
Burr CDF Based B With Linear Decay And Offset 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y / x + Offset [web citation]
Burr PDF Based With Linear Decay And Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y / (f * x) + Offset [web citation]
Dipole CDF Based With Linear Decay And Offset 2D		y = a * arctan(x) + b/x y = y / (c * x) + Offset [web citation]
Exponential PDF Based Scaled With Linear Decay And Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y / x + Offset [web citation]
Exponential PDF Based With Linear Decay And Offset 2D		y = (1.0/b) * exp((a-x)/b) y = y / (c * x) + Offset [web citation]
Extreme Values CDF Based A With Linear Decay And Offset 2D		y = exp(-exp(-((x-a)/b))) y = y / (c * x) + Offset [web citation]
Extreme Values CDF Based B With Linear Decay And Offset 2D		y = c * exp(-exp(-((x-a)/b))) y = y / x + Offset [web citation]
Extreme Values PDF Based With Linear Decay And Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y / (c * x) + Offset [web citation]
Fisk CDF Based A With Linear Decay And Offset 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y / (d * x) + Offset [web citation]
Fisk CDF Based B With Linear Decay And Offset 2D		y = d / (1.0+(b/(x-a))^c) y = y / x + Offset [web citation]
Fisk PDF Based With Linear Decay And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y / (d * x) + Offset [web citation]
Folded Normal PDF Based With Linear Decay And Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y / x + Offset [web citation]
Frechet CDF Based A With Linear Decay And Offset 2D		y = exp(-1.0 / x^a) y = y / (b * x) + Offset [web citation]
Frechet CDF Based B With Linear Decay And Offset 2D		y = b * exp(-1.0 / x^a) y = y / x + Offset [web citation]
Frechet PDF Based A With Linear Decay And Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / (b * x) + Offset [web citation]
Frechet PDF Based B With Linear Decay And Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / x + Offset [web citation]
Genlogistic CDF Based A With Linear Decay And Offset 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y / (d * x) + Offset [web citation]
Genlogistic CDF Based B With Linear Decay And Offset 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y / x + Offset [web citation]
Genlogistic PDF Based With Linear Decay And Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y / (d * x) + Offset [web citation]
Gompertz CDF Based Scaled With Linear Decay And Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y / x + Offset [web citation]
Gompertz CDF Based With Linear Decay And Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y / (c * x) + Offset [web citation]
Gumbel CDF Based With Linear Decay And Offset 2D		y = a * exp(-exp(-x)) y = y / x + Offset [web citation]
Gumbel PDF Based With Linear Decay And Offset 2D		y = a * exp(-x-exp(-x)) y = y / x + Offset [web citation]
Half Normal PDF Based With Linear Decay And Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y / x + Offset [web citation]
Inverse_gaussian PDF Based A With Linear Decay And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y / (d x) + Offset [web citation]
Inverse_gaussian PDF Based B With Linear Decay And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = y / x + Offset [web citation]
Levy PDF Based Scaled With Linear Decay And Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = y / x + Offset [web citation]
Levy PDF Based With Linear Decay And Offset 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y / (c x) + Offset [web citation]
Log Normal PDF Based With Linear Decay And Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y / (c * x) + Offset [web citation]
Logistic PDF Based With Linear Decay And Offset 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y / (c x) + Offset [web citation]
Pareto PDF Based With Linear Decay And Offset 2D		y = b * a^b / x^(b+1.0) y = y / (c * x) + Offset [web citation]
Power PDF Based With Linear Decay And Offset 2D		y = (a/b) * (x/b)^(a-1.0) y = y / (c * x) + Offset [web citation]
Rayleigh CDF Based A With Linear Decay And Offset 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y / (b x) + Offset [web citation]
Rayleigh CDF Based B With Linear Decay And Offset 2D		y = b * exp(-x²/(2.0*a²)) y = y / x + Offset [web citation]
Rayleigh PDF Based Scaled With Linear Decay And Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = y / x + Offset [web citation]
Rayleigh PDF Based With Linear Decay And Offset 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y / (b x) + Offset [web citation]
Reciprocal CDF Based With Linear Decay And Offset 2D		y = ln(a/x) / ln(a/b) y = y / (c * x) + Offset [web citation]
Sech CDF Based With Linear Decay And Offset 2D		y = c * atan(exp((x-a)/b)) y = y / x + Offset [web citation]
Weibull CDF Based A With Linear Decay And Offset 2D		y = 1.0 / exp(((x-a)/b)^c) y = y / (d * x) + Offset [web citation]
Weibull CDF Based B With Linear Decay And Offset 2D		y = d / exp(((x-a)/b)^c) y = y / x + Offset [web citation]
Weibull PDF Based With Linear Decay And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y / (d * x) + Offset [web citation]



Arcsin CDF Based With Linear Decay 2D		y = a * asin( (bx+c) / d) y = y / x [web citation]
Arcsin PDF Based With Linear Decay 2D		y = a / sqrt( b² - x²) y = y / x [web citation]
Bradford CDF Based A With Linear Decay 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y / (d x) [web citation]
Bradford CDF Based B With Linear Decay 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = y / x [web citation]
Bradford PDF Based With Linear Decay 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y / x [web citation]
Burr CDF Based A With Linear Decay 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y / (f * x) [web citation]
Burr CDF Based B With Linear Decay 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y / x [web citation]
Burr PDF Based With Linear Decay 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y / (f * x) [web citation]
Dipole CDF Based With Linear Decay 2D		y = a * arctan(x) + b/x y = y / (c * x) [web citation]
Exponential PDF Based Scaled With Linear Decay 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y / x [web citation]
Exponential PDF Based With Linear Decay 2D		y = (1.0/b) * exp((a-x)/b) y = y / (c * x) [web citation]
Extreme Values CDF Based A With Linear Decay 2D		y = exp(-exp(-((x-a)/b))) y = y / (c * x) [web citation]
Extreme Values CDF Based B With Linear Decay 2D		y = c * exp(-exp(-((x-a)/b))) y = y / x [web citation]
Extreme Values PDF Based With Linear Decay 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y / (c * x) [web citation]
Fisk CDF Based A With Linear Decay 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y / (d * x) [web citation]
Fisk CDF Based B With Linear Decay 2D		y = d / (1.0+(b/(x-a))^c) y = y / x [web citation]
Fisk PDF Based With Linear Decay 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y / (d * x) [web citation]
Folded Normal PDF Based With Linear Decay 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y / x [web citation]
Frechet CDF Based A With Linear Decay 2D		y = exp(-1.0 / x^a) y = y / (b * x) [web citation]
Frechet CDF Based B With Linear Decay 2D		y = b * exp(-1.0 / x^a) y = y / x [web citation]
Frechet PDF Based A With Linear Decay 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / (b * x) [web citation]
Frechet PDF Based B With Linear Decay 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y / x [web citation]
Genlogistic CDF Based A With Linear Decay 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y / (d * x) [web citation]
Genlogistic CDF Based B With Linear Decay 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y / x [web citation]
Genlogistic PDF Based With Linear Decay 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y / (d * x) [web citation]
Gompertz CDF Based Scaled With Linear Decay 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y / x [web citation]
Gompertz CDF Based With Linear Decay 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y / (c * x) [web citation]
Gumbel CDF Based With Linear Decay 2D		y = a * exp(-exp(-x)) y = y / x [web citation]
Gumbel PDF Based With Linear Decay 2D		y = a * exp(-x-exp(-x)) y = y / x [web citation]
Half Normal PDF Based With Linear Decay 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y / x [web citation]
Inverse_gaussian PDF Based A With Linear Decay 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y / (d x) [web citation]
Inverse_gaussian PDF Based B With Linear Decay 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = y / x [web citation]
Levy PDF Based Scaled With Linear Decay 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = y / x [web citation]
Levy PDF Based With Linear Decay 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y / (c x) [web citation]
Log Normal PDF Based With Linear Decay 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y / (c * x) [web citation]
Logistic PDF Based With Linear Decay 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y / (c x) [web citation]
Pareto PDF Based With Linear Decay 2D		y = b * a^b / x^(b+1.0) y = y / (c * x) [web citation]
Power PDF Based With Linear Decay 2D		y = (a/b) * (x/b)^(a-1.0) y = y / (c * x) [web citation]
Rayleigh CDF Based A With Linear Decay 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y / (b x) [web citation]
Rayleigh CDF Based B With Linear Decay 2D		y = b * exp(-x²/(2.0*a²)) y = y / x [web citation]
Rayleigh PDF Based Scaled With Linear Decay 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = y / x [web citation]
Rayleigh PDF Based With Linear Decay 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y / (b x) [web citation]
Reciprocal CDF Based With Linear Decay 2D		y = ln(a/x) / ln(a/b) y = y / (c * x) [web citation]
Sech CDF Based With Linear Decay 2D		y = c * atan(exp((x-a)/b)) y = y / x [web citation]
Weibull CDF Based A With Linear Decay 2D		y = 1.0 / exp(((x-a)/b)^c) y = y / (d * x) [web citation]
Weibull CDF Based B With Linear Decay 2D		y = d / exp(((x-a)/b)^c) y = y / x [web citation]
Weibull PDF Based With Linear Decay 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y / (d * x) [web citation]



Arcsin CDF Based With Linear Growth And Offset 2D		y = a * asin( (bx+c) / d) y = y * x + Offset [web citation]
Arcsin PDF Based With Linear Growth And Offset 2D		y = a / sqrt( b² - x²) y = y * x + Offset [web citation]
Bradford CDF Based A With Linear Growth And Offset 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y (d * x) + Offset [web citation]
Bradford CDF Based B With Linear Growth And Offset 2D		y = d * ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y x + Offset [web citation]
Bradford PDF Based With Linear Growth And Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y * x + Offset [web citation]
Burr CDF Based A With Linear Growth And Offset 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y * (f * x) + Offset [web citation]
Burr CDF Based B With Linear Growth And Offset 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y * x + Offset [web citation]
Burr PDF Based With Linear Growth And Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y * (f * x) + Offset [web citation]
Dipole CDF Based With Linear Growth And Offset 2D		y = a * arctan(x) + b/x y = y * (c * x) + Offset [web citation]
Exponential PDF Based Scaled With Linear Growth And Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y * x + Offset [web citation]
Exponential PDF Based With Linear Growth And Offset 2D		y = (1.0/b) * exp((a-x)/b) y = y * (c * x) + Offset [web citation]
Extreme Values CDF Based A With Linear Growth And Offset 2D		y = exp(-exp(-((x-a)/b))) y = y * (c * x) + Offset [web citation]
Extreme Values CDF Based B With Linear Growth And Offset 2D		y = c * exp(-exp(-((x-a)/b))) y = y * x + Offset [web citation]
Extreme Values PDF Based With Linear Growth And Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y * (c * x) + Offset [web citation]
Fisk CDF Based A With Linear Growth And Offset 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y * (d * x) + Offset [web citation]
Fisk CDF Based B With Linear Growth And Offset 2D		y = d / (1.0+(b/(x-a))^c) y = y * x + Offset [web citation]
Fisk PDF Based With Linear Growth And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y * (d * x) + Offset [web citation]
Folded Normal PDF Based With Linear Growth And Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y * x + Offset [web citation]
Frechet CDF Based A With Linear Growth And Offset 2D		y = exp(-1.0 / x^a) y = y * (b * x) + Offset [web citation]
Frechet CDF Based B With Linear Growth And Offset 2D		y = b * exp(-1.0 / x^a) y = y * x + Offset [web citation]
Frechet PDF Based A With Linear Growth And Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * (b * x) + Offset [web citation]
Frechet PDF Based B With Linear Growth And Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * x + Offset [web citation]
Genlogistic CDF Based A With Linear Growth And Offset 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y * (d * x) + Offset [web citation]
Genlogistic CDF Based B With Linear Growth And Offset 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y * x + Offset [web citation]
Genlogistic PDF Based With Linear Growth And Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y * (d * x) + Offset [web citation]
Gompertz CDF Based Scaled With Linear Growth And Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y * x + Offset [web citation]
Gompertz CDF Based With Linear Growth And Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y * (c * x) + Offset [web citation]
Gumbel CDF Based With Linear Growth And Offset 2D		y = a * exp(-exp(-x)) y = y * x + Offset [web citation]
Gumbel PDF Based With Linear Growth And Offset 2D		y = a * exp(-x-exp(-x)) y = y * x + Offset [web citation]
Half Normal PDF Based With Linear Growth And Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y * x + Offset [web citation]
Inverse_gaussian PDF Based A With Linear Growth And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y (d * x) + Offset [web citation]
Inverse_gaussian PDF Based B With Linear Growth And Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y x + Offset [web citation]
Levy PDF Based Scaled With Linear Growth And Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y x + Offset [web citation]
Levy PDF Based With Linear Growth And Offset 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y (c * x) + Offset [web citation]
Log Normal PDF Based With Linear Growth And Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y * (c * x) + Offset [web citation]
Logistic PDF Based With Linear Growth And Offset 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y (c * x) + Offset [web citation]
Pareto PDF Based With Linear Growth And Offset 2D		y = b * a^b / x^(b+1.0) y = y * (c * x) + Offset [web citation]
Power PDF Based With Linear Growth And Offset 2D		y = (a/b) * (x/b)^(a-1.0) y = y * (c * x) + Offset [web citation]
Rayleigh CDF Based A With Linear Growth And Offset 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y (b * x) + Offset [web citation]
Rayleigh CDF Based B With Linear Growth And Offset 2D		y = b * exp(-x²/(2.0a²)) y = y x + Offset [web citation]
Rayleigh PDF Based Scaled With Linear Growth And Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0a²)) y = y x + Offset [web citation]
Rayleigh PDF Based With Linear Growth And Offset 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y (b * x) + Offset [web citation]
Reciprocal CDF Based With Linear Growth And Offset 2D		y = ln(a/x) / ln(a/b) y = y * (c * x) + Offset [web citation]
Sech CDF Based With Linear Growth And Offset 2D		y = c * atan(exp((x-a)/b)) y = y * x + Offset [web citation]
Weibull CDF Based A With Linear Growth And Offset 2D		y = 1.0 / exp(((x-a)/b)^c) y = y * (d * x) + Offset [web citation]
Weibull CDF Based B With Linear Growth And Offset 2D		y = d / exp(((x-a)/b)^c) y = y * x + Offset [web citation]
Weibull PDF Based With Linear Growth And Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y * (d * x) + Offset [web citation]



Arcsin CDF Based With Linear Growth 2D		y = a * asin( (bx+c) / d) y = y * x [web citation]
Arcsin PDF Based With Linear Growth 2D		y = a / sqrt( b² - x²) y = y * x [web citation]
Bradford CDF Based A With Linear Growth 2D		y = ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y (d * x) [web citation]
Bradford CDF Based B With Linear Growth 2D		y = d * ln(1.0+c(x-a)/(b-a)) / ln(c+1.0) y = y x [web citation]
Bradford PDF Based With Linear Growth 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = y * x [web citation]
Burr CDF Based A With Linear Growth 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d y = y * (f * x) [web citation]
Burr CDF Based B With Linear Growth 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d y = y * x [web citation]
Burr PDF Based With Linear Growth 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = y * (f * x) [web citation]
Dipole CDF Based With Linear Growth 2D		y = a * arctan(x) + b/x y = y * (c * x) [web citation]
Exponential PDF Based Scaled With Linear Growth 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = y * x [web citation]
Exponential PDF Based With Linear Growth 2D		y = (1.0/b) * exp((a-x)/b) y = y * (c * x) [web citation]
Extreme Values CDF Based A With Linear Growth 2D		y = exp(-exp(-((x-a)/b))) y = y * (c * x) [web citation]
Extreme Values CDF Based B With Linear Growth 2D		y = c * exp(-exp(-((x-a)/b))) y = y * x [web citation]
Extreme Values PDF Based With Linear Growth 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y * (c * x) [web citation]
Fisk CDF Based A With Linear Growth 2D		y = 1.0 / (1.0+(b/(x-a))^c) y = y * (d * x) [web citation]
Fisk CDF Based B With Linear Growth 2D		y = d / (1.0+(b/(x-a))^c) y = y * x [web citation]
Fisk PDF Based With Linear Growth 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² y = y * (d * x) [web citation]
Folded Normal PDF Based With Linear Growth 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = y * x [web citation]
Frechet CDF Based A With Linear Growth 2D		y = exp(-1.0 / x^a) y = y * (b * x) [web citation]
Frechet CDF Based B With Linear Growth 2D		y = b * exp(-1.0 / x^a) y = y * x [web citation]
Frechet PDF Based A With Linear Growth 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * (b * x) [web citation]
Frechet PDF Based B With Linear Growth 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y * x [web citation]
Genlogistic CDF Based A With Linear Growth 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c y = y * (d * x) [web citation]
Genlogistic CDF Based B With Linear Growth 2D		y = (d/(1.0+exp(-(x-a)/b)))^c y = y * x [web citation]
Genlogistic PDF Based With Linear Growth 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = y * (d * x) [web citation]
Gompertz CDF Based Scaled With Linear Growth 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = y * x [web citation]
Gompertz CDF Based With Linear Growth 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y * (c * x) [web citation]
Gumbel CDF Based With Linear Growth 2D		y = a * exp(-exp(-x)) y = y * x [web citation]
Gumbel PDF Based With Linear Growth 2D		y = a * exp(-x-exp(-x)) y = y * x [web citation]
Half Normal PDF Based With Linear Growth 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = y * x [web citation]
Inverse_gaussian PDF Based A With Linear Growth 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y (d * x) [web citation]
Inverse_gaussian PDF Based B With Linear Growth 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²x)) y = y x [web citation]
Levy PDF Based Scaled With Linear Growth 2D		y = Scale * b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y x [web citation]
Levy PDF Based With Linear Growth 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y (c * x) [web citation]
Log Normal PDF Based With Linear Growth 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y * (c * x) [web citation]
Logistic PDF Based With Linear Growth 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y (c * x) [web citation]
Pareto PDF Based With Linear Growth 2D		y = b * a^b / x^(b+1.0) y = y * (c * x) [web citation]
Power PDF Based With Linear Growth 2D		y = (a/b) * (x/b)^(a-1.0) y = y * (c * x) [web citation]
Rayleigh CDF Based A With Linear Growth 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y (b * x) [web citation]
Rayleigh CDF Based B With Linear Growth 2D		y = b * exp(-x²/(2.0a²)) y = y x [web citation]
Rayleigh PDF Based Scaled With Linear Growth 2D		y = Scale * (x/a²) * exp(-x²/(2.0a²)) y = y x [web citation]
Rayleigh PDF Based With Linear Growth 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y (b * x) [web citation]
Reciprocal CDF Based With Linear Growth 2D		y = ln(a/x) / ln(a/b) y = y * (c * x) [web citation]
Sech CDF Based With Linear Growth 2D		y = c * atan(exp((x-a)/b)) y = y * x [web citation]
Weibull CDF Based A With Linear Growth 2D		y = 1.0 / exp(((x-a)/b)^c) y = y * (d * x) [web citation]
Weibull CDF Based B With Linear Growth 2D		y = d / exp(((x-a)/b)^c) y = y * x [web citation]
Weibull PDF Based With Linear Growth 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = y * (d * x) [web citation]



Reciprocal Arcsin CDF Based 2D		y = a * asin( (bx+c) / d) y = 1.0 / y [web citation]
Reciprocal Arcsin PDF Based 2D		y = a / sqrt( b² - x²) y = 1.0 / y [web citation]
Reciprocal Bradford CDF Based A 2D		y = ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = 1.0 / y [web citation]
Reciprocal Bradford CDF Based B 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = 1.0 / y [web citation]
Reciprocal Bradford PDF Based 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = 1.0 / y [web citation]
Reciprocal Burr PDF Based 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = 1.0 / y [web citation]
Reciprocal Dipole CDF Based 2D		y = a * arctan(x) + b/x y = 1.0 / y [web citation]
Reciprocal Exponential PDF Based 2D		y = (1.0/b) * exp((a-x)/b) y = 1.0 / y [web citation]
Reciprocal Exponential PDF Based Scaled 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = 1.0 / y [web citation]
Reciprocal Extreme Values CDF Based A 2D		y = exp(-exp(-((x-a)/b))) y = 1.0 / y [web citation]
Reciprocal Extreme Values CDF Based B 2D		y = c * exp(-exp(-((x-a)/b))) y = 1.0 / y [web citation]
Reciprocal Extreme Values PDF Based 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = 1.0 / y [web citation]
Reciprocal Folded Normal PDF Based 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = 1.0 / y [web citation]
Reciprocal Frechet CDF Based A 2D		y = exp(-1.0 / x^a) y = 1.0 / y [web citation]
Reciprocal Frechet CDF Based B 2D		y = b * exp(-1.0 / x^a) y = 1.0 / y [web citation]
Reciprocal Frechet PDF Based A 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = 1.0 / y [web citation]
Reciprocal Frechet PDF Based B 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = 1.0 / y [web citation]
Reciprocal Genlogistic PDF Based 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = 1.0 / y [web citation]
Reciprocal Gompertz CDF Based 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = 1.0 / y [web citation]
Reciprocal Gompertz CDF Based Scaled 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = 1.0 / y [web citation]
Reciprocal Gumbel CDF Based 2D		y = a * exp(-exp(-x)) y = 1.0 / y [web citation]
Reciprocal Gumbel PDF Based 2D		y = a * exp(-x-exp(-x)) y = 1.0 / y [web citation]
Reciprocal Half Normal PDF Based 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = 1.0 / y [web citation]
Reciprocal Inverse_gaussian PDF Based A 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = 1.0 / y [web citation]
Reciprocal Inverse_gaussian PDF Based B 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = 1.0 / y [web citation]
Reciprocal Levy PDF Based 2D		y = b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = 1.0 / y [web citation]
Reciprocal Levy PDF Based Scaled 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = 1.0 / y [web citation]
Reciprocal Log Normal PDF Based 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = 1.0 / y [web citation]
Reciprocal Logistic PDF Based 2D		y = exp((a-x)/b) / (b*(1.0+exp((a-x)/b))²) y = 1.0 / y [web citation]
Reciprocal Pareto PDF Based 2D		y = b * a^b / x^(b+1.0) y = 1.0 / y [web citation]
Reciprocal Power PDF Based 2D		y = (a/b) * (x/b)^(a-1.0) y = 1.0 / y [web citation]
Reciprocal Rayleigh CDF Based A 2D		y = 1.0 - exp(-x²/(2.0*a²)) y = 1.0 / y [web citation]
Reciprocal Rayleigh CDF Based B 2D		y = b * exp(-x²/(2.0*a²)) y = 1.0 / y [web citation]
Reciprocal Rayleigh PDF Based 2D		y = (x/a²) * exp(-x²/(2.0*a²)) y = 1.0 / y [web citation]
Reciprocal Rayleigh PDF Based Scaled 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = 1.0 / y [web citation]
Reciprocal Reciprocal CDF Based 2D		y = ln(a/x) / ln(a/b) y = 1.0 / y [web citation]
Reciprocal Sech CDF Based 2D		y = c * atan(exp((x-a)/b)) y = 1.0 / y [web citation]
Reciprocal Weibull PDF Based 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = 1.0 / y [web citation]



Reciprocal Arcsin CDF Based With Offset 2D		y = a * asin( (bx+c) / d) y = 1.0 / y + Offset [web citation]
Reciprocal Arcsin PDF Based With Offset 2D		y = a / sqrt( b² - x²) y = 1.0 / y + Offset [web citation]
Reciprocal Bradford CDF Based A With Offset 2D		y = ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = 1.0 / y + Offset [web citation]
Reciprocal Bradford CDF Based B With Offset 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) y = 1.0 / y + Offset [web citation]
Reciprocal Bradford PDF Based With Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) y = 1.0 / y + Offset [web citation]
Reciprocal Burr PDF Based With Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) y = 1.0 / y + Offset [web citation]
Reciprocal Dipole CDF Based With Offset 2D		y = a * arctan(x) + b/x y = 1.0 / y + Offset [web citation]
Reciprocal Exponential PDF Based Scaled With Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) y = 1.0 / y + Offset [web citation]
Reciprocal Exponential PDF Based With Offset 2D		y = (1.0/b) * exp((a-x)/b) y = 1.0 / y + Offset [web citation]
Reciprocal Extreme Values CDF Based A With Offset 2D		y = exp(-exp(-((x-a)/b))) y = 1.0 / y + Offset [web citation]
Reciprocal Extreme Values CDF Based B With Offset 2D		y = c * exp(-exp(-((x-a)/b))) y = 1.0 / y + Offset [web citation]
Reciprocal Extreme Values PDF Based With Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = 1.0 / y + Offset [web citation]
Reciprocal Folded Normal PDF Based With Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) y = 1.0 / y + Offset [web citation]
Reciprocal Frechet CDF Based A With Offset 2D		y = exp(-1.0 / x^a) y = 1.0 / y + Offset [web citation]
Reciprocal Frechet CDF Based B With Offset 2D		y = b * exp(-1.0 / x^a) y = 1.0 / y + Offset [web citation]
Reciprocal Frechet PDF Based A With Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = 1.0 / y + Offset [web citation]
Reciprocal Frechet PDF Based B With Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = 1.0 / y + Offset [web citation]
Reciprocal Genlogistic PDF Based With Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) y = 1.0 / y + Offset [web citation]
Reciprocal Gompertz CDF Based Scaled With Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) y = 1.0 / y + Offset [web citation]
Reciprocal Gompertz CDF Based With Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = 1.0 / y + Offset [web citation]
Reciprocal Gumbel CDF Based With Offset 2D		y = a * exp(-exp(-x)) y = 1.0 / y + Offset [web citation]
Reciprocal Gumbel PDF Based With Offset 2D		y = a * exp(-x-exp(-x)) y = 1.0 / y + Offset [web citation]
Reciprocal Half Normal PDF Based With Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) y = 1.0 / y + Offset [web citation]
Reciprocal Inverse_gaussian PDF Based A With Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = 1.0 / y + Offset [web citation]
Reciprocal Inverse_gaussian PDF Based B With Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) y = 1.0 / y + Offset [web citation]
Reciprocal Levy PDF Based Scaled With Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = 1.0 / y + Offset [web citation]
Reciprocal Levy PDF Based With Offset 2D		y = b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) y = 1.0 / y + Offset [web citation]
Reciprocal Log Normal PDF Based With Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = 1.0 / y + Offset [web citation]
Reciprocal Logistic PDF Based With Offset 2D		y = exp((a-x)/b) / (b*(1.0+exp((a-x)/b))²) y = 1.0 / y + Offset [web citation]
Reciprocal Pareto PDF Based With Offset 2D		y = b * a^b / x^(b+1.0) y = 1.0 / y + Offset [web citation]
Reciprocal Power PDF Based With Offset 2D		y = (a/b) * (x/b)^(a-1.0) y = 1.0 / y + Offset [web citation]
Reciprocal Rayleigh CDF Based A With Offset 2D		y = 1.0 - exp(-x²/(2.0*a²)) y = 1.0 / y + Offset [web citation]
Reciprocal Rayleigh CDF Based B With Offset 2D		y = b * exp(-x²/(2.0*a²)) y = 1.0 / y + Offset [web citation]
Reciprocal Rayleigh PDF Based Scaled With Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) y = 1.0 / y + Offset [web citation]
Reciprocal Rayleigh PDF Based With Offset 2D		y = (x/a²) * exp(-x²/(2.0*a²)) y = 1.0 / y + Offset [web citation]
Reciprocal Reciprocal CDF Based With Offset 2D		y = ln(a/x) / ln(a/b) y = 1.0 / y + Offset [web citation]
Reciprocal Sech CDF Based With Offset 2D		y = c * atan(exp((x-a)/b)) y = 1.0 / y + Offset [web citation]
Reciprocal Weibull PDF Based With Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) y = 1.0 / y + Offset [web citation]



Arcsin CDF Based 2D		y = a * asin( (bx+c) / d) [web citation]
Arcsin PDF Based 2D		y = a / sqrt( b² - x²) [web citation]
Bradford CDF Based A 2D		y = ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) [web citation]
Bradford CDF Based B 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) [web citation]
Bradford PDF Based 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) [web citation]
Burr CDF Based A 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d [web citation]
Burr CDF Based B 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d [web citation]
Burr PDF Based 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) [web citation]
Dipole CDF Based 2D		y = a * arctan(x) + b/x [web citation]
Exponential PDF Based 2D		y = (1.0/b) * exp((a-x)/b) [web citation]
Exponential PDF Based Scaled 2D		y = Scale * (1.0/b) * exp((a-x)/b) [web citation]
Extreme Values CDF Based A 2D		y = exp(-exp(-((x-a)/b))) [web citation]
Extreme Values CDF Based B 2D		y = c * exp(-exp(-((x-a)/b))) [web citation]
Extreme Values PDF Based 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) [web citation]
Fisk CDF Based A 2D		y = 1.0 / (1.0+(b/(x-a))^c) [web citation]
Fisk CDF Based B 2D		y = d / (1.0+(b/(x-a))^c) [web citation]
Fisk PDF Based 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² [web citation]
Folded Normal PDF Based 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) [web citation]
Frechet CDF Based A 2D		y = exp(-1.0 / x^a) [web citation]
Frechet CDF Based B 2D		y = b * exp(-1.0 / x^a) [web citation]
Frechet PDF Based A 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} [web citation]
Frechet PDF Based B 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} [web citation]
Genlogistic CDF Based A 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c [web citation]
Genlogistic CDF Based B 2D		y = (d/(1.0+exp(-(x-a)/b)))^c [web citation]
Genlogistic PDF Based 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) [web citation]
Gompertz CDF Based 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) [web citation]
Gompertz CDF Based Scaled 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) [web citation]
Gumbel CDF Based 2D		y = a * exp(-exp(-x)) [web citation]
Gumbel PDF Based 2D		y = a * exp(-x-exp(-x)) [web citation]
Half Normal PDF Based 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) [web citation]
Inverse_gaussian PDF Based A 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) [web citation]
Inverse_gaussian PDF Based B 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) [web citation]
Levy PDF Based 2D		y = b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) [web citation]
Levy PDF Based Scaled 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) [web citation]
Log Normal PDF Based 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) [web citation]
Logistic PDF Based 2D		y = exp((a-x)/b) / (b*(1.0+exp((a-x)/b))²) [web citation]
Pareto PDF Based 2D		y = b * a^b / x^(b+1.0) [web citation]
Power PDF Based 2D		y = (a/b) * (x/b)^(a-1.0) [web citation]
Rayleigh CDF Based A 2D		y = 1.0 - exp(-x²/(2.0*a²)) [web citation]
Rayleigh CDF Based B 2D		y = b * exp(-x²/(2.0*a²)) [web citation]
Rayleigh PDF Based 2D		y = (x/a²) * exp(-x²/(2.0*a²)) [web citation]
Rayleigh PDF Based Scaled 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) [web citation]
Reciprocal CDF Based 2D		y = ln(a/x) / ln(a/b) [web citation]
Sech CDF Based 2D		y = c * atan(exp((x-a)/b)) [web citation]
Weibull CDF Based A 2D		y = 1.0 / exp(((x-a)/b)^c) [web citation]
Weibull CDF Based B 2D		y = d / exp(((x-a)/b)^c) [web citation]
Weibull PDF Based 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) [web citation]



Arcsin CDF Based With Offset 2D		y = a * asin( (bx+c) / d) + Offset [web citation]
Arcsin PDF Based With Offset 2D		y = a / sqrt( b² - x²) + Offset [web citation]
Bradford CDF Based A With Offset 2D		y = ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) + Offset [web citation]
Bradford CDF Based B With Offset 2D		y = d * ln(1.0+c*(x-a)/(b-a)) / ln(c+1.0) + Offset [web citation]
Bradford PDF Based With Offset 2D		y = c / (( c * (x-a) + b-a) * ln(c + 1.0)) + Offset [web citation]
Burr CDF Based A With Offset 2D		y = 1.0 / ( 1.0 + ( b / ( x-a ))^c)^d + Offset [web citation]
Burr CDF Based B With Offset 2D		y = f / ( 1.0 + ( b / ( x-a ))^c)^d + Offset [web citation]
Burr PDF Based With Offset 2D		y = (cd/b) ((x-a)/b)^(-c-1.0) * (1.0+((x-a)/b)^(-c))^(-d-1.0) + Offset [web citation]
Dipole CDF Based With Offset 2D		y = a * arctan(x) + b/x + Offset [web citation]
Exponential PDF Based Scaled With Offset 2D		y = Scale * (1.0/b) * exp((a-x)/b) + Offset [web citation]
Exponential PDF Based With Offset 2D		y = (1.0/b) * exp((a-x)/b) + Offset [web citation]
Extreme Values CDF Based A With Offset 2D		y = exp(-exp(-((x-a)/b))) + Offset [web citation]
Extreme Values CDF Based B With Offset 2D		y = c * exp(-exp(-((x-a)/b))) + Offset [web citation]
Extreme Values PDF Based With Offset 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) + Offset [web citation]
Fisk CDF Based A With Offset 2D		y = 1.0 / (1.0+(b/(x-a))^c) + Offset [web citation]
Fisk CDF Based B With Offset 2D		y = d / (1.0+(b/(x-a))^c) + Offset [web citation]
Fisk PDF Based With Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / (1.0 + ((x-a)/b)^c)² + Offset [web citation]
Folded Normal PDF Based With Offset 2D		y = c * (1/b) * cosh(ax/b²) exp(-0.5 * (x² + a²)/b²) + Offset [web citation]
Frechet CDF Based A With Offset 2D		y = exp(-1.0 / x^a) + Offset [web citation]
Frechet CDF Based B With Offset 2D		y = b * exp(-1.0 / x^a) + Offset [web citation]
Frechet PDF Based A With Offset 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} + Offset [web citation]
Frechet PDF Based B With Offset 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} + Offset [web citation]
Genlogistic CDF Based A With Offset 2D		y = (1.0/(1.0+exp(-(x-a)/b)))^c + Offset [web citation]
Genlogistic CDF Based B With Offset 2D		y = (d/(1.0+exp(-(x-a)/b)))^c + Offset [web citation]
Genlogistic PDF Based With Offset 2D		y = (c/b) * exp(-((x-a)/b)) / (1.0+exp(-((x-a)/b)))^(c+1.0) + Offset [web citation]
Gompertz CDF Based Scaled With Offset 2D		y = Scale * (1.0 - exp(-b * (a^x-1.0) / ln(a))) + Offset [web citation]
Gompertz CDF Based With Offset 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) + Offset [web citation]
Gumbel CDF Based With Offset 2D		y = a * exp(-exp(-x)) + Offset [web citation]
Gumbel PDF Based With Offset 2D		y = a * exp(-x-exp(-x)) + Offset [web citation]
Half Normal PDF Based With Offset 2D		y = c * ( 1.0/b) * exp(-0.5((x-a)/b)((x-a)/b)) + Offset [web citation]
Inverse_gaussian PDF Based A With Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) + Offset [web citation]
Inverse_gaussian PDF Based B With Offset 2D		y = sqrt(b/(cx³))exp(-b(x-a)² / (2.0a²*x)) + Offset [web citation]
Levy PDF Based Scaled With Offset 2D		y = Scale * b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) + Offset [web citation]
Levy PDF Based With Offset 2D		y = b^0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)³) + Offset [web citation]
Log Normal PDF Based With Offset 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) + Offset [web citation]
Logistic PDF Based With Offset 2D		y = exp((a-x)/b) / (b*(1.0+exp((a-x)/b))²) + Offset [web citation]
Pareto PDF Based With Offset 2D		y = b * a^b / x^(b+1.0) + Offset [web citation]
Power PDF Based With Offset 2D		y = (a/b) * (x/b)^(a-1.0) + Offset [web citation]
Rayleigh CDF Based A With Offset 2D		y = 1.0 - exp(-x²/(2.0*a²)) + Offset [web citation]
Rayleigh CDF Based B With Offset 2D		y = b * exp(-x²/(2.0*a²)) + Offset [web citation]
Rayleigh PDF Based Scaled With Offset 2D		y = Scale * (x/a²) * exp(-x²/(2.0*a²)) + Offset [web citation]
Rayleigh PDF Based With Offset 2D		y = (x/a²) * exp(-x²/(2.0*a²)) + Offset [web citation]
Reciprocal CDF Based With Offset 2D		y = ln(a/x) / ln(a/b) + Offset [web citation]
Sech CDF Based With Offset 2D		y = c * atan(exp((x-a)/b)) + Offset [web citation]
Weibull CDF Based A With Offset 2D		y = 1.0 / exp(((x-a)/b)^c) + Offset [web citation]
Weibull CDF Based B With Offset 2D		y = d / exp(((x-a)/b)^c) + Offset [web citation]
Weibull PDF Based With Offset 2D		y = (c/b) * ((x-a)/b)^(c-1.0) / exp(((x-a)/b)^c) + Offset [web citation]



Arcsin PDF Based Plus Line 2D		y = a / sqrt( b² - x²) y = y + (c * x) + d [web citation]
Dipole CDF Based Plus Line 2D		y = a * arctan(x) + b/x y = y + (c * x) + d [web citation]
Exponential PDF Based Plus Line 2D		y = (1.0/b) * exp((a-x)/b) y = y + (c * x) + d [web citation]
Extreme Values CDF Based A Plus Line 2D		y = exp(-exp(-((x-a)/b))) y = y + (c * x) + d [web citation]
Extreme Values PDF Based Plus Line 2D		y = (1.0/b) * exp(((a-x)/b)-exp((a-x)/b)) y = y + (c * x) + d [web citation]
Frechet CDF Based A Plus Line 2D		y = exp(-1.0 / x^a) y = y + (b * x) + c [web citation]
Frechet CDF Based B Plus Line 2D		y = b * exp(-1.0 / x^a) y = y + (c * x) + d [web citation]
Frechet PDF Based A Plus Line 2D		y = exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y + (b * x) + c [web citation]
Frechet PDF Based B Plus Line 2D		y = b * exp(- 1.0 / x^a) / x^{( a + 1.0)} y = y + (c * x) + d [web citation]
Gompertz CDF Based Plus Line 2D		y = 1.0 - exp(-b * (a^x-1.0) / ln(a)) y = y + (c * x) + d [web citation]
Gumbel CDF Based Plus Line 2D		y = a * exp(-exp(-x)) y = y + (b * x) + c [web citation]
Gumbel PDF Based Plus Line 2D		y = a * exp(-x-exp(-x)) y = y + (b * x) + c [web citation]
Levy PDF Based Plus Line 2D		y = b^0.5 * exp(-b/(2.0(x-a)))/sqrt((x-a)³) y = y + (c x) + d [web citation]
Log Normal PDF Based Plus Line 2D		y = exp(-0.5((ln(x)-a)/b)²) / (bx) y = y + (c * x) + d [web citation]
Logistic PDF Based Plus Line 2D		y = exp((a-x)/b) / (b(1.0+exp((a-x)/b))²) y = y + (c x) + d [web citation]
Pareto PDF Based Plus Line 2D		y = b * a^b / x^(b+1.0) y = y + (c * x) + d [web citation]
Power PDF Based Plus Line 2D		y = (a/b) * (x/b)^(a-1.0) y = y + (c * x) + d [web citation]
Rayleigh CDF Based A Plus Line 2D		y = 1.0 - exp(-x²/(2.0a²)) y = y + (b x) + c [web citation]
Rayleigh CDF Based B Plus Line 2D		y = b * exp(-x²/(2.0a²)) y = y + (c x) + d [web citation]
Rayleigh PDF Based Plus Line 2D		y = (x/a²) * exp(-x²/(2.0a²)) y = y + (b x) + c [web citation]
Rayleigh PDF Based Scaled Plus Line 2D		y = Scale * (x/a²) * exp(-x²/(2.0a²)) y = y + (c x) + d [web citation]
Reciprocal CDF Based Plus Line 2D		y = ln(a/x) / ln(a/b) y = y + (c * x) + d [web citation]

2D Engineering

Electron Beam Lithography Point Spread With Exponential Decay And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y / (n exp(x)) + Offset
Graeme Paterson Electric Motor With Exponential Decay And Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y / (h * exp(x)) + Offset
Klimpel Kinetics Flotation A With Exponential Decay And Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y / exp(x) + Offset
Maxwell - Wiechert 1 With Exponential Decay And Offset 2D		y = a1*exp(-X/Tau1) y = y / exp(x) + Offset [web citation]
Maxwell - Wiechert 2 With Exponential Decay And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y / (f * exp(x)) + Offset [web citation]
Maxwell - Wiechert 3 With Exponential Decay And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y / (h exp(x)) + Offset [web citation]
Maxwell - Wiechert 4 With Exponential Decay And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y / (j * exp(x)) + Offset [web citation]
Modified Arps Well Production With Exponential Decay And Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y / (d exp(x)) + Offset
Ramberg-Osgood With Exponential Decay And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y / (d * exp(x)) + Offset
Sellmeier Optical Square Root With Exponential Decay And Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n / (h * exp(x)) + Offset
Sellmeier Optical With Exponential Decay And Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) / (h * exp(x)) + Offset



Dispersion Optical Square Root With Exponential Decay 2D		n = (A1 + A2x² + A3/x² + A4/x⁴)^0.5 n = n / (f exp(x))
Dispersion Optical With Exponential Decay 2D		n²(x) = A1 + A2x² + A3/x² + A4/x⁴ n²(x) = n²(x) / (f exp(x))
Electron Beam Lithography Point Spread With Exponential Decay 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y / (n exp(x))
Extended Steinhart-Hart With Exponential Decay 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³ 1/T = 1/T / (f * exp(x))
Graeme Paterson Electric Motor With Exponential Decay 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y / (h * exp(x))
Klimpel Kinetics Flotation A With Exponential Decay 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y / exp(x)
Maxwell - Wiechert 1 With Exponential Decay 2D		y = a1*exp(-X/Tau1) y = y / exp(x) [web citation]
Maxwell - Wiechert 2 With Exponential Decay 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y / (f * exp(x)) [web citation]
Maxwell - Wiechert 3 With Exponential Decay 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y / (h exp(x)) [web citation]
Maxwell - Wiechert 4 With Exponential Decay 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y / (j * exp(x)) [web citation]
Modified Arps Well Production With Exponential Decay 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y / (d exp(x))
Ramberg-Osgood With Exponential Decay 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y / (d * exp(x))
Sellmeier Optical Square Root With Exponential Decay 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n / (h * exp(x))
Sellmeier Optical With Exponential Decay 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) / (h * exp(x))
VanDeemter Chromatography With Exponential Decay 2D		y = a + b/x + cx y = y / (d * exp(x))



Electron Beam Lithography Point Spread With Exponential Growth And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y (n * exp(x)) + Offset
Graeme Paterson Electric Motor With Exponential Growth And Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y * (h * exp(x)) + Offset
Klimpel Kinetics Flotation A With Exponential Growth And Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y * exp(x) + Offset
Maxwell - Wiechert 1 With Exponential Growth And Offset 2D		y = a1exp(-X/Tau1) y = y exp(x) + Offset [web citation]
Maxwell - Wiechert 2 With Exponential Growth And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y * (f * exp(x)) + Offset [web citation]
Maxwell - Wiechert 3 With Exponential Growth And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y (h * exp(x)) + Offset [web citation]
Maxwell - Wiechert 4 With Exponential Growth And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y * (j * exp(x)) + Offset [web citation]
Modified Arps Well Production With Exponential Growth And Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y (d * exp(x)) + Offset
Ramberg-Osgood With Exponential Growth And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y * (d * exp(x)) + Offset
Sellmeier Optical Square Root With Exponential Growth And Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n * (h * exp(x)) + Offset
Sellmeier Optical With Exponential Growth And Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) * (h * exp(x)) + Offset



Dispersion Optical Square Root With Exponential Growth 2D		n = (A1 + A2x² + A3/x² + A4/x⁴)^0.5 n = n (f * exp(x))
Dispersion Optical With Exponential Growth 2D		n²(x) = A1 + A2x² + A3/x² + A4/x⁴ n²(x) = n²(x) (f * exp(x))
Electron Beam Lithography Point Spread With Exponential Growth 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y (n * exp(x))
Extended Steinhart-Hart With Exponential Growth 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³ 1/T = 1/T * (f * exp(x))
Graeme Paterson Electric Motor With Exponential Growth 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y * (h * exp(x))
Klimpel Kinetics Flotation A With Exponential Growth 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y * exp(x)
Maxwell - Wiechert 1 With Exponential Growth 2D		y = a1exp(-X/Tau1) y = y exp(x) [web citation]
Maxwell - Wiechert 2 With Exponential Growth 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y * (f * exp(x)) [web citation]
Maxwell - Wiechert 3 With Exponential Growth 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y (h * exp(x)) [web citation]
Maxwell - Wiechert 4 With Exponential Growth 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y * (j * exp(x)) [web citation]
Modified Arps Well Production With Exponential Growth 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y (d * exp(x))
Ramberg-Osgood With Exponential Growth 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y * (d * exp(x))
Sellmeier Optical Square Root With Exponential Growth 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n * (h * exp(x))
Sellmeier Optical With Exponential Growth 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) * (h * exp(x))
VanDeemter Chromatography With Exponential Growth 2D		y = a + b/x + cx y = y * (d * exp(x))



Inverse Dispersion Optical 2D		n²(x) = A1 + A2*x² + A3/x² + A4/x⁴ n²(x) = x / n²(x)
Inverse Dispersion Optical Square Root 2D		n = (A1 + A2*x² + A3/x² + A4/x⁴)^0.5 n = x / n
Inverse Electron Beam Lithography Point Spread 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + j*exp(-(x-k)² / l²) y = x / y
Inverse Extended Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³ 1/T = x / 1/T
Inverse Graeme Paterson Electric Motor 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = x / y
Inverse Klimpel Kinetics Flotation A 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = x / y
Inverse Maxwell - Wiechert 1 2D		y = a1*exp(-X/Tau1) y = x / y [web citation]
Inverse Maxwell - Wiechert 2 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = x / y [web citation]
Inverse Maxwell - Wiechert 3 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3*exp(-X/Tau3) y = x / y [web citation]
Inverse Maxwell - Wiechert 4 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = x / y [web citation]
Inverse Modified Arps Well Production 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)**(1.0-1.0/b_x))) y = x / y
Inverse Ramberg-Osgood 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = x / y
Inverse Sellmeier Optical 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = x / n²(x)
Inverse Sellmeier Optical Square Root 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = x / n
Inverse VanDeemter Chromatography 2D		y = a + b/x + cx y = x / y



Inverse Electron Beam Lithography Point Spread With Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + j*exp(-(x-k)² / l²) y = x / y + Offset
Inverse Graeme Paterson Electric Motor With Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = x / y + Offset
Inverse Klimpel Kinetics Flotation A With Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = x / y + Offset
Inverse Maxwell - Wiechert 1 With Offset 2D		y = a1*exp(-X/Tau1) y = x / y + Offset [web citation]
Inverse Maxwell - Wiechert 2 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = x / y + Offset [web citation]
Inverse Maxwell - Wiechert 3 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3*exp(-X/Tau3) y = x / y + Offset [web citation]
Inverse Maxwell - Wiechert 4 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = x / y + Offset [web citation]
Inverse Modified Arps Well Production With Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)**(1.0-1.0/b_x))) y = x / y + Offset
Inverse Ramberg-Osgood With Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = x / y + Offset
Inverse Sellmeier Optical Square Root With Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = x / n + Offset
Inverse Sellmeier Optical With Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = x / n²(x) + Offset



Electron Beam Lithography Point Spread With Linear Decay And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y / (n x) + Offset
Graeme Paterson Electric Motor With Linear Decay And Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y / (h * x) + Offset
Klimpel Kinetics Flotation A With Linear Decay And Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y / x + Offset
Maxwell - Wiechert 1 With Linear Decay And Offset 2D		y = a1*exp(-X/Tau1) y = y / x + Offset [web citation]
Maxwell - Wiechert 2 With Linear Decay And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y / (f * x) + Offset [web citation]
Maxwell - Wiechert 3 With Linear Decay And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y / (h x) + Offset [web citation]
Maxwell - Wiechert 4 With Linear Decay And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y / (j * x) + Offset [web citation]
Modified Arps Well Production With Linear Decay And Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y / (d x) + Offset
Ramberg-Osgood With Linear Decay And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y / (d * x) + Offset
Sellmeier Optical Square Root With Linear Decay And Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n / (h * x) + Offset
Sellmeier Optical With Linear Decay And Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) / (h * x) + Offset



Dispersion Optical Square Root With Linear Decay 2D		n = (A1 + A2x² + A3/x² + A4/x⁴)^0.5 n = n / (f x)
Dispersion Optical With Linear Decay 2D		n²(x) = A1 + A2x² + A3/x² + A4/x⁴ n²(x) = n²(x) / (f x)
Electron Beam Lithography Point Spread With Linear Decay 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y / (n x)
Extended Steinhart-Hart With Linear Decay 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³ 1/T = 1/T / (f * x)
Graeme Paterson Electric Motor With Linear Decay 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y / (h * x)
Klimpel Kinetics Flotation A With Linear Decay 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y / x
Maxwell - Wiechert 1 With Linear Decay 2D		y = a1*exp(-X/Tau1) y = y / x [web citation]
Maxwell - Wiechert 2 With Linear Decay 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y / (f * x) [web citation]
Maxwell - Wiechert 3 With Linear Decay 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y / (h x) [web citation]
Maxwell - Wiechert 4 With Linear Decay 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y / (j * x) [web citation]
Modified Arps Well Production With Linear Decay 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y / (d x)
Ramberg-Osgood With Linear Decay 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y / (d * x)
Sellmeier Optical Square Root With Linear Decay 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n / (h * x)
Sellmeier Optical With Linear Decay 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) / (h * x)
VanDeemter Chromatography With Linear Decay 2D		y = a + b/x + cx y = y / (d * x)



Electron Beam Lithography Point Spread With Linear Growth And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y (n * x) + Offset
Graeme Paterson Electric Motor With Linear Growth And Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y * (h * x) + Offset
Klimpel Kinetics Flotation A With Linear Growth And Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y * x + Offset
Maxwell - Wiechert 1 With Linear Growth And Offset 2D		y = a1exp(-X/Tau1) y = y x + Offset [web citation]
Maxwell - Wiechert 2 With Linear Growth And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y * (f * x) + Offset [web citation]
Maxwell - Wiechert 3 With Linear Growth And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y (h * x) + Offset [web citation]
Maxwell - Wiechert 4 With Linear Growth And Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y * (j * x) + Offset [web citation]
Modified Arps Well Production With Linear Growth And Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y (d * x) + Offset
Ramberg-Osgood With Linear Growth And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y * (d * x) + Offset
Sellmeier Optical Square Root With Linear Growth And Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n * (h * x) + Offset
Sellmeier Optical With Linear Growth And Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) * (h * x) + Offset



Dispersion Optical Square Root With Linear Growth 2D		n = (A1 + A2x² + A3/x² + A4/x⁴)^0.5 n = n (f * x)
Dispersion Optical With Linear Growth 2D		n²(x) = A1 + A2x² + A3/x² + A4/x⁴ n²(x) = n²(x) (f * x)
Electron Beam Lithography Point Spread With Linear Growth 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + jexp(-(x-k)² / l²) y = y (n * x)
Extended Steinhart-Hart With Linear Growth 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³ 1/T = 1/T * (f * x)
Graeme Paterson Electric Motor With Linear Growth 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = y * (h * x)
Klimpel Kinetics Flotation A With Linear Growth 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y * x
Maxwell - Wiechert 1 With Linear Growth 2D		y = a1exp(-X/Tau1) y = y x [web citation]
Maxwell - Wiechert 2 With Linear Growth 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = y * (f * x) [web citation]
Maxwell - Wiechert 3 With Linear Growth 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) y = y (h * x) [web citation]
Maxwell - Wiechert 4 With Linear Growth 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = y * (j * x) [web citation]
Modified Arps Well Production With Linear Growth 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)*(1.0-1.0/b_x))) y = y (d * x)
Ramberg-Osgood With Linear Growth 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = y * (d * x)
Sellmeier Optical Square Root With Linear Growth 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = n * (h * x)
Sellmeier Optical With Linear Growth 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = n²(x) * (h * x)
VanDeemter Chromatography With Linear Growth 2D		y = a + b/x + cx y = y * (d * x)



Reciprocal Dispersion Optical 2D		n²(x) = A1 + A2*x² + A3/x² + A4/x⁴ n²(x) = 1.0 / n²(x)
Reciprocal Dispersion Optical Square Root 2D		n = (A1 + A2*x² + A3/x² + A4/x⁴)^0.5 n = 1.0 / n
Reciprocal Electron Beam Lithography Point Spread 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + j*exp(-(x-k)² / l²) y = 1.0 / y
Reciprocal Extended Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³ 1/T = 1.0 / 1/T
Reciprocal Graeme Paterson Electric Motor 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = 1.0 / y
Reciprocal Klimpel Kinetics Flotation A 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = 1.0 / y
Reciprocal Maxwell - Wiechert 1 2D		y = a1*exp(-X/Tau1) y = 1.0 / y [web citation]
Reciprocal Maxwell - Wiechert 2 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = 1.0 / y [web citation]
Reciprocal Maxwell - Wiechert 3 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3*exp(-X/Tau3) y = 1.0 / y [web citation]
Reciprocal Maxwell - Wiechert 4 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = 1.0 / y [web citation]
Reciprocal Modified Arps Well Production 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)**(1.0-1.0/b_x))) y = 1.0 / y
Reciprocal Ramberg-Osgood 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = 1.0 / y
Reciprocal Sellmeier Optical 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = 1.0 / n²(x)
Reciprocal Sellmeier Optical Square Root 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = 1.0 / n
Reciprocal VanDeemter Chromatography 2D		y = a + b/x + cx y = 1.0 / y



Reciprocal Electron Beam Lithography Point Spread With Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + j*exp(-(x-k)² / l²) y = 1.0 / y + Offset
Reciprocal Graeme Paterson Electric Motor With Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) y = 1.0 / y + Offset
Reciprocal Klimpel Kinetics Flotation A With Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = 1.0 / y + Offset
Reciprocal Maxwell - Wiechert 1 With Offset 2D		y = a1*exp(-X/Tau1) y = 1.0 / y + Offset [web citation]
Reciprocal Maxwell - Wiechert 2 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) y = 1.0 / y + Offset [web citation]
Reciprocal Maxwell - Wiechert 3 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3*exp(-X/Tau3) y = 1.0 / y + Offset [web citation]
Reciprocal Maxwell - Wiechert 4 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) y = 1.0 / y + Offset [web citation]
Reciprocal Modified Arps Well Production With Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)**(1.0-1.0/b_x))) y = 1.0 / y + Offset
Reciprocal Ramberg-Osgood With Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) y = 1.0 / y + Offset
Reciprocal Sellmeier Optical Square Root With Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 n = 1.0 / n + Offset
Reciprocal Sellmeier Optical With Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) n²(x) = 1.0 / n²(x) + Offset



Dispersion Optical 2D		n²(x) = A1 + A2*x² + A3/x² + A4/x⁴
Dispersion Optical Square Root 2D		n = (A1 + A2*x² + A3/x² + A4/x⁴)^0.5
Electron Beam Lithography Point Spread 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + j*exp(-(x-k)² / l²)
Extended Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))² + D(ln(R))³
Graeme Paterson Electric Motor 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t)
Klimpel Kinetics Flotation A 2D		y = a * (1 - (1 - exp(-bx)) / (bx))
Maxwell - Wiechert 1 2D		y = a1*exp(-X/Tau1) [web citation]
Maxwell - Wiechert 2 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) [web citation]
Maxwell - Wiechert 3 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3*exp(-X/Tau3) [web citation]
Maxwell - Wiechert 4 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) [web citation]
Modified Arps Well Production 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)**(1.0-1.0/b_x)))
Ramberg-Osgood 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n)
Reciprocal Extended Steinhart-Hart 2D		T = 1.0 / (A + Bln(R) + C(ln(R))² + D(ln(R))³)
Reciprocal Steinhart-Hart 2D		T = 1.0 / (A + Bln(R) + C(ln(R))³)
Sellmeier Optical 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3)
Sellmeier Optical Square Root 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5
Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))³
VanDeemter Chromatography 2D		y = a + b/x + cx



Electron Beam Lithography Point Spread With Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + j*exp(-(x-k)² / l²) + Offset
Graeme Paterson Electric Motor With Offset 2D		y = Aexp(-bt)cos(omegat + phi) + A2exp(-b2t) + Offset
Klimpel Kinetics Flotation A With Offset 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) + Offset
Maxwell - Wiechert 1 With Offset 2D		y = a1*exp(-X/Tau1) + Offset [web citation]
Maxwell - Wiechert 2 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + Offset [web citation]
Maxwell - Wiechert 3 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3*exp(-X/Tau3) + Offset [web citation]
Maxwell - Wiechert 4 With Offset 2D		y = a1exp(-X/Tau1) + a2exp(-X/Tau2) + a3exp(-X/Tau3) + a4exp(-X/Tau4) + Offset [web citation]
Modified Arps Well Production With Offset 2D		y = (qi_x/((1.0-b_x)Di_x)) (1.0-((1.0+b_xDi_xx)**(1.0-1.0/b_x))) + Offset
Ramberg-Osgood With Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)^(1.0/n) + Offset
Reciprocal Extended Steinhart-Hart With Offset 2D		T = 1.0 / (A + Bln(R) + C(ln(R))² + D(ln(R))³) + Offset
Reciprocal Steinhart-Hart With Offset 2D		T = 1.0 / (A + Bln(R) + C(ln(R))³) + Offset
Sellmeier Optical Square Root With Offset 2D		n = (1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3))^0.5 + Offset
Sellmeier Optical With Offset 2D		n²(x) = 1 + (B1 x²)/(x²-C1) + (B2 x²)/(x²-C2) + (B3 x²)/(x²-C3) + Offset



Klimpel Kinetics Flotation A Plus Line 2D		y = a * (1 - (1 - exp(-bx)) / (bx)) y = y + (c * x) + d
Maxwell - Wiechert 1 Plus Line 2D		y = a1exp(-X/Tau1) y = y + (c x) + d [web citation]

2D Exponential

Asymptotic Exponential A Transform With Exponential Decay And Offset 2D		y = 1.0 - a^{bx + c} y = y / (d * exp(x)) + Offset
Asymptotic Exponential A With Exponential Decay And Offset 2D		y = 1.0 - a^x y = y / (b * exp(x)) + Offset
Asymptotic Exponential B With Exponential Decay And Offset 2D		y = a * (1.0 - exp(bx)) y = y / exp(x) + Offset
Double Asymptotic Exponential B With Exponential Decay And Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y / (f * exp(x)) + Offset
Double Exponential With Exponential Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y / (f * exp(x)) + Offset
Exponential With Exponential Decay And Offset 2D		y = a * exp(bx) y = y / exp(x) + Offset
Hoerl Transform With Exponential Decay And Offset 2D		y = (bx + c)^a * exp(bx + c) y = y / (d * exp(x)) + Offset
Hoerl With Exponential Decay And Offset 2D		y = x^a * exp(x) y = y / (b * exp(x)) + Offset
Inverted Exponential With Exponential Decay And Offset 2D		y = a * exp(b/x) y = y / exp(x) + Offset
Inverted Offset Exponential With Exponential Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / exp(x) + Offset
Lake Nganoke Samples Exponential With Exponential Decay And Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y / (g * exp(x)) + Offset [web citation]
Offset Exponential With Exponential Decay And Offset 2D		y = a * exp(bx + c) y = y / exp(x) + Offset
Scaled Exponential With Exponential Decay And Offset 2D		y = a * exp(x) y = y / exp(x) + Offset
Shifted Exponential With Exponential Decay And Offset 2D		y = a * exp(x + b) y = y / exp(x) + Offset
Simple Exponential With Exponential Decay And Offset 2D		y = a^x y = y / (b * exp(x)) + Offset
Standard Vapor Pressure With Exponential Decay And Offset 2D		y = exp(a + (b/x) + cln(x)) y = y / (d exp(x)) + Offset
Steve Battison Exponential A With Exponential Decay And Offset 2D		y = exp((a + bx) / (c + dx)) y = y / (f * exp(x)) + Offset
Steve Battison Exponential B With Exponential Decay And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y / exp(x) + Offset
Stirling With Exponential Decay And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y / exp(x) + Offset
Triple Exponential With Exponential Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / exp(x) + Offset



Asymptotic Exponential A Transform With Exponential Decay 2D		y = 1.0 - a^{bx + c} y = y / (d * exp(x))
Asymptotic Exponential A With Exponential Decay 2D		y = 1.0 - a^x y = y / (b * exp(x))
Asymptotic Exponential B With Exponential Decay 2D		y = a * (1.0 - exp(bx)) y = y / exp(x)
Double Asymptotic Exponential B With Exponential Decay 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y / (f * exp(x))
Double Exponential With Exponential Decay 2D		y = a * exp(bx) + c * exp(dx) y = y / (f * exp(x))
Exponential With Exponential Decay 2D		y = a * exp(bx) y = y / exp(x)
Hocket-Sherby With Exponential Decay 2D		y = b - (b-a) * exp(-c * (x^d)) y = y / (f * exp(x))
Hoerl Transform With Exponential Decay 2D		y = (bx + c)^a * exp(bx + c) y = y / (d * exp(x))
Hoerl With Exponential Decay 2D		y = x^a * exp(x) y = y / (b * exp(x))
Inverted Exponential With Exponential Decay 2D		y = a * exp(b/x) y = y / exp(x)
Inverted Offset Exponential With Exponential Decay 2D		y = a * exp(b/(x+c)) y = y / exp(x)
Jonathan Litz Custom Exponential With Exponential Decay 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) y = y / (f * exp(x)) [web citation]
Lake Nganoke Samples Exponential With Exponential Decay 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y / (g * exp(x)) [web citation]
Offset Exponential With Exponential Decay 2D		y = a * exp(bx + c) y = y / exp(x)
Scaled Exponential With Exponential Decay 2D		y = a * exp(x) y = y / exp(x)
Shifted Exponential With Exponential Decay 2D		y = a * exp(x + b) y = y / exp(x)
Simple Exponential With Exponential Decay 2D		y = a^x y = y / (b * exp(x))
Standard Vapor Pressure With Exponential Decay 2D		y = exp(a + (b/x) + cln(x)) y = y / (d exp(x))
Steve Battison Exponential A With Exponential Decay 2D		y = exp((a + bx) / (c + dx)) y = y / (f * exp(x))
Steve Battison Exponential B With Exponential Decay 2D		y = a * exp((b + cx) / (d + fx)) y = y / exp(x)
Stirling With Exponential Decay 2D		y = a * (exp(bx) - 1.0) / b y = y / exp(x)
Triple Exponential With Exponential Decay 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / exp(x)



Asymptotic Exponential A Transform With Exponential Growth And Offset 2D		y = 1.0 - a^{bx + c} y = y * (d * exp(x)) + Offset
Asymptotic Exponential A With Exponential Growth And Offset 2D		y = 1.0 - a^x y = y * (b * exp(x)) + Offset
Asymptotic Exponential B With Exponential Growth And Offset 2D		y = a * (1.0 - exp(bx)) y = y * exp(x) + Offset
Double Asymptotic Exponential B With Exponential Growth And Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y * (f * exp(x)) + Offset
Double Exponential With Exponential Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y * (f * exp(x)) + Offset
Exponential With Exponential Growth And Offset 2D		y = a * exp(bx) y = y * exp(x) + Offset
Hoerl Transform With Exponential Growth And Offset 2D		y = (bx + c)^a * exp(bx + c) y = y * (d * exp(x)) + Offset
Hoerl With Exponential Growth And Offset 2D		y = x^a * exp(x) y = y * (b * exp(x)) + Offset
Inverted Exponential With Exponential Growth And Offset 2D		y = a * exp(b/x) y = y * exp(x) + Offset
Inverted Offset Exponential With Exponential Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * exp(x) + Offset
Lake Nganoke Samples Exponential With Exponential Growth And Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y * (g * exp(x)) + Offset [web citation]
Offset Exponential With Exponential Growth And Offset 2D		y = a * exp(bx + c) y = y * exp(x) + Offset
Scaled Exponential With Exponential Growth And Offset 2D		y = a * exp(x) y = y * exp(x) + Offset
Shifted Exponential With Exponential Growth And Offset 2D		y = a * exp(x + b) y = y * exp(x) + Offset
Simple Exponential With Exponential Growth And Offset 2D		y = a^x y = y * (b * exp(x)) + Offset
Standard Vapor Pressure With Exponential Growth And Offset 2D		y = exp(a + (b/x) + cln(x)) y = y (d * exp(x)) + Offset
Steve Battison Exponential A With Exponential Growth And Offset 2D		y = exp((a + bx) / (c + dx)) y = y * (f * exp(x)) + Offset
Steve Battison Exponential B With Exponential Growth And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y * exp(x) + Offset
Stirling With Exponential Growth And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y * exp(x) + Offset
Triple Exponential With Exponential Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * exp(x) + Offset



Asymptotic Exponential A Transform With Exponential Growth 2D		y = 1.0 - a^{bx + c} y = y * (d * exp(x))
Asymptotic Exponential A With Exponential Growth 2D		y = 1.0 - a^x y = y * (b * exp(x))
Asymptotic Exponential B With Exponential Growth 2D		y = a * (1.0 - exp(bx)) y = y * exp(x)
Double Asymptotic Exponential B With Exponential Growth 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y * (f * exp(x))
Double Exponential With Exponential Growth 2D		y = a * exp(bx) + c * exp(dx) y = y * (f * exp(x))
Exponential With Exponential Growth 2D		y = a * exp(bx) y = y * exp(x)
Hocket-Sherby With Exponential Growth 2D		y = b - (b-a) * exp(-c * (x^d)) y = y * (f * exp(x))
Hoerl Transform With Exponential Growth 2D		y = (bx + c)^a * exp(bx + c) y = y * (d * exp(x))
Hoerl With Exponential Growth 2D		y = x^a * exp(x) y = y * (b * exp(x))
Inverted Exponential With Exponential Growth 2D		y = a * exp(b/x) y = y * exp(x)
Inverted Offset Exponential With Exponential Growth 2D		y = a * exp(b/(x+c)) y = y * exp(x)
Jonathan Litz Custom Exponential With Exponential Growth 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) y = y * (f * exp(x)) [web citation]
Lake Nganoke Samples Exponential With Exponential Growth 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y * (g * exp(x)) [web citation]
Offset Exponential With Exponential Growth 2D		y = a * exp(bx + c) y = y * exp(x)
Scaled Exponential With Exponential Growth 2D		y = a * exp(x) y = y * exp(x)
Shifted Exponential With Exponential Growth 2D		y = a * exp(x + b) y = y * exp(x)
Simple Exponential With Exponential Growth 2D		y = a^x y = y * (b * exp(x))
Standard Vapor Pressure With Exponential Growth 2D		y = exp(a + (b/x) + cln(x)) y = y (d * exp(x))
Steve Battison Exponential A With Exponential Growth 2D		y = exp((a + bx) / (c + dx)) y = y * (f * exp(x))
Steve Battison Exponential B With Exponential Growth 2D		y = a * exp((b + cx) / (d + fx)) y = y * exp(x)
Stirling With Exponential Growth 2D		y = a * (exp(bx) - 1.0) / b y = y * exp(x)
Triple Exponential With Exponential Growth 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * exp(x)



Inverse Asymptotic Exponential A 2D		y = 1.0 - a^x y = x / y
Inverse Asymptotic Exponential A Transform 2D		y = 1.0 - a^{bx + c} y = x / y
Inverse Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) y = x / y
Inverse Double Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = x / y
Inverse Double Exponential 2D		y = a * exp(bx) + c * exp(dx) y = x / y
Inverse Exponential 2D		y = a * exp(bx) y = x / y
Inverse Hocket-Sherby 2D		y = b - (b-a) * exp(-c * (x^d)) y = x / y
Inverse Hoerl 2D		y = x^a * exp(x) y = x / y
Inverse Hoerl Transform 2D		y = (bx + c)^a * exp(bx + c) y = x / y
Inverse Inverted Exponential 2D		y = a * exp(b/x) y = x / y
Inverse Inverted Offset Exponential 2D		y = a * exp(b/(x+c)) y = x / y
Inverse Jonathan Litz Custom Exponential 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) y = x / y [web citation]
Inverse Lake Nganoke Samples Exponential 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = x / y [web citation]
Inverse Offset Exponential 2D		y = a * exp(bx + c) y = x / y
Inverse Shifted Exponential 2D		y = a * exp(x + b) y = x / y
Inverse Standard Vapor Pressure 2D		y = exp(a + (b/x) + c*ln(x)) y = x / y
Inverse Steve Battison Exponential A 2D		y = exp((a + bx) / (c + dx)) y = x / y
Inverse Steve Battison Exponential B 2D		y = a * exp((b + cx) / (d + fx)) y = x / y
Inverse Stirling 2D		y = a * (exp(bx) - 1.0) / b y = x / y
Inverse Triple Exponential 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = x / y



Inverse Asymptotic Exponential A Transform With Offset 2D		y = 1.0 - a^{bx + c} y = x / y + Offset
Inverse Asymptotic Exponential A With Offset 2D		y = 1.0 - a^x y = x / y + Offset
Inverse Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) y = x / y + Offset
Inverse Double Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = x / y + Offset
Inverse Double Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) y = x / y + Offset
Inverse Exponential With Offset 2D		y = a * exp(bx) y = x / y + Offset
Inverse Hoerl Transform With Offset 2D		y = (bx + c)^a * exp(bx + c) y = x / y + Offset
Inverse Hoerl With Offset 2D		y = x^a * exp(x) y = x / y + Offset
Inverse Inverted Exponential With Offset 2D		y = a * exp(b/x) y = x / y + Offset
Inverse Inverted Offset Exponential With Offset 2D		y = a * exp(b/(x+c)) y = x / y + Offset
Inverse Lake Nganoke Samples Exponential With Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = x / y + Offset [web citation]
Inverse Offset Exponential With Offset 2D		y = a * exp(bx + c) y = x / y + Offset
Inverse Shifted Exponential With Offset 2D		y = a * exp(x + b) y = x / y + Offset
Inverse Standard Vapor Pressure With Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = x / y + Offset
Inverse Steve Battison Exponential A With Offset 2D		y = exp((a + bx) / (c + dx)) y = x / y + Offset
Inverse Steve Battison Exponential B With Offset 2D		y = a * exp((b + cx) / (d + fx)) y = x / y + Offset
Inverse Stirling With Offset 2D		y = a * (exp(bx) - 1.0) / b y = x / y + Offset
Inverse Triple Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = x / y + Offset



Asymptotic Exponential A Transform With Linear Decay And Offset 2D		y = 1.0 - a^{bx + c} y = y / (d * x) + Offset
Asymptotic Exponential A With Linear Decay And Offset 2D		y = 1.0 - a^x y = y / (b * x) + Offset
Asymptotic Exponential B With Linear Decay And Offset 2D		y = a * (1.0 - exp(bx)) y = y / x + Offset
Double Asymptotic Exponential B With Linear Decay And Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y / (f * x) + Offset
Double Exponential With Linear Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y / (f * x) + Offset
Exponential With Linear Decay And Offset 2D		y = a * exp(bx) y = y / x + Offset
Hoerl Transform With Linear Decay And Offset 2D		y = (bx + c)^a * exp(bx + c) y = y / (d * x) + Offset
Hoerl With Linear Decay And Offset 2D		y = x^a * exp(x) y = y / (b * x) + Offset
Inverted Exponential With Linear Decay And Offset 2D		y = a * exp(b/x) y = y / x + Offset
Inverted Offset Exponential With Linear Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / x + Offset
Lake Nganoke Samples Exponential With Linear Decay And Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y / (g * x) + Offset [web citation]
Offset Exponential With Linear Decay And Offset 2D		y = a * exp(bx + c) y = y / x + Offset
Scaled Exponential With Linear Decay And Offset 2D		y = a * exp(x) y = y / x + Offset
Shifted Exponential With Linear Decay And Offset 2D		y = a * exp(x + b) y = y / x + Offset
Simple Exponential With Linear Decay And Offset 2D		y = a^x y = y / (b * x) + Offset
Standard Vapor Pressure With Linear Decay And Offset 2D		y = exp(a + (b/x) + cln(x)) y = y / (d x) + Offset
Steve Battison Exponential A With Linear Decay And Offset 2D		y = exp((a + bx) / (c + dx)) y = y / (f * x) + Offset
Steve Battison Exponential B With Linear Decay And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y / x + Offset
Stirling With Linear Decay And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y / x + Offset
Triple Exponential With Linear Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / x + Offset



Asymptotic Exponential A Transform With Linear Decay 2D		y = 1.0 - a^{bx + c} y = y / (d * x)
Asymptotic Exponential A With Linear Decay 2D		y = 1.0 - a^x y = y / (b * x)
Asymptotic Exponential B With Linear Decay 2D		y = a * (1.0 - exp(bx)) y = y / x
Double Asymptotic Exponential B With Linear Decay 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y / (f * x)
Double Exponential With Linear Decay 2D		y = a * exp(bx) + c * exp(dx) y = y / (f * x)
Exponential With Linear Decay 2D		y = a * exp(bx) y = y / x
Hocket-Sherby With Linear Decay 2D		y = b - (b-a) * exp(-c * (x^d)) y = y / (f * x)
Hoerl Transform With Linear Decay 2D		y = (bx + c)^a * exp(bx + c) y = y / (d * x)
Hoerl With Linear Decay 2D		y = x^a * exp(x) y = y / (b * x)
Inverted Exponential With Linear Decay 2D		y = a * exp(b/x) y = y / x
Inverted Offset Exponential With Linear Decay 2D		y = a * exp(b/(x+c)) y = y / x
Jonathan Litz Custom Exponential With Linear Decay 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) y = y / (f * x) [web citation]
Lake Nganoke Samples Exponential With Linear Decay 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y / (g * x) [web citation]
Offset Exponential With Linear Decay 2D		y = a * exp(bx + c) y = y / x
Scaled Exponential With Linear Decay 2D		y = a * exp(x) y = y / x
Shifted Exponential With Linear Decay 2D		y = a * exp(x + b) y = y / x
Simple Exponential With Linear Decay 2D		y = a^x y = y / (b * x)
Standard Vapor Pressure With Linear Decay 2D		y = exp(a + (b/x) + cln(x)) y = y / (d x)
Steve Battison Exponential A With Linear Decay 2D		y = exp((a + bx) / (c + dx)) y = y / (f * x)
Steve Battison Exponential B With Linear Decay 2D		y = a * exp((b + cx) / (d + fx)) y = y / x
Stirling With Linear Decay 2D		y = a * (exp(bx) - 1.0) / b y = y / x
Triple Exponential With Linear Decay 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / x



Asymptotic Exponential A Transform With Linear Growth And Offset 2D		y = 1.0 - a^{bx + c} y = y * (d * x) + Offset
Asymptotic Exponential A With Linear Growth And Offset 2D		y = 1.0 - a^x y = y * (b * x) + Offset
Asymptotic Exponential B With Linear Growth And Offset 2D		y = a * (1.0 - exp(bx)) y = y * x + Offset
Double Asymptotic Exponential B With Linear Growth And Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y * (f * x) + Offset
Double Exponential With Linear Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y * (f * x) + Offset
Exponential With Linear Growth And Offset 2D		y = a * exp(bx) y = y * x + Offset
Hoerl Transform With Linear Growth And Offset 2D		y = (bx + c)^a * exp(bx + c) y = y * (d * x) + Offset
Hoerl With Linear Growth And Offset 2D		y = x^a * exp(x) y = y * (b * x) + Offset
Inverted Exponential With Linear Growth And Offset 2D		y = a * exp(b/x) y = y * x + Offset
Inverted Offset Exponential With Linear Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * x + Offset
Lake Nganoke Samples Exponential With Linear Growth And Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y * (g * x) + Offset [web citation]
Offset Exponential With Linear Growth And Offset 2D		y = a * exp(bx + c) y = y * x + Offset
Scaled Exponential With Linear Growth And Offset 2D		y = a * exp(x) y = y * x + Offset
Shifted Exponential With Linear Growth And Offset 2D		y = a * exp(x + b) y = y * x + Offset
Simple Exponential With Linear Growth And Offset 2D		y = a^x y = y * (b * x) + Offset
Standard Vapor Pressure With Linear Growth And Offset 2D		y = exp(a + (b/x) + cln(x)) y = y (d * x) + Offset
Steve Battison Exponential A With Linear Growth And Offset 2D		y = exp((a + bx) / (c + dx)) y = y * (f * x) + Offset
Steve Battison Exponential B With Linear Growth And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y * x + Offset
Stirling With Linear Growth And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y * x + Offset
Triple Exponential With Linear Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * x + Offset



Asymptotic Exponential A Transform With Linear Growth 2D		y = 1.0 - a^{bx + c} y = y * (d * x)
Asymptotic Exponential A With Linear Growth 2D		y = 1.0 - a^x y = y * (b * x)
Asymptotic Exponential B With Linear Growth 2D		y = a * (1.0 - exp(bx)) y = y * x
Double Asymptotic Exponential B With Linear Growth 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = y * (f * x)
Double Exponential With Linear Growth 2D		y = a * exp(bx) + c * exp(dx) y = y * (f * x)
Exponential With Linear Growth 2D		y = a * exp(bx) y = y * x
Hocket-Sherby With Linear Growth 2D		y = b - (b-a) * exp(-c * (x^d)) y = y * (f * x)
Hoerl Transform With Linear Growth 2D		y = (bx + c)^a * exp(bx + c) y = y * (d * x)
Hoerl With Linear Growth 2D		y = x^a * exp(x) y = y * (b * x)
Inverted Exponential With Linear Growth 2D		y = a * exp(b/x) y = y * x
Inverted Offset Exponential With Linear Growth 2D		y = a * exp(b/(x+c)) y = y * x
Jonathan Litz Custom Exponential With Linear Growth 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) y = y * (f * x) [web citation]
Lake Nganoke Samples Exponential With Linear Growth 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = y * (g * x) [web citation]
Offset Exponential With Linear Growth 2D		y = a * exp(bx + c) y = y * x
Scaled Exponential With Linear Growth 2D		y = a * exp(x) y = y * x
Shifted Exponential With Linear Growth 2D		y = a * exp(x + b) y = y * x
Simple Exponential With Linear Growth 2D		y = a^x y = y * (b * x)
Standard Vapor Pressure With Linear Growth 2D		y = exp(a + (b/x) + cln(x)) y = y (d * x)
Steve Battison Exponential A With Linear Growth 2D		y = exp((a + bx) / (c + dx)) y = y * (f * x)
Steve Battison Exponential B With Linear Growth 2D		y = a * exp((b + cx) / (d + fx)) y = y * x
Stirling With Linear Growth 2D		y = a * (exp(bx) - 1.0) / b y = y * x
Triple Exponential With Linear Growth 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * x



Reciprocal Asymptotic Exponential A 2D		y = 1.0 - a^x y = 1.0 / y
Reciprocal Asymptotic Exponential A Transform 2D		y = 1.0 - a^{bx + c} y = 1.0 / y
Reciprocal Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) y = 1.0 / y
Reciprocal Double Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = 1.0 / y
Reciprocal Double Exponential 2D		y = a * exp(bx) + c * exp(dx) y = 1.0 / y
Reciprocal Exponential 2D		y = a * exp(bx) y = 1.0 / y
Reciprocal Hocket-Sherby 2D		y = b - (b-a) * exp(-c * (x^d)) y = 1.0 / y
Reciprocal Hoerl 2D		y = x^a * exp(x) y = 1.0 / y
Reciprocal Hoerl Transform 2D		y = (bx + c)^a * exp(bx + c) y = 1.0 / y
Reciprocal Inverted Exponential 2D		y = a * exp(b/x) y = 1.0 / y
Reciprocal Inverted Offset Exponential 2D		y = a * exp(b/(x+c)) y = 1.0 / y
Reciprocal Jonathan Litz Custom Exponential 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) y = 1.0 / y [web citation]
Reciprocal Lake Nganoke Samples Exponential 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = 1.0 / y [web citation]
Reciprocal Offset Exponential 2D		y = a * exp(bx + c) y = 1.0 / y
Reciprocal Scaled Exponential 2D		y = a * exp(x) y = 1.0 / y
Reciprocal Shifted Exponential 2D		y = a * exp(x + b) y = 1.0 / y
Reciprocal Simple Exponential 2D		y = a^x y = 1.0 / y
Reciprocal Standard Vapor Pressure 2D		y = exp(a + (b/x) + c*ln(x)) y = 1.0 / y
Reciprocal Steve Battison Exponential A 2D		y = exp((a + bx) / (c + dx)) y = 1.0 / y
Reciprocal Steve Battison Exponential B 2D		y = a * exp((b + cx) / (d + fx)) y = 1.0 / y
Reciprocal Stirling 2D		y = a * (exp(bx) - 1.0) / b y = 1.0 / y
Reciprocal Triple Exponential 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = 1.0 / y



Reciprocal Asymptotic Exponential A Transform With Offset 2D		y = 1.0 - a^{bx + c} y = 1.0 / y + Offset
Reciprocal Asymptotic Exponential A With Offset 2D		y = 1.0 - a^x y = 1.0 / y + Offset
Reciprocal Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) y = 1.0 / y + Offset
Reciprocal Double Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) y = 1.0 / y + Offset
Reciprocal Double Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) y = 1.0 / y + Offset
Reciprocal Exponential With Offset 2D		y = a * exp(bx) y = 1.0 / y + Offset
Reciprocal Hoerl Transform With Offset 2D		y = (bx + c)^a * exp(bx + c) y = 1.0 / y + Offset
Reciprocal Hoerl With Offset 2D		y = x^a * exp(x) y = 1.0 / y + Offset
Reciprocal Inverted Exponential With Offset 2D		y = a * exp(b/x) y = 1.0 / y + Offset
Reciprocal Inverted Offset Exponential With Offset 2D		y = a * exp(b/(x+c)) y = 1.0 / y + Offset
Reciprocal Lake Nganoke Samples Exponential With Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) y = 1.0 / y + Offset [web citation]
Reciprocal Offset Exponential With Offset 2D		y = a * exp(bx + c) y = 1.0 / y + Offset
Reciprocal Scaled Exponential With Offset 2D		y = a * exp(x) y = 1.0 / y + Offset
Reciprocal Shifted Exponential With Offset 2D		y = a * exp(x + b) y = 1.0 / y + Offset
Reciprocal Simple Exponential With Offset 2D		y = a^x y = 1.0 / y + Offset
Reciprocal Standard Vapor Pressure With Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = 1.0 / y + Offset
Reciprocal Steve Battison Exponential A With Offset 2D		y = exp((a + bx) / (c + dx)) y = 1.0 / y + Offset
Reciprocal Steve Battison Exponential B With Offset 2D		y = a * exp((b + cx) / (d + fx)) y = 1.0 / y + Offset
Reciprocal Stirling With Offset 2D		y = a * (exp(bx) - 1.0) / b y = 1.0 / y + Offset
Reciprocal Triple Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = 1.0 / y + Offset



Asymptotic Exponential A 2D		y = 1.0 - a^x
Asymptotic Exponential A Transform 2D		y = 1.0 - a^{bx + c}
Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx))
Bruno Torremans Quadruple Exponential 2D		y = Offset - R1 * exp(-x/T1) + R2 * exp(-x/T2) + R3 * exp(-x/T3) + R4 * exp(-x/T4)
Double Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx))
Double Exponential 2D		y = a * exp(bx) + c * exp(dx)
Exponential 2D		y = a * exp(bx)
Hocket-Sherby 2D		y = b - (b-a) * exp(-c * (x^d))
Hoerl 2D		y = x^a * exp(x)
Hoerl Transform 2D		y = (bx + c)^a * exp(bx + c)
Inverted Exponential 2D		y = a * exp(b/x)
Inverted Offset Exponential 2D		y = a * exp(b/(x+c))
Jonathan Litz Custom Exponential 2D		y = a + b * x + c * exp(-d * x) - c * x * exp(-d * x) [web citation]
Lake Nganoke Samples Exponential 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) [web citation]
Offset Exponential 2D		y = a * exp(bx + c)
Scaled Exponential 2D		y = a * exp(x)
Shifted Exponential 2D		y = a * exp(x + b)
Simple Exponential 2D		y = a^x
Standard Vapor Pressure 2D		y = exp(a + (b/x) + c*ln(x))
Steve Battison Exponential A 2D		y = exp((a + bx) / (c + dx))
Steve Battison Exponential B 2D		y = a * exp((b + cx) / (d + fx))
Stirling 2D		y = a * (exp(bx) - 1.0) / b
Triple Exponential 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx)



Asymptotic Exponential A Transform With Offset 2D		y = 1.0 - a^{bx + c} + Offset
Asymptotic Exponential A With Offset 2D		y = 1.0 - a^x + Offset
Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) + Offset
Double Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) + c * (1.0 - exp(dx)) + Offset
Double Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + Offset
Exponential With Offset 2D		y = a * exp(bx) + Offset
Hoerl Transform With Offset 2D		y = (bx + c)^a * exp(bx + c) + Offset
Hoerl With Offset 2D		y = x^a * exp(x) + Offset
Inverted Exponential With Offset 2D		y = a * exp(b/x) + Offset
Inverted Offset Exponential With Offset 2D		y = a * exp(b/(x+c)) + Offset
Lake Nganoke Samples Exponential With Offset 2D		y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E) + Offset [web citation]
Offset Exponential With Offset 2D		y = a * exp(bx + c) + Offset
Scaled Exponential With Offset 2D		y = a * exp(x) + Offset
Shifted Exponential With Offset 2D		y = a * exp(x + b) + Offset
Simple Exponential With Offset 2D		y = a^x + Offset
Standard Vapor Pressure With Offset 2D		y = exp(a + (b/x) + c*ln(x)) + Offset
Steve Battison Exponential A With Offset 2D		y = exp((a + bx) / (c + dx)) + Offset
Steve Battison Exponential B With Offset 2D		y = a * exp((b + cx) / (d + fx)) + Offset
Stirling With Offset 2D		y = a * (exp(bx) - 1.0) / b + Offset
Triple Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) + Offset



Asymptotic Exponential A Plus Line 2D		y = 1.0 - a^x y = y + (b * x) + c
Asymptotic Exponential B Plus Line 2D		y = a * (1.0 - exp(bx)) y = y + (c * x) + d
Exponential Plus Line 2D		y = a * exp(bx) y = y + (c * x) + d
Hoerl Plus Line 2D		y = x^a * exp(x) y = y + (b * x) + c
Inverted Exponential Plus Line 2D		y = a * exp(b/x) y = y + (c * x) + d
Scaled Exponential Plus Line 2D		y = a * exp(x) y = y + (b * x) + c
Shifted Exponential Plus Line 2D		y = a * exp(x + b) y = y + (c * x) + d
Simple Exponential Plus Line 2D		y = a^x y = y + (b * x) + c
Stirling Plus Line 2D		y = a * (exp(bx) - 1.0) / b y = y + (c * x) + d

2D FourierSeries

1 Term (Scaled X) With Exponential Decay 2D		y = a0 + a1sin(c1x)+b1cos(c1x) y = y / (f * exp(x)) [web citation]
1 Term Standard With Exponential Decay 2D		y = a0 + a1sin(x)+b1cos(x) y = y / (d * exp(x)) [web citation]
2 Term Standard With Exponential Decay 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) y = y / (g * exp(x)) [web citation]
3 Term Standard With Exponential Decay 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) y = y / (i * exp(x)) [web citation]
4 Term Standard With Exponential Decay 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) + a4sin(4x)+b4cos(4x) y = y / (k * exp(x)) [web citation]



1 Term (Scaled X) With Exponential Growth 2D		y = a0 + a1sin(c1x)+b1cos(c1x) y = y * (f * exp(x)) [web citation]
1 Term Standard With Exponential Growth 2D		y = a0 + a1sin(x)+b1cos(x) y = y * (d * exp(x)) [web citation]
2 Term Standard With Exponential Growth 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) y = y * (g * exp(x)) [web citation]
3 Term Standard With Exponential Growth 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) y = y * (i * exp(x)) [web citation]
4 Term Standard With Exponential Growth 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) + a4sin(4x)+b4cos(4x) y = y * (k * exp(x)) [web citation]



Inverse 1 Term (Scaled X) 2D		y = a0 + a1sin(c1x)+b1cos(c1x) y = x / y [web citation]
Inverse 1 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) y = x / y [web citation]
Inverse 2 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) y = x / y [web citation]
Inverse 3 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) y = x / y [web citation]
Inverse 4 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) + a4sin(4x)+b4cos(4x) y = x / y [web citation]



1 Term (Scaled X) With Linear Decay 2D		y = a0 + a1sin(c1x)+b1cos(c1x) y = y / (f * x) [web citation]
1 Term Standard With Linear Decay 2D		y = a0 + a1sin(x)+b1cos(x) y = y / (d * x) [web citation]
2 Term Standard With Linear Decay 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) y = y / (g * x) [web citation]
3 Term Standard With Linear Decay 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) y = y / (i * x) [web citation]
4 Term Standard With Linear Decay 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) + a4sin(4x)+b4cos(4x) y = y / (k * x) [web citation]



1 Term (Scaled X) With Linear Growth 2D		y = a0 + a1sin(c1x)+b1cos(c1x) y = y * (f * x) [web citation]
1 Term Standard With Linear Growth 2D		y = a0 + a1sin(x)+b1cos(x) y = y * (d * x) [web citation]
2 Term Standard With Linear Growth 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) y = y * (g * x) [web citation]
3 Term Standard With Linear Growth 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) y = y * (i * x) [web citation]
4 Term Standard With Linear Growth 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) + a4sin(4x)+b4cos(4x) y = y * (k * x) [web citation]



1 Term (Scaled X) 2D		y = a0 + a1sin(c1x)+b1cos(c1x) [web citation]
1 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) [web citation]
2 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) [web citation]
3 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) [web citation]
4 Term Standard 2D		y = a0 + a1sin(x)+b1cos(x) + a2sin(2x)+b2cos(2x) + a3sin(3x)+b3cos(3x) + a4sin(4x)+b4cos(4x) [web citation]

2D LegendrePolynomial

Gamma Ray Angular Distribution (degrees) A 2D		y = A0 + A2 * P₂(cos(theta))
Gamma Ray Angular Distribution (degrees) B 2D		y = A0 + A2 * P₂(cos(theta)) + A4 * P₄(cos(theta))
Gamma Ray Angular Distribution (radians) A 2D		y = A0 + A2 * P₂(cos(theta))
Gamma Ray Angular Distribution (radians) B 2D		y = A0 + A2 * P₂(cos(theta)) + A4 * P₄(cos(theta))
Legendre Polynomial A - Second Degree 2D		y = a + bx + cP₂ [web citation]
Legendre Polynomial B - Third Degree 2D		y = a + bx + cP₂ + dP₃ [web citation]
Legendre Polynomial C - Fourth Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ [web citation]
Legendre Polynomial D - Fifth Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ + gP₅ [web citation]
Legendre Polynomial E - Sixth Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ + gP₅ + hP₆ [web citation]
Legendre Polynomial F - Seventh Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ + gP₅ + hP₆ + iP₇ [web citation]
Legendre Polynomial G - Eighth Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ + gP₅ + hP₆ + iP₇ + jP₈ [web citation]
Legendre Polynomial H - Ninth Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ + gP₅ + hP₆ + iP₇ + jP₈ + kP₉ [web citation]
Legendre Polynomial I - Tenth Degree 2D		y = a + bx + cP₂ + dP₃ + fP₄ + gP₅ + hP₆ + iP₇ + jP₈ + kP₉ + mP₁₀ [web citation]

2D Logarithmic

Bradley Transform With Exponential Decay And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y / exp(x) + Offset
Bradley With Exponential Decay And Offset 2D		y = a * ln(-b * ln(x)) y = y / exp(x) + Offset



Base 10 Logarithmic With Exponential Decay 2D		y = a + blog₁₀(x) y = y / (c exp(x))
Bradley Transform With Exponential Decay 2D		y = a * ln(-b * ln(cx + d)) y = y / exp(x)
Bradley With Exponential Decay 2D		y = a * ln(-b * ln(x)) y = y / exp(x)
Crystal Resonator Ageing MIL-PRF-55310E With Exponential Decay 2D		y = A(ln(Bt + 1)) + f0 y = y / (d * exp(x))
Cubic Logarithmic Scaled With Exponential Decay 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³ y = y / (g * exp(x))
Cubic Logarithmic Transform With Exponential Decay 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³ y = y / (h * exp(x))
Cubic Logarithmic With Exponential Decay 2D		y = a + bln(x) + cln(x)² + dln(x)³ y = y / (f exp(x))
Linear Logarithmic Scaled With Exponential Decay 2D		y = a + bln(cx) y = y / (d exp(x))
Linear Logarithmic Shifted With Exponential Decay 2D		y = a + bln(c+x) y = y / (d exp(x))
Linear Logarithmic Transform With Exponential Decay 2D		y = a + bln(cx+d) y = y / (f exp(x))
Linear Logarithmic With Exponential Decay 2D		y = a + bln(x) y = y / (c exp(x))
Quadratic Logarithmic Scaled With Exponential Decay 2D		y = a + bln(dx) + cln(dx)² y = y / (f * exp(x))
Quadratic Logarithmic Transform With Exponential Decay 2D		y = a + bln(dx+f) + cln(dx+f)² y = y / (g * exp(x))
Quadratic Logarithmic With Exponential Decay 2D		y = a + bln(x) + cln(x)² y = y / (d * exp(x))
Quartic Logarithmic Scaled With Exponential Decay 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ y = y / (h * exp(x))
Quartic Logarithmic Transform With Exponential Decay 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴ y = y / (i * exp(x))
Quartic Logarithmic With Exponential Decay 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ y = y / (g * exp(x))
Quintic Logarithmic Scaled With Exponential Decay 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴ y = y / (i * exp(x))
Quintic Logarithmic Transform With Exponential Decay 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵ y = y / (j * exp(x))
Quintic Logarithmic With Exponential Decay 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + gln(x)⁵ y = y / (h exp(x))



Bradley Transform With Exponential Growth And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y * exp(x) + Offset
Bradley With Exponential Growth And Offset 2D		y = a * ln(-b * ln(x)) y = y * exp(x) + Offset



Base 10 Logarithmic With Exponential Growth 2D		y = a + blog₁₀(x) y = y (c * exp(x))
Bradley Transform With Exponential Growth 2D		y = a * ln(-b * ln(cx + d)) y = y * exp(x)
Bradley With Exponential Growth 2D		y = a * ln(-b * ln(x)) y = y * exp(x)
Crystal Resonator Ageing MIL-PRF-55310E With Exponential Growth 2D		y = A(ln(Bt + 1)) + f0 y = y * (d * exp(x))
Cubic Logarithmic Scaled With Exponential Growth 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³ y = y * (g * exp(x))
Cubic Logarithmic Transform With Exponential Growth 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³ y = y * (h * exp(x))
Cubic Logarithmic With Exponential Growth 2D		y = a + bln(x) + cln(x)² + dln(x)³ y = y (f * exp(x))
Linear Logarithmic Scaled With Exponential Growth 2D		y = a + bln(cx) y = y (d * exp(x))
Linear Logarithmic Shifted With Exponential Growth 2D		y = a + bln(c+x) y = y (d * exp(x))
Linear Logarithmic Transform With Exponential Growth 2D		y = a + bln(cx+d) y = y (f * exp(x))
Linear Logarithmic With Exponential Growth 2D		y = a + bln(x) y = y (c * exp(x))
Quadratic Logarithmic Scaled With Exponential Growth 2D		y = a + bln(dx) + cln(dx)² y = y * (f * exp(x))
Quadratic Logarithmic Transform With Exponential Growth 2D		y = a + bln(dx+f) + cln(dx+f)² y = y * (g * exp(x))
Quadratic Logarithmic With Exponential Growth 2D		y = a + bln(x) + cln(x)² y = y * (d * exp(x))
Quartic Logarithmic Scaled With Exponential Growth 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ y = y * (h * exp(x))
Quartic Logarithmic Transform With Exponential Growth 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴ y = y * (i * exp(x))
Quartic Logarithmic With Exponential Growth 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ y = y * (g * exp(x))
Quintic Logarithmic Scaled With Exponential Growth 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴ y = y * (i * exp(x))
Quintic Logarithmic Transform With Exponential Growth 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵ y = y * (j * exp(x))
Quintic Logarithmic With Exponential Growth 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + gln(x)⁵ y = y (h * exp(x))



Inverse Base 10 Logarithmic 2D		y = a + b*log₁₀(x) y = x / y
Inverse Bradley 2D		y = a * ln(-b * ln(x)) y = x / y
Inverse Bradley Transform 2D		y = a * ln(-b * ln(cx + d)) y = x / y
Inverse Crystal Resonator Ageing MIL-PRF-55310E 2D		y = A(ln(Bt + 1)) + f0 y = x / y
Inverse Cubic Logarithmic 2D		y = a + bln(x) + cln(x)² + d*ln(x)³ y = x / y
Inverse Cubic Logarithmic Scaled 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³ y = x / y
Inverse Cubic Logarithmic Transform 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³ y = x / y
Inverse Linear Logarithmic 2D		y = a + b*ln(x) y = x / y
Inverse Linear Logarithmic Scaled 2D		y = a + b*ln(cx) y = x / y
Inverse Linear Logarithmic Shifted 2D		y = a + b*ln(c+x) y = x / y
Inverse Linear Logarithmic Transform 2D		y = a + b*ln(cx+d) y = x / y
Inverse Quadratic Logarithmic 2D		y = a + bln(x) + cln(x)² y = x / y
Inverse Quadratic Logarithmic Scaled 2D		y = a + bln(dx) + cln(dx)² y = x / y
Inverse Quadratic Logarithmic Transform 2D		y = a + bln(dx+f) + cln(dx+f)² y = x / y
Inverse Quartic Logarithmic 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ y = x / y
Inverse Quartic Logarithmic Scaled 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ y = x / y
Inverse Quartic Logarithmic Transform 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴ y = x / y
Inverse Quintic Logarithmic 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + g*ln(x)⁵ y = x / y
Inverse Quintic Logarithmic Scaled 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴ y = x / y
Inverse Quintic Logarithmic Transform 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵ y = x / y



Inverse Bradley Transform With Offset 2D		y = a * ln(-b * ln(cx + d)) y = x / y + Offset
Inverse Bradley With Offset 2D		y = a * ln(-b * ln(x)) y = x / y + Offset



Bradley Transform With Linear Decay And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y / x + Offset
Bradley With Linear Decay And Offset 2D		y = a * ln(-b * ln(x)) y = y / x + Offset



Base 10 Logarithmic With Linear Decay 2D		y = a + blog₁₀(x) y = y / (c x)
Bradley Transform With Linear Decay 2D		y = a * ln(-b * ln(cx + d)) y = y / x
Bradley With Linear Decay 2D		y = a * ln(-b * ln(x)) y = y / x
Crystal Resonator Ageing MIL-PRF-55310E With Linear Decay 2D		y = A(ln(Bt + 1)) + f0 y = y / (d * x)
Cubic Logarithmic Scaled With Linear Decay 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³ y = y / (g * x)
Cubic Logarithmic Transform With Linear Decay 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³ y = y / (h * x)
Cubic Logarithmic With Linear Decay 2D		y = a + bln(x) + cln(x)² + dln(x)³ y = y / (f x)
Linear Logarithmic Scaled With Linear Decay 2D		y = a + bln(cx) y = y / (d x)
Linear Logarithmic Shifted With Linear Decay 2D		y = a + bln(c+x) y = y / (d x)
Linear Logarithmic Transform With Linear Decay 2D		y = a + bln(cx+d) y = y / (f x)
Linear Logarithmic With Linear Decay 2D		y = a + bln(x) y = y / (c x)
Quadratic Logarithmic Scaled With Linear Decay 2D		y = a + bln(dx) + cln(dx)² y = y / (f * x)
Quadratic Logarithmic Transform With Linear Decay 2D		y = a + bln(dx+f) + cln(dx+f)² y = y / (g * x)
Quadratic Logarithmic With Linear Decay 2D		y = a + bln(x) + cln(x)² y = y / (d * x)
Quartic Logarithmic Scaled With Linear Decay 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ y = y / (h * x)
Quartic Logarithmic Transform With Linear Decay 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴ y = y / (i * x)
Quartic Logarithmic With Linear Decay 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ y = y / (g * x)
Quintic Logarithmic Scaled With Linear Decay 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴ y = y / (i * x)
Quintic Logarithmic Transform With Linear Decay 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵ y = y / (j * x)
Quintic Logarithmic With Linear Decay 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + gln(x)⁵ y = y / (h x)



Bradley Transform With Linear Growth And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y * x + Offset
Bradley With Linear Growth And Offset 2D		y = a * ln(-b * ln(x)) y = y * x + Offset



Base 10 Logarithmic With Linear Growth 2D		y = a + blog₁₀(x) y = y (c * x)
Bradley Transform With Linear Growth 2D		y = a * ln(-b * ln(cx + d)) y = y * x
Bradley With Linear Growth 2D		y = a * ln(-b * ln(x)) y = y * x
Crystal Resonator Ageing MIL-PRF-55310E With Linear Growth 2D		y = A(ln(Bt + 1)) + f0 y = y * (d * x)
Cubic Logarithmic Scaled With Linear Growth 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³ y = y * (g * x)
Cubic Logarithmic Transform With Linear Growth 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³ y = y * (h * x)
Cubic Logarithmic With Linear Growth 2D		y = a + bln(x) + cln(x)² + dln(x)³ y = y (f * x)
Linear Logarithmic Scaled With Linear Growth 2D		y = a + bln(cx) y = y (d * x)
Linear Logarithmic Shifted With Linear Growth 2D		y = a + bln(c+x) y = y (d * x)
Linear Logarithmic Transform With Linear Growth 2D		y = a + bln(cx+d) y = y (f * x)
Linear Logarithmic With Linear Growth 2D		y = a + bln(x) y = y (c * x)
Quadratic Logarithmic Scaled With Linear Growth 2D		y = a + bln(dx) + cln(dx)² y = y * (f * x)
Quadratic Logarithmic Transform With Linear Growth 2D		y = a + bln(dx+f) + cln(dx+f)² y = y * (g * x)
Quadratic Logarithmic With Linear Growth 2D		y = a + bln(x) + cln(x)² y = y * (d * x)
Quartic Logarithmic Scaled With Linear Growth 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ y = y * (h * x)
Quartic Logarithmic Transform With Linear Growth 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴ y = y * (i * x)
Quartic Logarithmic With Linear Growth 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ y = y * (g * x)
Quintic Logarithmic Scaled With Linear Growth 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴ y = y * (i * x)
Quintic Logarithmic Transform With Linear Growth 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵ y = y * (j * x)
Quintic Logarithmic With Linear Growth 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + gln(x)⁵ y = y (h * x)



Reciprocal Base 10 Logarithmic 2D		y = a + b*log₁₀(x) y = 1.0 / y
Reciprocal Bradley 2D		y = a * ln(-b * ln(x)) y = 1.0 / y
Reciprocal Bradley Transform 2D		y = a * ln(-b * ln(cx + d)) y = 1.0 / y
Reciprocal Crystal Resonator Ageing MIL-PRF-55310E 2D		y = A(ln(Bt + 1)) + f0 y = 1.0 / y
Reciprocal Cubic Logarithmic 2D		y = a + bln(x) + cln(x)² + d*ln(x)³ y = 1.0 / y
Reciprocal Cubic Logarithmic Scaled 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³ y = 1.0 / y
Reciprocal Cubic Logarithmic Transform 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³ y = 1.0 / y
Reciprocal Linear Logarithmic 2D		y = a + b*ln(x) y = 1.0 / y
Reciprocal Linear Logarithmic Scaled 2D		y = a + b*ln(cx) y = 1.0 / y
Reciprocal Linear Logarithmic Shifted 2D		y = a + b*ln(c+x) y = 1.0 / y
Reciprocal Linear Logarithmic Transform 2D		y = a + b*ln(cx+d) y = 1.0 / y
Reciprocal Quadratic Logarithmic 2D		y = a + bln(x) + cln(x)² y = 1.0 / y
Reciprocal Quadratic Logarithmic Scaled 2D		y = a + bln(dx) + cln(dx)² y = 1.0 / y
Reciprocal Quadratic Logarithmic Transform 2D		y = a + bln(dx+f) + cln(dx+f)² y = 1.0 / y
Reciprocal Quartic Logarithmic 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ y = 1.0 / y
Reciprocal Quartic Logarithmic Scaled 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ y = 1.0 / y
Reciprocal Quartic Logarithmic Transform 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴ y = 1.0 / y
Reciprocal Quintic Logarithmic 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + g*ln(x)⁵ y = 1.0 / y
Reciprocal Quintic Logarithmic Scaled 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴ y = 1.0 / y
Reciprocal Quintic Logarithmic Transform 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵ y = 1.0 / y



Reciprocal Bradley Transform With Offset 2D		y = a * ln(-b * ln(cx + d)) y = 1.0 / y + Offset
Reciprocal Bradley With Offset 2D		y = a * ln(-b * ln(x)) y = 1.0 / y + Offset



Base 10 Logarithmic 2D		y = a + b*log₁₀(x)
Bradley 2D		y = a * ln(-b * ln(x))
Bradley Transform 2D		y = a * ln(-b * ln(cx + d))
Crystal Resonator Ageing MIL-PRF-55310E 2D		y = A(ln(Bt + 1)) + f0
Cubic Logarithmic 2D		y = a + bln(x) + cln(x)² + d*ln(x)³
Cubic Logarithmic Scaled 2D		y = a + bln(fx) + cln(fx)² + dln(fx)³
Cubic Logarithmic Transform 2D		y = a + bln(fx+g) + cln(fx+g)² + dln(fx+g)³
Linear Logarithmic 2D		y = a + b*ln(x)
Linear Logarithmic Scaled 2D		y = a + b*ln(cx)
Linear Logarithmic Shifted 2D		y = a + b*ln(c+x)
Linear Logarithmic Transform 2D		y = a + b*ln(cx+d)
Quadratic Logarithmic 2D		y = a + bln(x) + cln(x)²
Quadratic Logarithmic Scaled 2D		y = a + bln(dx) + cln(dx)²
Quadratic Logarithmic Transform 2D		y = a + bln(dx+f) + cln(dx+f)²
Quartic Logarithmic 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴
Quartic Logarithmic Scaled 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴
Quartic Logarithmic Transform 2D		y = a + bln(gx+h) + cln(gx+h)² + dln(gx+h)³ + fln(gx+h)⁴
Quintic Logarithmic 2D		y = a + bln(x) + cln(x)² + dln(x)³ + fln(x)⁴ + g*ln(x)⁵
Quintic Logarithmic Scaled 2D		y = a + bln(hx) + cln(hx)² + dln(hx)³ + fln(hx)⁴ + gln(hx)⁴
Quintic Logarithmic Transform 2D		y = a + bln(hx+i) + cln(hx+i)² + dln(hx+i)³ + fln(hx+i)⁴ + gln(hx+i)⁵



Bradley Transform With Offset 2D		y = a * ln(-b * ln(cx + d)) + Offset
Bradley With Offset 2D		y = a * ln(-b * ln(x)) + Offset



Bradley Plus Line 2D		y = a * ln(-b * ln(x)) y = y + (c * x) + d

2D Miscellaneous

Arrhenius Rate Constant Law Stretched With Exponential Decay And Offset 2D		y = a * exp(-pow(b/x, c)) y = y / exp(x) + Offset
Arrhenius Rate Constant Law With Exponential Decay And Offset 2D		y = a * exp(-b/x) y = y / exp(x) + Offset
Bleasdale-Nelder With Exponential Decay And Offset 2D		y = (a + bx)^-c y = y / (d * exp(x)) + Offset
Catenary Transform With Exponential Decay And Offset 2D		y = a * cosh((bx + c) / a) y = y / exp(x) + Offset [web citation]
Catenary With Exponential Decay And Offset 2D		y = a * cosh(x / a) y = y / exp(x) + Offset [web citation]
Cissoid Of Diocles Transform With Exponential Decay And Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y / exp(x) + Offset [web citation]
Cissoid Of Diocles With Exponential Decay And Offset 2D		y = a(x³ / (2b-x))^0.5 y = y / exp(x) + Offset [web citation]
Combined Power And Exponential With Exponential Decay And Offset 2D		y = ax^b * exp(cx) y = y / exp(x) + Offset
Double Langmuir Probe Characteristic With Exponential Decay And Offset 2D		y = a * tanh(bx+c) y = y / exp(x) + Offset
Double Rectangular Hyperbola A With Exponential Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y / (f * exp(x)) + Offset
Double Rectangular Hyperbola B With Exponential Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (g * exp(x)) + Offset
Figure Eight Curve Transform With Exponential Decay And Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y / exp(x) + Offset [web citation]
Figure Eight Curve With Exponential Decay And Offset 2D		y = a(x² - (x⁴/b²))^0.5 y = y / exp(x) + Offset [web citation]
Gunary With Exponential Decay And Offset 2D		y = x / (a + bx + cx^0.5) y = y / (d * exp(x)) + Offset
Hyperbola A Modified With Exponential Decay And Offset 2D		y = ax/(1+bx) y = y / exp(x) + Offset
Hyperbola B Modified With Exponential Decay And Offset 2D		y = x/(a+bx) y = y / (c * exp(x)) + Offset
Hyperbolic Decay With Exponential Decay And Offset 2D		y = ab/(b+x) y = y / exp(x) + Offset
Lame's Cubic Transform With Exponential Decay And Offset 2D		y = (a³ - (bx + c)³)^1/3 y = y / (d * exp(x)) + Offset [web citation]
Lame's Cubic With Exponential Decay And Offset 2D		y = (a³ - x³)^1/3 y = y / (b * exp(x)) + Offset [web citation]
Miscellaneous 1 With Exponential Decay And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (c * exp(x)) + Offset
Niele's Semi-cubical Parabola Transform With Exponential Decay And Offset 2D		y = (a(bx+c)²)^1.0/3.0 y = y / (d exp(x)) + Offset [web citation]
Niele's Semi-cubical Parabola With Exponential Decay And Offset 2D		y = (ax²)^1.0/3.0 y = y / (b * exp(x)) + Offset [web citation]
Pareto A With Exponential Decay And Offset 2D		y = 1 - x^-a y = y / (b * exp(x)) + Offset
Pareto B With Exponential Decay And Offset 2D		y = a(1 - x^-b) y = y / exp(x) + Offset
Pareto C With Exponential Decay And Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y / (c * exp(x)) + Offset
Pareto D With Exponential Decay And Offset 2D		y = 1.0 - (1.0 / x^a) y = y / (b * exp(x)) + Offset
Pear-shaped Quartic Transform With Exponential Decay And Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y / exp(x) + Offset [web citation]
Pear-shaped Quartic With Exponential Decay And Offset 2D		y = a(x³(b-x) / c²)^0.5 y = y / exp(x) + Offset [web citation]
Physicist Peter's Pendulum Traversal With Exponential Decay And Offset 2D		y = a*(x + b)^1/2 y = y / exp(x) + Offset
Polytrope Transform With Exponential Decay And Offset 2D		y = a / (cx + d)^b y = y / exp(x) + Offset [web citation]
Polytrope With Exponential Decay And Offset 2D		y = a / x^b y = y / exp(x) + Offset [web citation]
Pursuit Curve Transform With Exponential Decay And Offset 2D		y = a(bx + c)² - log(bx + c) y = y / (d * exp(x)) + Offset
Pursuit Curve With Exponential Decay And Offset 2D		y = ax² - log(x) y = y / (b * exp(x)) + Offset
Rectangular Hyperbola A With Exponential Decay And Offset 2D		y = ax/(b+x) y = y / exp(x) + Offset
Rectangular Hyperbola B With Exponential Decay And Offset 2D		y = ax/(b+x) + cx y = y / (d * exp(x)) + Offset
Serpentine With Exponential Decay And Offset 2D		y = ax / (1.0 + bx²) y = y / exp(x) + Offset
Shifted Reciprocal With Exponential Decay And Offset 2D		y = 1.0 / (a - x) y = y / (b * exp(x)) + Offset
Square Modified Transform With Exponential Decay And Offset 2D		y = (bx + c)² - a(bx + c) y = y / (d * exp(x)) + Offset
Square Modified With Exponential Decay And Offset 2D		y = x² - ax y = y / (b * exp(x)) + Offset
Timothy Strobel's Custom Equation With Exponential Decay And Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y / (j * exp(x)) + Offset [web citation]
Transition State Rate Constant Law With Exponential Decay And Offset 2D		y = ax^b * exp(-c/x) y = y / exp(x) + Offset
Trisectrix Of Maclaurin Transform With Exponential Decay And Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y / exp(x) + Offset [web citation]
Trisectrix Of Maclaurin With Exponential Decay And Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y / exp(x) + Offset [web citation]
Witch Of Maria Agnesi A With Exponential Decay And Offset 2D		y = 8a³ / (x² + 4a²) y = y / (b * exp(x)) + Offset
Witch Of Maria Agnesi B With Exponential Decay And Offset 2D		y = a³ / (x² + a²) y = y / (b * exp(x)) + Offset
Witch Of Maria Agnesi C With Exponential Decay And Offset 2D		y = a³ / ((x * b + c)² + a²) y = y / (d * exp(x)) + Offset



Arrhenius Rate Constant Law Stretched With Exponential Decay 2D		y = a * exp(-pow(b/x, c)) y = y / exp(x)
Arrhenius Rate Constant Law With Exponential Decay 2D		y = a * exp(-b/x) y = y / exp(x)
Bleasdale-Nelder With Exponential Decay 2D		y = (a + bx)^-c y = y / (d * exp(x))
Catenary Transform With Exponential Decay 2D		y = a * cosh((bx + c) / a) y = y / exp(x) [web citation]
Catenary With Exponential Decay 2D		y = a * cosh(x / a) y = y / exp(x) [web citation]
Cissoid Of Diocles Transform With Exponential Decay 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y / exp(x) [web citation]
Cissoid Of Diocles With Exponential Decay 2D		y = a(x³ / (2b-x))^0.5 y = y / exp(x) [web citation]
Combined Power And Exponential With Exponential Decay 2D		y = ax^b * exp(cx) y = y / exp(x)
David Rodbard NIH With Exponential Decay 2D		y = d + (a - d) / (1.0 + (x/c)^b) y = y / (f * exp(x)) [web citation]
Double Langmuir Probe Characteristic With Exponential Decay 2D		y = a * tanh(bx+c) y = y / exp(x)
Double Rectangular Hyperbola A With Exponential Decay 2D		y = ax/(b+x) + cx/(d+x) y = y / (f * exp(x))
Double Rectangular Hyperbola B With Exponential Decay 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (g * exp(x))
Figure Eight Curve Transform With Exponential Decay 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y / exp(x) [web citation]
Figure Eight Curve With Exponential Decay 2D		y = a(x² - (x⁴/b²))^0.5 y = y / exp(x) [web citation]
Gunary With Exponential Decay 2D		y = x / (a + bx + cx^0.5) y = y / (d * exp(x))
Hyperbola A Modified With Exponential Decay 2D		y = ax/(1+bx) y = y / exp(x)
Hyperbola B Modified With Exponential Decay 2D		y = x/(a+bx) y = y / (c * exp(x))
Hyperbolic Decay With Exponential Decay 2D		y = ab/(b+x) y = y / exp(x)
Karplus NMR Spectroscopy Scaled With Exponential Decay 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C J(da) = J(da) / (f * exp(x)) [web citation]
Karplus NMR Spectroscopy With Exponential Decay 2D		J(da) = Acos²(da) + Bcos(da) + C J(da) = J(da) / (d * exp(x)) [web citation]
Lame's Cubic Transform With Exponential Decay 2D		y = (a³ - (bx + c)³)^1/3 y = y / (d * exp(x)) [web citation]
Lame's Cubic With Exponential Decay 2D		y = (a³ - x³)^1/3 y = y / (b * exp(x)) [web citation]
Miscellaneous 1 With Exponential Decay 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (c * exp(x))
Morse Potential With Exponential Decay 2D		V = D(exp(-2m(x-u)) - 2exp(-m*(x-u))) + offset V = V / exp(x) [web citation]
Nelson-Siegel With Exponential Decay 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) y(m) = y(m) / (f * exp(x)) [web citation]
Nelson-Siegel-Svensson With Exponential Decay 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) y(m) = y(m) / (h exp(x)) [web citation]
Niele's Semi-cubical Parabola Transform With Exponential Decay 2D		y = (a(bx+c)²)^1.0/3.0 y = y / (d exp(x)) [web citation]
Niele's Semi-cubical Parabola With Exponential Decay 2D		y = (ax²)^1.0/3.0 y = y / (b * exp(x)) [web citation]
Pareto A With Exponential Decay 2D		y = 1 - x^-a y = y / (b * exp(x))
Pareto B With Exponential Decay 2D		y = a(1 - x^-b) y = y / exp(x)
Pareto C With Exponential Decay 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y / (c * exp(x))
Pareto D With Exponential Decay 2D		y = 1.0 - (1.0 / x^a) y = y / (b * exp(x))
Pear-shaped Quartic Transform With Exponential Decay 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y / exp(x) [web citation]
Pear-shaped Quartic With Exponential Decay 2D		y = a(x³(b-x) / c²)^0.5 y = y / exp(x) [web citation]
Physicist Peter's Custom Equation With Exponential Decay 2D		y = A + B(X-C) + 0.5G(X-C)2 y = y / (f exp(x))
Physicist Peter's Pendulum Traversal With Exponential Decay 2D		y = a*(x + b)^1/2 y = y / exp(x)
Polytrope Transform With Exponential Decay 2D		y = a / (cx + d)^b y = y / exp(x) [web citation]
Polytrope With Exponential Decay 2D		y = a / x^b y = y / exp(x) [web citation]
Pursuit Curve Transform With Exponential Decay 2D		y = a(bx + c)² - log(bx + c) y = y / (d * exp(x))
Pursuit Curve With Exponential Decay 2D		y = ax² - log(x) y = y / (b * exp(x))
Rectangular Hyperbola A With Exponential Decay 2D		y = ax/(b+x) y = y / exp(x)
Rectangular Hyperbola B With Exponential Decay 2D		y = ax/(b+x) + cx y = y / (d * exp(x))
Serpentine With Exponential Decay 2D		y = ax / (1.0 + bx²) y = y / exp(x)
Shifted Reciprocal With Exponential Decay 2D		y = 1.0 / (a - x) y = y / (b * exp(x))
Square Modified Transform With Exponential Decay 2D		y = (bx + c)² - a(bx + c) y = y / (d * exp(x))
Square Modified With Exponential Decay 2D		y = x² - ax y = y / (b * exp(x))
Timothy Strobel's Custom Equation With Exponential Decay 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y / (j * exp(x)) [web citation]
Transition State Rate Constant Law With Exponential Decay 2D		y = ax^b * exp(-c/x) y = y / exp(x)
Trisectrix Of Maclaurin Transform With Exponential Decay 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y / exp(x) [web citation]
Trisectrix Of Maclaurin With Exponential Decay 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y / exp(x) [web citation]
Witch Of Maria Agnesi A With Exponential Decay 2D		y = 8a³ / (x² + 4a²) y = y / (b * exp(x))
Witch Of Maria Agnesi B With Exponential Decay 2D		y = a³ / (x² + a²) y = y / (b * exp(x))
Witch Of Maria Agnesi C With Exponential Decay 2D		y = a³ / ((x * b + c)² + a²) y = y / (d * exp(x))



Arrhenius Rate Constant Law Stretched With Exponential Growth And Offset 2D		y = a * exp(-pow(b/x, c)) y = y * exp(x) + Offset
Arrhenius Rate Constant Law With Exponential Growth And Offset 2D		y = a * exp(-b/x) y = y * exp(x) + Offset
Bleasdale-Nelder With Exponential Growth And Offset 2D		y = (a + bx)^-c y = y * (d * exp(x)) + Offset
Catenary Transform With Exponential Growth And Offset 2D		y = a * cosh((bx + c) / a) y = y * exp(x) + Offset [web citation]
Catenary With Exponential Growth And Offset 2D		y = a * cosh(x / a) y = y * exp(x) + Offset [web citation]
Cissoid Of Diocles Transform With Exponential Growth And Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y * exp(x) + Offset [web citation]
Cissoid Of Diocles With Exponential Growth And Offset 2D		y = a(x³ / (2b-x))^0.5 y = y * exp(x) + Offset [web citation]
Combined Power And Exponential With Exponential Growth And Offset 2D		y = ax^b * exp(cx) y = y * exp(x) + Offset
Double Langmuir Probe Characteristic With Exponential Growth And Offset 2D		y = a * tanh(bx+c) y = y * exp(x) + Offset
Double Rectangular Hyperbola A With Exponential Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y * (f * exp(x)) + Offset
Double Rectangular Hyperbola B With Exponential Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (g * exp(x)) + Offset
Figure Eight Curve Transform With Exponential Growth And Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y * exp(x) + Offset [web citation]
Figure Eight Curve With Exponential Growth And Offset 2D		y = a(x² - (x⁴/b²))^0.5 y = y * exp(x) + Offset [web citation]
Gunary With Exponential Growth And Offset 2D		y = x / (a + bx + cx^0.5) y = y * (d * exp(x)) + Offset
Hyperbola A Modified With Exponential Growth And Offset 2D		y = ax/(1+bx) y = y * exp(x) + Offset
Hyperbola B Modified With Exponential Growth And Offset 2D		y = x/(a+bx) y = y * (c * exp(x)) + Offset
Hyperbolic Decay With Exponential Growth And Offset 2D		y = ab/(b+x) y = y * exp(x) + Offset
Lame's Cubic Transform With Exponential Growth And Offset 2D		y = (a³ - (bx + c)³)^1/3 y = y * (d * exp(x)) + Offset [web citation]
Lame's Cubic With Exponential Growth And Offset 2D		y = (a³ - x³)^1/3 y = y * (b * exp(x)) + Offset [web citation]
Miscellaneous 1 With Exponential Growth And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (c * exp(x)) + Offset
Niele's Semi-cubical Parabola Transform With Exponential Growth And Offset 2D		y = (a(bx+c)²)^1.0/3.0 y = y (d * exp(x)) + Offset [web citation]
Niele's Semi-cubical Parabola With Exponential Growth And Offset 2D		y = (ax²)^1.0/3.0 y = y * (b * exp(x)) + Offset [web citation]
Pareto A With Exponential Growth And Offset 2D		y = 1 - x^-a y = y * (b * exp(x)) + Offset
Pareto B With Exponential Growth And Offset 2D		y = a(1 - x^-b) y = y * exp(x) + Offset
Pareto C With Exponential Growth And Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y * (c * exp(x)) + Offset
Pareto D With Exponential Growth And Offset 2D		y = 1.0 - (1.0 / x^a) y = y * (b * exp(x)) + Offset
Pear-shaped Quartic Transform With Exponential Growth And Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y * exp(x) + Offset [web citation]
Pear-shaped Quartic With Exponential Growth And Offset 2D		y = a(x³(b-x) / c²)^0.5 y = y * exp(x) + Offset [web citation]
Physicist Peter's Pendulum Traversal With Exponential Growth And Offset 2D		y = a(x + b)^1/2 y = y exp(x) + Offset
Polytrope Transform With Exponential Growth And Offset 2D		y = a / (cx + d)^b y = y * exp(x) + Offset [web citation]
Polytrope With Exponential Growth And Offset 2D		y = a / x^b y = y * exp(x) + Offset [web citation]
Pursuit Curve Transform With Exponential Growth And Offset 2D		y = a(bx + c)² - log(bx + c) y = y * (d * exp(x)) + Offset
Pursuit Curve With Exponential Growth And Offset 2D		y = ax² - log(x) y = y * (b * exp(x)) + Offset
Rectangular Hyperbola A With Exponential Growth And Offset 2D		y = ax/(b+x) y = y * exp(x) + Offset
Rectangular Hyperbola B With Exponential Growth And Offset 2D		y = ax/(b+x) + cx y = y * (d * exp(x)) + Offset
Serpentine With Exponential Growth And Offset 2D		y = ax / (1.0 + bx²) y = y * exp(x) + Offset
Shifted Reciprocal With Exponential Growth And Offset 2D		y = 1.0 / (a - x) y = y * (b * exp(x)) + Offset
Square Modified Transform With Exponential Growth And Offset 2D		y = (bx + c)² - a(bx + c) y = y * (d * exp(x)) + Offset
Square Modified With Exponential Growth And Offset 2D		y = x² - ax y = y * (b * exp(x)) + Offset
Timothy Strobel's Custom Equation With Exponential Growth And Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y * (j * exp(x)) + Offset [web citation]
Transition State Rate Constant Law With Exponential Growth And Offset 2D		y = ax^b * exp(-c/x) y = y * exp(x) + Offset
Trisectrix Of Maclaurin Transform With Exponential Growth And Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y * exp(x) + Offset [web citation]
Trisectrix Of Maclaurin With Exponential Growth And Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y * exp(x) + Offset [web citation]
Witch Of Maria Agnesi A With Exponential Growth And Offset 2D		y = 8a³ / (x² + 4a²) y = y * (b * exp(x)) + Offset
Witch Of Maria Agnesi B With Exponential Growth And Offset 2D		y = a³ / (x² + a²) y = y * (b * exp(x)) + Offset
Witch Of Maria Agnesi C With Exponential Growth And Offset 2D		y = a³ / ((x * b + c)² + a²) y = y * (d * exp(x)) + Offset



Arrhenius Rate Constant Law Stretched With Exponential Growth 2D		y = a * exp(-pow(b/x, c)) y = y * exp(x)
Arrhenius Rate Constant Law With Exponential Growth 2D		y = a * exp(-b/x) y = y * exp(x)
Bleasdale-Nelder With Exponential Growth 2D		y = (a + bx)^-c y = y * (d * exp(x))
Catenary Transform With Exponential Growth 2D		y = a * cosh((bx + c) / a) y = y * exp(x) [web citation]
Catenary With Exponential Growth 2D		y = a * cosh(x / a) y = y * exp(x) [web citation]
Cissoid Of Diocles Transform With Exponential Growth 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y * exp(x) [web citation]
Cissoid Of Diocles With Exponential Growth 2D		y = a(x³ / (2b-x))^0.5 y = y * exp(x) [web citation]
Combined Power And Exponential With Exponential Growth 2D		y = ax^b * exp(cx) y = y * exp(x)
David Rodbard NIH With Exponential Growth 2D		y = d + (a - d) / (1.0 + (x/c)^b) y = y * (f * exp(x)) [web citation]
Double Langmuir Probe Characteristic With Exponential Growth 2D		y = a * tanh(bx+c) y = y * exp(x)
Double Rectangular Hyperbola A With Exponential Growth 2D		y = ax/(b+x) + cx/(d+x) y = y * (f * exp(x))
Double Rectangular Hyperbola B With Exponential Growth 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (g * exp(x))
Figure Eight Curve Transform With Exponential Growth 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y * exp(x) [web citation]
Figure Eight Curve With Exponential Growth 2D		y = a(x² - (x⁴/b²))^0.5 y = y * exp(x) [web citation]
Gunary With Exponential Growth 2D		y = x / (a + bx + cx^0.5) y = y * (d * exp(x))
Hyperbola A Modified With Exponential Growth 2D		y = ax/(1+bx) y = y * exp(x)
Hyperbola B Modified With Exponential Growth 2D		y = x/(a+bx) y = y * (c * exp(x))
Hyperbolic Decay With Exponential Growth 2D		y = ab/(b+x) y = y * exp(x)
Karplus NMR Spectroscopy Scaled With Exponential Growth 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C J(da) = J(da) * (f * exp(x)) [web citation]
Karplus NMR Spectroscopy With Exponential Growth 2D		J(da) = Acos²(da) + Bcos(da) + C J(da) = J(da) * (d * exp(x)) [web citation]
Lame's Cubic Transform With Exponential Growth 2D		y = (a³ - (bx + c)³)^1/3 y = y * (d * exp(x)) [web citation]
Lame's Cubic With Exponential Growth 2D		y = (a³ - x³)^1/3 y = y * (b * exp(x)) [web citation]
Miscellaneous 1 With Exponential Growth 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (c * exp(x))
Morse Potential With Exponential Growth 2D		V = D(exp(-2m(x-u)) - 2exp(-m(x-u))) + offset V = V exp(x) [web citation]
Nelson-Siegel With Exponential Growth 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) y(m) = y(m) * (f * exp(x)) [web citation]
Nelson-Siegel-Svensson With Exponential Growth 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) y(m) = y(m) (h * exp(x)) [web citation]
Niele's Semi-cubical Parabola Transform With Exponential Growth 2D		y = (a(bx+c)²)^1.0/3.0 y = y (d * exp(x)) [web citation]
Niele's Semi-cubical Parabola With Exponential Growth 2D		y = (ax²)^1.0/3.0 y = y * (b * exp(x)) [web citation]
Pareto A With Exponential Growth 2D		y = 1 - x^-a y = y * (b * exp(x))
Pareto B With Exponential Growth 2D		y = a(1 - x^-b) y = y * exp(x)
Pareto C With Exponential Growth 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y * (c * exp(x))
Pareto D With Exponential Growth 2D		y = 1.0 - (1.0 / x^a) y = y * (b * exp(x))
Pear-shaped Quartic Transform With Exponential Growth 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y * exp(x) [web citation]
Pear-shaped Quartic With Exponential Growth 2D		y = a(x³(b-x) / c²)^0.5 y = y * exp(x) [web citation]
Physicist Peter's Custom Equation With Exponential Growth 2D		y = A + B(X-C) + 0.5G(X-C)2 y = y (f * exp(x))
Physicist Peter's Pendulum Traversal With Exponential Growth 2D		y = a(x + b)^1/2 y = y exp(x)
Polytrope Transform With Exponential Growth 2D		y = a / (cx + d)^b y = y * exp(x) [web citation]
Polytrope With Exponential Growth 2D		y = a / x^b y = y * exp(x) [web citation]
Pursuit Curve Transform With Exponential Growth 2D		y = a(bx + c)² - log(bx + c) y = y * (d * exp(x))
Pursuit Curve With Exponential Growth 2D		y = ax² - log(x) y = y * (b * exp(x))
Rectangular Hyperbola A With Exponential Growth 2D		y = ax/(b+x) y = y * exp(x)
Rectangular Hyperbola B With Exponential Growth 2D		y = ax/(b+x) + cx y = y * (d * exp(x))
Serpentine With Exponential Growth 2D		y = ax / (1.0 + bx²) y = y * exp(x)
Shifted Reciprocal With Exponential Growth 2D		y = 1.0 / (a - x) y = y * (b * exp(x))
Square Modified Transform With Exponential Growth 2D		y = (bx + c)² - a(bx + c) y = y * (d * exp(x))
Square Modified With Exponential Growth 2D		y = x² - ax y = y * (b * exp(x))
Timothy Strobel's Custom Equation With Exponential Growth 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y * (j * exp(x)) [web citation]
Transition State Rate Constant Law With Exponential Growth 2D		y = ax^b * exp(-c/x) y = y * exp(x)
Trisectrix Of Maclaurin Transform With Exponential Growth 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y * exp(x) [web citation]
Trisectrix Of Maclaurin With Exponential Growth 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y * exp(x) [web citation]
Witch Of Maria Agnesi A With Exponential Growth 2D		y = 8a³ / (x² + 4a²) y = y * (b * exp(x))
Witch Of Maria Agnesi B With Exponential Growth 2D		y = a³ / (x² + a²) y = y * (b * exp(x))
Witch Of Maria Agnesi C With Exponential Growth 2D		y = a³ / ((x * b + c)² + a²) y = y * (d * exp(x))



Inverse Arrhenius Rate Constant Law 2D		y = a * exp(-b/x) y = x / y
Inverse Arrhenius Rate Constant Law Stretched 2D		y = a * exp(-pow(b/x, c)) y = x / y
Inverse Bleasdale-Nelder 2D		y = (a + bx)^-c y = x / y
Inverse Catenary 2D		y = a * cosh(x / a) y = x / y [web citation]
Inverse Catenary Transform 2D		y = a * cosh((bx + c) / a) y = x / y [web citation]
Inverse Cissoid Of Diocles 2D		y = a(x³ / (2b-x))^0.5 y = x / y [web citation]
Inverse Cissoid Of Diocles Transform 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = x / y [web citation]
Inverse David Rodbard NIH 2D		y = d + (a - d) / (1.0 + (x/c)^b) y = x / y [web citation]
Inverse Double Langmuir Probe Characteristic 2D		y = a * tanh(bx+c) y = x / y
Inverse Double Rectangular Hyperbola A 2D		y = ax/(b+x) + cx/(d+x) y = x / y
Inverse Double Rectangular Hyperbola B 2D		y = ax/(b+x) + cx/(d+x) + fx y = x / y
Inverse Figure Eight Curve 2D		y = a(x² - (x⁴/b²))^0.5 y = x / y [web citation]
Inverse Figure Eight Curve Transform 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = x / y [web citation]
Inverse Hyperbolic Decay 2D		y = ab/(b+x) y = x / y
Inverse Karplus NMR Spectroscopy 2D		J(da) = Acos²(da) + Bcos(da) + C J(da) = x / J(da) [web citation]
Inverse Karplus NMR Spectroscopy Scaled 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C J(da) = x / J(da) [web citation]
Inverse Lame's Cubic 2D		y = (a³ - x³)^1/3 y = x / y [web citation]
Inverse Lame's Cubic Transform 2D		y = (a³ - (bx + c)³)^1/3 y = x / y [web citation]
Inverse Miscellaneous 1 2D		y = 1.0 + a(1.0 - exp(bx)) y = x / y
Inverse Morse Potential 2D		V = D(exp(-2m(x-u)) - 2exp(-m*(x-u))) + offset V = x / V [web citation]
Inverse Nelson-Siegel 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) y(m) = x / y(m) [web citation]
Inverse Nelson-Siegel-Svensson 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3*(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) y(m) = x / y(m) [web citation]
Inverse Niele's Semi-cubical Parabola 2D		y = (ax²)^1.0/3.0 y = x / y [web citation]
Inverse Niele's Semi-cubical Parabola Transform 2D		y = (a(b*x+c)²)^1.0/3.0 y = x / y [web citation]
Inverse Pareto A 2D		y = 1 - x^-a y = x / y
Inverse Pareto B 2D		y = a(1 - x^-b) y = x / y
Inverse Pareto C 2D		y = 1.0 - (1.0 / (1 + ax)^b y = x / y
Inverse Pareto D 2D		y = 1.0 - (1.0 / x^a) y = x / y
Inverse Pear-shaped Quartic 2D		y = a(x³(b-x) / c²)^0.5 y = x / y [web citation]
Inverse Pear-shaped Quartic Transform 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = x / y [web citation]
Inverse Physicist Peter's Custom Equation 2D		y = A + B(X-C) + 0.5G(X-C)*2 y = x / y
Inverse Physicist Peter's Pendulum Traversal 2D		y = a*(x + b)^1/2 y = x / y
Inverse Polytrope Transform 2D		y = a / (cx + d)^b y = x / y [web citation]
Inverse Pursuit Curve 2D		y = ax² - log(x) y = x / y
Inverse Pursuit Curve Transform 2D		y = a(bx + c)² - log(bx + c) y = x / y
Inverse Rectangular Hyperbola B 2D		y = ax/(b+x) + cx y = x / y
Inverse Shifted Reciprocal 2D		y = 1.0 / (a - x) y = x / y
Inverse Square Modified 2D		y = x² - ax y = x / y
Inverse Square Modified Transform 2D		y = (bx + c)² - a(bx + c) y = x / y
Inverse Timothy Strobel's Custom Equation 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = x / y [web citation]
Inverse Transition State Rate Constant Law 2D		y = ax^b * exp(-c/x) y = x / y
Inverse Trisectrix Of Maclaurin 2D		y = a(x²(3b-x) / (b+x))^0.5 y = x / y [web citation]
Inverse Trisectrix Of Maclaurin Transform 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = x / y [web citation]
Inverse Witch Of Maria Agnesi A 2D		y = 8a³ / (x² + 4a²) y = x / y
Inverse Witch Of Maria Agnesi B 2D		y = a³ / (x² + a²) y = x / y
Inverse Witch Of Maria Agnesi C 2D		y = a³ / ((x * b + c)² + a²) y = x / y



Inverse Arrhenius Rate Constant Law Stretched With Offset 2D		y = a * exp(-pow(b/x, c)) y = x / y + Offset
Inverse Arrhenius Rate Constant Law With Offset 2D		y = a * exp(-b/x) y = x / y + Offset
Inverse Bleasdale-Nelder With Offset 2D		y = (a + bx)^-c y = x / y + Offset
Inverse Catenary Transform With Offset 2D		y = a * cosh((bx + c) / a) y = x / y + Offset [web citation]
Inverse Catenary With Offset 2D		y = a * cosh(x / a) y = x / y + Offset [web citation]
Inverse Cissoid Of Diocles Transform With Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = x / y + Offset [web citation]
Inverse Cissoid Of Diocles With Offset 2D		y = a(x³ / (2b-x))^0.5 y = x / y + Offset [web citation]
Inverse Double Langmuir Probe Characteristic With Offset 2D		y = a * tanh(bx+c) y = x / y + Offset
Inverse Double Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + cx/(d+x) y = x / y + Offset
Inverse Double Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = x / y + Offset
Inverse Figure Eight Curve Transform With Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = x / y + Offset [web citation]
Inverse Figure Eight Curve With Offset 2D		y = a(x² - (x⁴/b²))^0.5 y = x / y + Offset [web citation]
Inverse Hyperbolic Decay With Offset 2D		y = ab/(b+x) y = x / y + Offset
Inverse Lame's Cubic Transform With Offset 2D		y = (a³ - (bx + c)³)^1/3 y = x / y + Offset [web citation]
Inverse Lame's Cubic With Offset 2D		y = (a³ - x³)^1/3 y = x / y + Offset [web citation]
Inverse Miscellaneous 1 With Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = x / y + Offset
Inverse Niele's Semi-cubical Parabola Transform With Offset 2D		y = (a(b*x+c)²)^1.0/3.0 y = x / y + Offset [web citation]
Inverse Niele's Semi-cubical Parabola With Offset 2D		y = (ax²)^1.0/3.0 y = x / y + Offset [web citation]
Inverse Pareto A With Offset 2D		y = 1 - x^-a y = x / y + Offset
Inverse Pareto B With Offset 2D		y = a(1 - x^-b) y = x / y + Offset
Inverse Pareto C With Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b y = x / y + Offset
Inverse Pareto D With Offset 2D		y = 1.0 - (1.0 / x^a) y = x / y + Offset
Inverse Pear-shaped Quartic Transform With Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = x / y + Offset [web citation]
Inverse Pear-shaped Quartic With Offset 2D		y = a(x³(b-x) / c²)^0.5 y = x / y + Offset [web citation]
Inverse Physicist Peter's Pendulum Traversal With Offset 2D		y = a*(x + b)^1/2 y = x / y + Offset
Inverse Polytrope Transform With Offset 2D		y = a / (cx + d)^b y = x / y + Offset [web citation]
Inverse Pursuit Curve Transform With Offset 2D		y = a(bx + c)² - log(bx + c) y = x / y + Offset
Inverse Pursuit Curve With Offset 2D		y = ax² - log(x) y = x / y + Offset
Inverse Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx y = x / y + Offset
Inverse Shifted Reciprocal With Offset 2D		y = 1.0 / (a - x) y = x / y + Offset
Inverse Square Modified Transform With Offset 2D		y = (bx + c)² - a(bx + c) y = x / y + Offset
Inverse Square Modified With Offset 2D		y = x² - ax y = x / y + Offset
Inverse Timothy Strobel's Custom Equation With Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = x / y + Offset [web citation]
Inverse Transition State Rate Constant Law With Offset 2D		y = ax^b * exp(-c/x) y = x / y + Offset
Inverse Trisectrix Of Maclaurin Transform With Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = x / y + Offset [web citation]
Inverse Trisectrix Of Maclaurin With Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 y = x / y + Offset [web citation]
Inverse Witch Of Maria Agnesi A With Offset 2D		y = 8a³ / (x² + 4a²) y = x / y + Offset
Inverse Witch Of Maria Agnesi B With Offset 2D		y = a³ / (x² + a²) y = x / y + Offset
Inverse Witch Of Maria Agnesi C With Offset 2D		y = a³ / ((x * b + c)² + a²) y = x / y + Offset



Arrhenius Rate Constant Law Stretched With Linear Decay And Offset 2D		y = a * exp(-pow(b/x, c)) y = y / x + Offset
Arrhenius Rate Constant Law With Linear Decay And Offset 2D		y = a * exp(-b/x) y = y / x + Offset
Bleasdale-Nelder With Linear Decay And Offset 2D		y = (a + bx)^-c y = y / (d * x) + Offset
Catenary Transform With Linear Decay And Offset 2D		y = a * cosh((bx + c) / a) y = y / x + Offset [web citation]
Catenary With Linear Decay And Offset 2D		y = a * cosh(x / a) y = y / x + Offset [web citation]
Cissoid Of Diocles Transform With Linear Decay And Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y / x + Offset [web citation]
Cissoid Of Diocles With Linear Decay And Offset 2D		y = a(x³ / (2b-x))^0.5 y = y / x + Offset [web citation]
Combined Power And Exponential With Linear Decay And Offset 2D		y = ax^b * exp(cx) y = y / x + Offset
Double Langmuir Probe Characteristic With Linear Decay And Offset 2D		y = a * tanh(bx+c) y = y / x + Offset
Double Rectangular Hyperbola A With Linear Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y / (f * x) + Offset
Double Rectangular Hyperbola B With Linear Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (g * x) + Offset
Figure Eight Curve Transform With Linear Decay And Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y / x + Offset [web citation]
Figure Eight Curve With Linear Decay And Offset 2D		y = a(x² - (x⁴/b²))^0.5 y = y / x + Offset [web citation]
Gunary With Linear Decay And Offset 2D		y = x / (a + bx + cx^0.5) y = y / (d * x) + Offset
Hyperbola A Modified With Linear Decay And Offset 2D		y = ax/(1+bx) y = y / x + Offset
Hyperbola B Modified With Linear Decay And Offset 2D		y = x/(a+bx) y = y / (c * x) + Offset
Hyperbolic Decay With Linear Decay And Offset 2D		y = ab/(b+x) y = y / x + Offset
Lame's Cubic Transform With Linear Decay And Offset 2D		y = (a³ - (bx + c)³)^1/3 y = y / (d * x) + Offset [web citation]
Lame's Cubic With Linear Decay And Offset 2D		y = (a³ - x³)^1/3 y = y / (b * x) + Offset [web citation]
Miscellaneous 1 With Linear Decay And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (c * x) + Offset
Niele's Semi-cubical Parabola Transform With Linear Decay And Offset 2D		y = (a(bx+c)²)^1.0/3.0 y = y / (d x) + Offset [web citation]
Niele's Semi-cubical Parabola With Linear Decay And Offset 2D		y = (ax²)^1.0/3.0 y = y / (b * x) + Offset [web citation]
Pareto A With Linear Decay And Offset 2D		y = 1 - x^-a y = y / (b * x) + Offset
Pareto B With Linear Decay And Offset 2D		y = a(1 - x^-b) y = y / x + Offset
Pareto C With Linear Decay And Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y / (c * x) + Offset
Pareto D With Linear Decay And Offset 2D		y = 1.0 - (1.0 / x^a) y = y / (b * x) + Offset
Pear-shaped Quartic Transform With Linear Decay And Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y / x + Offset [web citation]
Pear-shaped Quartic With Linear Decay And Offset 2D		y = a(x³(b-x) / c²)^0.5 y = y / x + Offset [web citation]
Physicist Peter's Pendulum Traversal With Linear Decay And Offset 2D		y = a*(x + b)^1/2 y = y / x + Offset
Polytrope Transform With Linear Decay And Offset 2D		y = a / (cx + d)^b y = y / x + Offset [web citation]
Polytrope With Linear Decay And Offset 2D		y = a / x^b y = y / x + Offset [web citation]
Pursuit Curve Transform With Linear Decay And Offset 2D		y = a(bx + c)² - log(bx + c) y = y / (d * x) + Offset
Pursuit Curve With Linear Decay And Offset 2D		y = ax² - log(x) y = y / (b * x) + Offset
Rectangular Hyperbola A With Linear Decay And Offset 2D		y = ax/(b+x) y = y / x + Offset
Rectangular Hyperbola B With Linear Decay And Offset 2D		y = ax/(b+x) + cx y = y / (d * x) + Offset
Serpentine With Linear Decay And Offset 2D		y = ax / (1.0 + bx²) y = y / x + Offset
Shifted Reciprocal With Linear Decay And Offset 2D		y = 1.0 / (a - x) y = y / (b * x) + Offset
Square Modified Transform With Linear Decay And Offset 2D		y = (bx + c)² - a(bx + c) y = y / (d * x) + Offset
Square Modified With Linear Decay And Offset 2D		y = x² - ax y = y / (b * x) + Offset
Timothy Strobel's Custom Equation With Linear Decay And Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y / (j * x) + Offset [web citation]
Transition State Rate Constant Law With Linear Decay And Offset 2D		y = ax^b * exp(-c/x) y = y / x + Offset
Trisectrix Of Maclaurin Transform With Linear Decay And Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y / x + Offset [web citation]
Trisectrix Of Maclaurin With Linear Decay And Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y / x + Offset [web citation]
Witch Of Maria Agnesi A With Linear Decay And Offset 2D		y = 8a³ / (x² + 4a²) y = y / (b * x) + Offset
Witch Of Maria Agnesi B With Linear Decay And Offset 2D		y = a³ / (x² + a²) y = y / (b * x) + Offset
Witch Of Maria Agnesi C With Linear Decay And Offset 2D		y = a³ / ((x * b + c)² + a²) y = y / (d * x) + Offset



Arrhenius Rate Constant Law Stretched With Linear Decay 2D		y = a * exp(-pow(b/x, c)) y = y / x
Arrhenius Rate Constant Law With Linear Decay 2D		y = a * exp(-b/x) y = y / x
Bleasdale-Nelder With Linear Decay 2D		y = (a + bx)^-c y = y / (d * x)
Catenary Transform With Linear Decay 2D		y = a * cosh((bx + c) / a) y = y / x [web citation]
Catenary With Linear Decay 2D		y = a * cosh(x / a) y = y / x [web citation]
Cissoid Of Diocles Transform With Linear Decay 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y / x [web citation]
Cissoid Of Diocles With Linear Decay 2D		y = a(x³ / (2b-x))^0.5 y = y / x [web citation]
Combined Power And Exponential With Linear Decay 2D		y = ax^b * exp(cx) y = y / x
David Rodbard NIH With Linear Decay 2D		y = d + (a - d) / (1.0 + (x/c)^b) y = y / (f * x) [web citation]
Double Langmuir Probe Characteristic With Linear Decay 2D		y = a * tanh(bx+c) y = y / x
Double Rectangular Hyperbola A With Linear Decay 2D		y = ax/(b+x) + cx/(d+x) y = y / (f * x)
Double Rectangular Hyperbola B With Linear Decay 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (g * x)
Figure Eight Curve Transform With Linear Decay 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y / x [web citation]
Figure Eight Curve With Linear Decay 2D		y = a(x² - (x⁴/b²))^0.5 y = y / x [web citation]
Gunary With Linear Decay 2D		y = x / (a + bx + cx^0.5) y = y / (d * x)
Hyperbola A Modified With Linear Decay 2D		y = ax/(1+bx) y = y / x
Hyperbola B Modified With Linear Decay 2D		y = x/(a+bx) y = y / (c * x)
Hyperbolic Decay With Linear Decay 2D		y = ab/(b+x) y = y / x
Karplus NMR Spectroscopy Scaled With Linear Decay 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C J(da) = J(da) / (f * x) [web citation]
Karplus NMR Spectroscopy With Linear Decay 2D		J(da) = Acos²(da) + Bcos(da) + C J(da) = J(da) / (d * x) [web citation]
Lame's Cubic Transform With Linear Decay 2D		y = (a³ - (bx + c)³)^1/3 y = y / (d * x) [web citation]
Lame's Cubic With Linear Decay 2D		y = (a³ - x³)^1/3 y = y / (b * x) [web citation]
Miscellaneous 1 With Linear Decay 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (c * x)
Morse Potential With Linear Decay 2D		V = D(exp(-2m(x-u)) - 2exp(-m*(x-u))) + offset V = V / x [web citation]
Nelson-Siegel With Linear Decay 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) y(m) = y(m) / (f * x) [web citation]
Nelson-Siegel-Svensson With Linear Decay 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) y(m) = y(m) / (h x) [web citation]
Niele's Semi-cubical Parabola Transform With Linear Decay 2D		y = (a(bx+c)²)^1.0/3.0 y = y / (d x) [web citation]
Niele's Semi-cubical Parabola With Linear Decay 2D		y = (ax²)^1.0/3.0 y = y / (b * x) [web citation]
Pareto A With Linear Decay 2D		y = 1 - x^-a y = y / (b * x)
Pareto B With Linear Decay 2D		y = a(1 - x^-b) y = y / x
Pareto C With Linear Decay 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y / (c * x)
Pareto D With Linear Decay 2D		y = 1.0 - (1.0 / x^a) y = y / (b * x)
Pear-shaped Quartic Transform With Linear Decay 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y / x [web citation]
Pear-shaped Quartic With Linear Decay 2D		y = a(x³(b-x) / c²)^0.5 y = y / x [web citation]
Physicist Peter's Custom Equation With Linear Decay 2D		y = A + B(X-C) + 0.5G(X-C)2 y = y / (f x)
Physicist Peter's Pendulum Traversal With Linear Decay 2D		y = a*(x + b)^1/2 y = y / x
Polytrope Transform With Linear Decay 2D		y = a / (cx + d)^b y = y / x [web citation]
Polytrope With Linear Decay 2D		y = a / x^b y = y / x [web citation]
Pursuit Curve Transform With Linear Decay 2D		y = a(bx + c)² - log(bx + c) y = y / (d * x)
Pursuit Curve With Linear Decay 2D		y = ax² - log(x) y = y / (b * x)
Rectangular Hyperbola A With Linear Decay 2D		y = ax/(b+x) y = y / x
Rectangular Hyperbola B With Linear Decay 2D		y = ax/(b+x) + cx y = y / (d * x)
Serpentine With Linear Decay 2D		y = ax / (1.0 + bx²) y = y / x
Shifted Reciprocal With Linear Decay 2D		y = 1.0 / (a - x) y = y / (b * x)
Square Modified Transform With Linear Decay 2D		y = (bx + c)² - a(bx + c) y = y / (d * x)
Square Modified With Linear Decay 2D		y = x² - ax y = y / (b * x)
Timothy Strobel's Custom Equation With Linear Decay 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y / (j * x) [web citation]
Transition State Rate Constant Law With Linear Decay 2D		y = ax^b * exp(-c/x) y = y / x
Trisectrix Of Maclaurin Transform With Linear Decay 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y / x [web citation]
Trisectrix Of Maclaurin With Linear Decay 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y / x [web citation]
Witch Of Maria Agnesi A With Linear Decay 2D		y = 8a³ / (x² + 4a²) y = y / (b * x)
Witch Of Maria Agnesi B With Linear Decay 2D		y = a³ / (x² + a²) y = y / (b * x)
Witch Of Maria Agnesi C With Linear Decay 2D		y = a³ / ((x * b + c)² + a²) y = y / (d * x)



Arrhenius Rate Constant Law Stretched With Linear Growth And Offset 2D		y = a * exp(-pow(b/x, c)) y = y * x + Offset
Arrhenius Rate Constant Law With Linear Growth And Offset 2D		y = a * exp(-b/x) y = y * x + Offset
Bleasdale-Nelder With Linear Growth And Offset 2D		y = (a + bx)^-c y = y * (d * x) + Offset
Catenary Transform With Linear Growth And Offset 2D		y = a * cosh((bx + c) / a) y = y * x + Offset [web citation]
Catenary With Linear Growth And Offset 2D		y = a * cosh(x / a) y = y * x + Offset [web citation]
Cissoid Of Diocles Transform With Linear Growth And Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y * x + Offset [web citation]
Cissoid Of Diocles With Linear Growth And Offset 2D		y = a(x³ / (2b-x))^0.5 y = y * x + Offset [web citation]
Combined Power And Exponential With Linear Growth And Offset 2D		y = ax^b * exp(cx) y = y * x + Offset
Double Langmuir Probe Characteristic With Linear Growth And Offset 2D		y = a * tanh(bx+c) y = y * x + Offset
Double Rectangular Hyperbola A With Linear Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y * (f * x) + Offset
Double Rectangular Hyperbola B With Linear Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (g * x) + Offset
Figure Eight Curve Transform With Linear Growth And Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y * x + Offset [web citation]
Figure Eight Curve With Linear Growth And Offset 2D		y = a(x² - (x⁴/b²))^0.5 y = y * x + Offset [web citation]
Gunary With Linear Growth And Offset 2D		y = x / (a + bx + cx^0.5) y = y * (d * x) + Offset
Hyperbola A Modified With Linear Growth And Offset 2D		y = ax/(1+bx) y = y * x + Offset
Hyperbola B Modified With Linear Growth And Offset 2D		y = x/(a+bx) y = y * (c * x) + Offset
Hyperbolic Decay With Linear Growth And Offset 2D		y = ab/(b+x) y = y * x + Offset
Lame's Cubic Transform With Linear Growth And Offset 2D		y = (a³ - (bx + c)³)^1/3 y = y * (d * x) + Offset [web citation]
Lame's Cubic With Linear Growth And Offset 2D		y = (a³ - x³)^1/3 y = y * (b * x) + Offset [web citation]
Miscellaneous 1 With Linear Growth And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (c * x) + Offset
Niele's Semi-cubical Parabola Transform With Linear Growth And Offset 2D		y = (a(bx+c)²)^1.0/3.0 y = y (d * x) + Offset [web citation]
Niele's Semi-cubical Parabola With Linear Growth And Offset 2D		y = (ax²)^1.0/3.0 y = y * (b * x) + Offset [web citation]
Pareto A With Linear Growth And Offset 2D		y = 1 - x^-a y = y * (b * x) + Offset
Pareto B With Linear Growth And Offset 2D		y = a(1 - x^-b) y = y * x + Offset
Pareto C With Linear Growth And Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y * (c * x) + Offset
Pareto D With Linear Growth And Offset 2D		y = 1.0 - (1.0 / x^a) y = y * (b * x) + Offset
Pear-shaped Quartic Transform With Linear Growth And Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y * x + Offset [web citation]
Pear-shaped Quartic With Linear Growth And Offset 2D		y = a(x³(b-x) / c²)^0.5 y = y * x + Offset [web citation]
Physicist Peter's Pendulum Traversal With Linear Growth And Offset 2D		y = a(x + b)^1/2 y = y x + Offset
Polytrope Transform With Linear Growth And Offset 2D		y = a / (cx + d)^b y = y * x + Offset [web citation]
Polytrope With Linear Growth And Offset 2D		y = a / x^b y = y * x + Offset [web citation]
Pursuit Curve Transform With Linear Growth And Offset 2D		y = a(bx + c)² - log(bx + c) y = y * (d * x) + Offset
Pursuit Curve With Linear Growth And Offset 2D		y = ax² - log(x) y = y * (b * x) + Offset
Rectangular Hyperbola A With Linear Growth And Offset 2D		y = ax/(b+x) y = y * x + Offset
Rectangular Hyperbola B With Linear Growth And Offset 2D		y = ax/(b+x) + cx y = y * (d * x) + Offset
Serpentine With Linear Growth And Offset 2D		y = ax / (1.0 + bx²) y = y * x + Offset
Shifted Reciprocal With Linear Growth And Offset 2D		y = 1.0 / (a - x) y = y * (b * x) + Offset
Square Modified Transform With Linear Growth And Offset 2D		y = (bx + c)² - a(bx + c) y = y * (d * x) + Offset
Square Modified With Linear Growth And Offset 2D		y = x² - ax y = y * (b * x) + Offset
Timothy Strobel's Custom Equation With Linear Growth And Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y * (j * x) + Offset [web citation]
Transition State Rate Constant Law With Linear Growth And Offset 2D		y = ax^b * exp(-c/x) y = y * x + Offset
Trisectrix Of Maclaurin Transform With Linear Growth And Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y * x + Offset [web citation]
Trisectrix Of Maclaurin With Linear Growth And Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y * x + Offset [web citation]
Witch Of Maria Agnesi A With Linear Growth And Offset 2D		y = 8a³ / (x² + 4a²) y = y * (b * x) + Offset
Witch Of Maria Agnesi B With Linear Growth And Offset 2D		y = a³ / (x² + a²) y = y * (b * x) + Offset
Witch Of Maria Agnesi C With Linear Growth And Offset 2D		y = a³ / ((x * b + c)² + a²) y = y * (d * x) + Offset



Arrhenius Rate Constant Law Stretched With Linear Growth 2D		y = a * exp(-pow(b/x, c)) y = y * x
Arrhenius Rate Constant Law With Linear Growth 2D		y = a * exp(-b/x) y = y * x
Bleasdale-Nelder With Linear Growth 2D		y = (a + bx)^-c y = y * (d * x)
Catenary Transform With Linear Growth 2D		y = a * cosh((bx + c) / a) y = y * x [web citation]
Catenary With Linear Growth 2D		y = a * cosh(x / a) y = y * x [web citation]
Cissoid Of Diocles Transform With Linear Growth 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = y * x [web citation]
Cissoid Of Diocles With Linear Growth 2D		y = a(x³ / (2b-x))^0.5 y = y * x [web citation]
Combined Power And Exponential With Linear Growth 2D		y = ax^b * exp(cx) y = y * x
David Rodbard NIH With Linear Growth 2D		y = d + (a - d) / (1.0 + (x/c)^b) y = y * (f * x) [web citation]
Double Langmuir Probe Characteristic With Linear Growth 2D		y = a * tanh(bx+c) y = y * x
Double Rectangular Hyperbola A With Linear Growth 2D		y = ax/(b+x) + cx/(d+x) y = y * (f * x)
Double Rectangular Hyperbola B With Linear Growth 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (g * x)
Figure Eight Curve Transform With Linear Growth 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = y * x [web citation]
Figure Eight Curve With Linear Growth 2D		y = a(x² - (x⁴/b²))^0.5 y = y * x [web citation]
Gunary With Linear Growth 2D		y = x / (a + bx + cx^0.5) y = y * (d * x)
Hyperbola A Modified With Linear Growth 2D		y = ax/(1+bx) y = y * x
Hyperbola B Modified With Linear Growth 2D		y = x/(a+bx) y = y * (c * x)
Hyperbolic Decay With Linear Growth 2D		y = ab/(b+x) y = y * x
Karplus NMR Spectroscopy Scaled With Linear Growth 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C J(da) = J(da) * (f * x) [web citation]
Karplus NMR Spectroscopy With Linear Growth 2D		J(da) = Acos²(da) + Bcos(da) + C J(da) = J(da) * (d * x) [web citation]
Lame's Cubic Transform With Linear Growth 2D		y = (a³ - (bx + c)³)^1/3 y = y * (d * x) [web citation]
Lame's Cubic With Linear Growth 2D		y = (a³ - x³)^1/3 y = y * (b * x) [web citation]
Miscellaneous 1 With Linear Growth 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (c * x)
Morse Potential With Linear Growth 2D		V = D(exp(-2m(x-u)) - 2exp(-m(x-u))) + offset V = V x [web citation]
Nelson-Siegel With Linear Growth 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) y(m) = y(m) * (f * x) [web citation]
Nelson-Siegel-Svensson With Linear Growth 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) y(m) = y(m) (h * x) [web citation]
Niele's Semi-cubical Parabola Transform With Linear Growth 2D		y = (a(bx+c)²)^1.0/3.0 y = y (d * x) [web citation]
Niele's Semi-cubical Parabola With Linear Growth 2D		y = (ax²)^1.0/3.0 y = y * (b * x) [web citation]
Pareto A With Linear Growth 2D		y = 1 - x^-a y = y * (b * x)
Pareto B With Linear Growth 2D		y = a(1 - x^-b) y = y * x
Pareto C With Linear Growth 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y * (c * x)
Pareto D With Linear Growth 2D		y = 1.0 - (1.0 / x^a) y = y * (b * x)
Pear-shaped Quartic Transform With Linear Growth 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = y * x [web citation]
Pear-shaped Quartic With Linear Growth 2D		y = a(x³(b-x) / c²)^0.5 y = y * x [web citation]
Physicist Peter's Custom Equation With Linear Growth 2D		y = A + B(X-C) + 0.5G(X-C)2 y = y (f * x)
Physicist Peter's Pendulum Traversal With Linear Growth 2D		y = a(x + b)^1/2 y = y x
Polytrope Transform With Linear Growth 2D		y = a / (cx + d)^b y = y * x [web citation]
Polytrope With Linear Growth 2D		y = a / x^b y = y * x [web citation]
Pursuit Curve Transform With Linear Growth 2D		y = a(bx + c)² - log(bx + c) y = y * (d * x)
Pursuit Curve With Linear Growth 2D		y = ax² - log(x) y = y * (b * x)
Rectangular Hyperbola A With Linear Growth 2D		y = ax/(b+x) y = y * x
Rectangular Hyperbola B With Linear Growth 2D		y = ax/(b+x) + cx y = y * (d * x)
Serpentine With Linear Growth 2D		y = ax / (1.0 + bx²) y = y * x
Shifted Reciprocal With Linear Growth 2D		y = 1.0 / (a - x) y = y * (b * x)
Square Modified Transform With Linear Growth 2D		y = (bx + c)² - a(bx + c) y = y * (d * x)
Square Modified With Linear Growth 2D		y = x² - ax y = y * (b * x)
Timothy Strobel's Custom Equation With Linear Growth 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = y * (j * x) [web citation]
Transition State Rate Constant Law With Linear Growth 2D		y = ax^b * exp(-c/x) y = y * x
Trisectrix Of Maclaurin Transform With Linear Growth 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = y * x [web citation]
Trisectrix Of Maclaurin With Linear Growth 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y * x [web citation]
Witch Of Maria Agnesi A With Linear Growth 2D		y = 8a³ / (x² + 4a²) y = y * (b * x)
Witch Of Maria Agnesi B With Linear Growth 2D		y = a³ / (x² + a²) y = y * (b * x)
Witch Of Maria Agnesi C With Linear Growth 2D		y = a³ / ((x * b + c)² + a²) y = y * (d * x)



Reciprocal Arrhenius Rate Constant Law 2D		y = a * exp(-b/x) y = 1.0 / y
Reciprocal Arrhenius Rate Constant Law Stretched 2D		y = a * exp(-pow(b/x, c)) y = 1.0 / y
Reciprocal Bleasdale-Nelder 2D		y = (a + bx)^-c y = 1.0 / y
Reciprocal Catenary 2D		y = a * cosh(x / a) y = 1.0 / y [web citation]
Reciprocal Catenary Transform 2D		y = a * cosh((bx + c) / a) y = 1.0 / y [web citation]
Reciprocal Cissoid Of Diocles 2D		y = a(x³ / (2b-x))^0.5 y = 1.0 / y [web citation]
Reciprocal Cissoid Of Diocles Transform 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = 1.0 / y [web citation]
Reciprocal Combined Power And Exponential 2D		y = ax^b * exp(cx) y = 1.0 / y
Reciprocal David Rodbard NIH 2D		y = d + (a - d) / (1.0 + (x/c)^b) y = 1.0 / y [web citation]
Reciprocal Double Langmuir Probe Characteristic 2D		y = a * tanh(bx+c) y = 1.0 / y
Reciprocal Double Rectangular Hyperbola A 2D		y = ax/(b+x) + cx/(d+x) y = 1.0 / y
Reciprocal Double Rectangular Hyperbola B 2D		y = ax/(b+x) + cx/(d+x) + fx y = 1.0 / y
Reciprocal Figure Eight Curve 2D		y = a(x² - (x⁴/b²))^0.5 y = 1.0 / y [web citation]
Reciprocal Figure Eight Curve Transform 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = 1.0 / y [web citation]
Reciprocal Gunary 2D		y = x / (a + bx + cx^0.5) y = 1.0 / y
Reciprocal Hyperbola A Modified 2D		y = ax/(1+bx) y = 1.0 / y
Reciprocal Hyperbola B Modified 2D		y = x/(a+bx) y = 1.0 / y
Reciprocal Hyperbolic Decay 2D		y = ab/(b+x) y = 1.0 / y
Reciprocal Karplus NMR Spectroscopy 2D		J(da) = Acos²(da) + Bcos(da) + C J(da) = 1.0 / J(da) [web citation]
Reciprocal Karplus NMR Spectroscopy Scaled 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C J(da) = 1.0 / J(da) [web citation]
Reciprocal Lame's Cubic 2D		y = (a³ - x³)^1/3 y = 1.0 / y [web citation]
Reciprocal Lame's Cubic Transform 2D		y = (a³ - (bx + c)³)^1/3 y = 1.0 / y [web citation]
Reciprocal Miscellaneous 1 2D		y = 1.0 + a(1.0 - exp(bx)) y = 1.0 / y
Reciprocal Morse Potential 2D		V = D(exp(-2m(x-u)) - 2exp(-m*(x-u))) + offset V = 1.0 / V [web citation]
Reciprocal Nelson-Siegel 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) y(m) = 1.0 / y(m) [web citation]
Reciprocal Nelson-Siegel-Svensson 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3*(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) y(m) = 1.0 / y(m) [web citation]
Reciprocal Niele's Semi-cubical Parabola 2D		y = (ax²)^1.0/3.0 y = 1.0 / y [web citation]
Reciprocal Niele's Semi-cubical Parabola Transform 2D		y = (a(b*x+c)²)^1.0/3.0 y = 1.0 / y [web citation]
Reciprocal Pareto A 2D		y = 1 - x^-a y = 1.0 / y
Reciprocal Pareto B 2D		y = a(1 - x^-b) y = 1.0 / y
Reciprocal Pareto C 2D		y = 1.0 - (1.0 / (1 + ax)^b y = 1.0 / y
Reciprocal Pareto D 2D		y = 1.0 - (1.0 / x^a) y = 1.0 / y
Reciprocal Pear-shaped Quartic 2D		y = a(x³(b-x) / c²)^0.5 y = 1.0 / y [web citation]
Reciprocal Pear-shaped Quartic Transform 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = 1.0 / y [web citation]
Reciprocal Physicist Peter's Custom Equation 2D		y = A + B(X-C) + 0.5G(X-C)*2 y = 1.0 / y
Reciprocal Physicist Peter's Pendulum Traversal 2D		y = a*(x + b)^1/2 y = 1.0 / y
Reciprocal Polytrope 2D		y = a / x^b y = 1.0 / y [web citation]
Reciprocal Polytrope Transform 2D		y = a / (cx + d)^b y = 1.0 / y [web citation]
Reciprocal Pursuit Curve 2D		y = ax² - log(x) y = 1.0 / y
Reciprocal Pursuit Curve Transform 2D		y = a(bx + c)² - log(bx + c) y = 1.0 / y
Reciprocal Rectangular Hyperbola A 2D		y = ax/(b+x) y = 1.0 / y
Reciprocal Rectangular Hyperbola B 2D		y = ax/(b+x) + cx y = 1.0 / y
Reciprocal Serpentine 2D		y = ax / (1.0 + bx²) y = 1.0 / y
Reciprocal Square Modified 2D		y = x² - ax y = 1.0 / y
Reciprocal Square Modified Transform 2D		y = (bx + c)² - a(bx + c) y = 1.0 / y
Reciprocal Timothy Strobel's Custom Equation 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = 1.0 / y [web citation]
Reciprocal Transition State Rate Constant Law 2D		y = ax^b * exp(-c/x) y = 1.0 / y
Reciprocal Trisectrix Of Maclaurin 2D		y = a(x²(3b-x) / (b+x))^0.5 y = 1.0 / y [web citation]
Reciprocal Trisectrix Of Maclaurin Transform 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = 1.0 / y [web citation]
Reciprocal Witch Of Maria Agnesi A 2D		y = 8a³ / (x² + 4a²) y = 1.0 / y
Reciprocal Witch Of Maria Agnesi B 2D		y = a³ / (x² + a²) y = 1.0 / y
Reciprocal Witch Of Maria Agnesi C 2D		y = a³ / ((x * b + c)² + a²) y = 1.0 / y



Reciprocal Arrhenius Rate Constant Law Stretched With Offset 2D		y = a * exp(-pow(b/x, c)) y = 1.0 / y + Offset
Reciprocal Arrhenius Rate Constant Law With Offset 2D		y = a * exp(-b/x) y = 1.0 / y + Offset
Reciprocal Bleasdale-Nelder With Offset 2D		y = (a + bx)^-c y = 1.0 / y + Offset
Reciprocal Catenary Transform With Offset 2D		y = a * cosh((bx + c) / a) y = 1.0 / y + Offset [web citation]
Reciprocal Catenary With Offset 2D		y = a * cosh(x / a) y = 1.0 / y + Offset [web citation]
Reciprocal Cissoid Of Diocles Transform With Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Cissoid Of Diocles With Offset 2D		y = a(x³ / (2b-x))^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Combined Power And Exponential With Offset 2D		y = ax^b * exp(cx) y = 1.0 / y + Offset
Reciprocal Double Langmuir Probe Characteristic With Offset 2D		y = a * tanh(bx+c) y = 1.0 / y + Offset
Reciprocal Double Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + cx/(d+x) y = 1.0 / y + Offset
Reciprocal Double Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = 1.0 / y + Offset
Reciprocal Figure Eight Curve Transform With Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Figure Eight Curve With Offset 2D		y = a(x² - (x⁴/b²))^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Gunary With Offset 2D		y = x / (a + bx + cx^0.5) y = 1.0 / y + Offset
Reciprocal Hyperbola A Modified With Offset 2D		y = ax/(1+bx) y = 1.0 / y + Offset
Reciprocal Hyperbola B Modified With Offset 2D		y = x/(a+bx) y = 1.0 / y + Offset
Reciprocal Hyperbolic Decay With Offset 2D		y = ab/(b+x) y = 1.0 / y + Offset
Reciprocal Lame's Cubic Transform With Offset 2D		y = (a³ - (bx + c)³)^1/3 y = 1.0 / y + Offset [web citation]
Reciprocal Lame's Cubic With Offset 2D		y = (a³ - x³)^1/3 y = 1.0 / y + Offset [web citation]
Reciprocal Miscellaneous 1 With Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = 1.0 / y + Offset
Reciprocal Niele's Semi-cubical Parabola Transform With Offset 2D		y = (a(b*x+c)²)^1.0/3.0 y = 1.0 / y + Offset [web citation]
Reciprocal Niele's Semi-cubical Parabola With Offset 2D		y = (ax²)^1.0/3.0 y = 1.0 / y + Offset [web citation]
Reciprocal Pareto A With Offset 2D		y = 1 - x^-a y = 1.0 / y + Offset
Reciprocal Pareto B With Offset 2D		y = a(1 - x^-b) y = 1.0 / y + Offset
Reciprocal Pareto C With Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b y = 1.0 / y + Offset
Reciprocal Pareto D With Offset 2D		y = 1.0 - (1.0 / x^a) y = 1.0 / y + Offset
Reciprocal Pear-shaped Quartic Transform With Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Pear-shaped Quartic With Offset 2D		y = a(x³(b-x) / c²)^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Physicist Peter's Pendulum Traversal With Offset 2D		y = a*(x + b)^1/2 y = 1.0 / y + Offset
Reciprocal Polytrope Transform With Offset 2D		y = a / (cx + d)^b y = 1.0 / y + Offset [web citation]
Reciprocal Polytrope With Offset 2D		y = a / x^b y = 1.0 / y + Offset [web citation]
Reciprocal Pursuit Curve Transform With Offset 2D		y = a(bx + c)² - log(bx + c) y = 1.0 / y + Offset
Reciprocal Pursuit Curve With Offset 2D		y = ax² - log(x) y = 1.0 / y + Offset
Reciprocal Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) y = 1.0 / y + Offset
Reciprocal Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx y = 1.0 / y + Offset
Reciprocal Serpentine With Offset 2D		y = ax / (1.0 + bx²) y = 1.0 / y + Offset
Reciprocal Square Modified Transform With Offset 2D		y = (bx + c)² - a(bx + c) y = 1.0 / y + Offset
Reciprocal Square Modified With Offset 2D		y = x² - ax y = 1.0 / y + Offset
Reciprocal Timothy Strobel's Custom Equation With Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) y = 1.0 / y + Offset [web citation]
Reciprocal Transition State Rate Constant Law With Offset 2D		y = ax^b * exp(-c/x) y = 1.0 / y + Offset
Reciprocal Trisectrix Of Maclaurin Transform With Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Trisectrix Of Maclaurin With Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 y = 1.0 / y + Offset [web citation]
Reciprocal Witch Of Maria Agnesi A With Offset 2D		y = 8a³ / (x² + 4a²) y = 1.0 / y + Offset
Reciprocal Witch Of Maria Agnesi B With Offset 2D		y = a³ / (x² + a²) y = 1.0 / y + Offset
Reciprocal Witch Of Maria Agnesi C With Offset 2D		y = a³ / ((x * b + c)² + a²) y = 1.0 / y + Offset



Arrhenius Rate Constant Law 2D		y = a * exp(-b/x)
Arrhenius Rate Constant Law Stretched 2D		y = a * exp(-pow(b/x, c))
Bleasdale-Nelder 2D		y = (a + bx)^-c
Catenary 2D		y = a * cosh(x / a) [web citation]
Catenary Transform 2D		y = a * cosh((bx + c) / a) [web citation]
Cissoid Of Diocles 2D		y = a(x³ / (2b-x))^0.5 [web citation]
Cissoid Of Diocles Transform 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 [web citation]
Combined Power And Exponential 2D		y = ax^b * exp(cx)
David Rodbard NIH 2D		y = d + (a - d) / (1.0 + (x/c)^b) [web citation]
Double Langmuir Probe Characteristic 2D		y = a * tanh(bx+c)
Double Rectangular Hyperbola A 2D		y = ax/(b+x) + cx/(d+x)
Double Rectangular Hyperbola B 2D		y = ax/(b+x) + cx/(d+x) + fx
Figure Eight Curve 2D		y = a(x² - (x⁴/b²))^0.5 [web citation]
Figure Eight Curve Transform 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 [web citation]
Gunary 2D		y = x / (a + bx + cx^0.5)
Hyperbola A Modified 2D		y = ax/(1+bx)
Hyperbola B Modified 2D		y = x/(a+bx)
Hyperbolic Decay 2D		y = ab/(b+x)
Karplus NMR Spectroscopy 2D		J(da) = Acos²(da) + Bcos(da) + C [web citation]
Karplus NMR Spectroscopy Scaled 2D		J(da) = Acos²(s * da) + Bcos(s * da) + C [web citation]
Lame's Cubic 2D		y = (a³ - x³)^1/3 [web citation]
Lame's Cubic Transform 2D		y = (a³ - (bx + c)³)^1/3 [web citation]
Miscellaneous 1 2D		y = 1.0 + a(1.0 - exp(bx))
Morse Potential 2D		V = D(exp(-2m(x-u)) - 2exp(-m*(x-u))) + offset [web citation]
Nelson-Siegel 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t))) [web citation]
Nelson-Siegel-Svensson 2D		y(m) = B0 + B1((1-exp(-m/t))/(m/t)) + B2(((1-exp(-m/t))/(m/t)) - exp(-m/t)) + B3*(((1-exp(-m/t2))/(m/t2)) - exp(-m/t2)) [web citation]
Niele's Semi-cubical Parabola 2D		y = (ax²)^1.0/3.0 [web citation]
Niele's Semi-cubical Parabola Transform 2D		y = (a(b*x+c)²)^1.0/3.0 [web citation]
Pareto A 2D		y = 1 - x^-a
Pareto B 2D		y = a(1 - x^-b)
Pareto C 2D		y = 1.0 - (1.0 / (1 + ax)^b
Pareto D 2D		y = 1.0 - (1.0 / x^a)
Pear-shaped Quartic 2D		y = a(x³(b-x) / c²)^0.5 [web citation]
Pear-shaped Quartic Transform 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 [web citation]
Physicist Peter's Custom Equation 2D		y = A + B(X-C) + 0.5G(X-C)*2
Physicist Peter's Pendulum Traversal 2D		y = a*(x + b)^1/2
Polytrope 2D		y = a / x^b [web citation]
Polytrope Transform 2D		y = a / (cx + d)^b [web citation]
Pursuit Curve 2D		y = ax² - log(x)
Pursuit Curve Transform 2D		y = a(bx + c)² - log(bx + c)
Rectangular Hyperbola A 2D		y = ax/(b+x)
Rectangular Hyperbola B 2D		y = ax/(b+x) + cx
Serpentine 2D		y = ax / (1.0 + bx²)
Shifted Reciprocal 2D		y = 1.0 / (a - x)
Square Modified 2D		y = x² - ax
Square Modified Transform 2D		y = (bx + c)² - a(bx + c)
Timothy Strobel's Custom Equation 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) [web citation]
Transition State Rate Constant Law 2D		y = ax^b * exp(-c/x)
Trisectrix Of Maclaurin 2D		y = a(x²(3b-x) / (b+x))^0.5 [web citation]
Trisectrix Of Maclaurin Transform 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 [web citation]
Witch Of Maria Agnesi A 2D		y = 8a³ / (x² + 4a²)
Witch Of Maria Agnesi B 2D		y = a³ / (x² + a²)
Witch Of Maria Agnesi C 2D		y = a³ / ((x * b + c)² + a²)



Arrhenius Rate Constant Law Stretched With Offset 2D		y = a * exp(-pow(b/x, c)) + Offset
Arrhenius Rate Constant Law With Offset 2D		y = a * exp(-b/x) + Offset
Bleasdale-Nelder With Offset 2D		y = (a + bx)^-c + Offset
Catenary Transform With Offset 2D		y = a * cosh((bx + c) / a) + Offset [web citation]
Catenary With Offset 2D		y = a * cosh(x / a) + Offset [web citation]
Cissoid Of Diocles Transform With Offset 2D		y = a((xc-d)³ / (2b-(xc-d)))^0.5 + Offset [web citation]
Cissoid Of Diocles With Offset 2D		y = a(x³ / (2b-x))^0.5 + Offset [web citation]
Combined Power And Exponential With Offset 2D		y = ax^b * exp(cx) + Offset
Double Langmuir Probe Characteristic With Offset 2D		y = a * tanh(bx+c) + Offset
Double Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + cx/(d+x) + Offset
Double Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx/(d+x) + fx + Offset
Figure Eight Curve Transform With Offset 2D		y = a((cx+d)² - ((cx+d)⁴/b²))^0.5 + Offset [web citation]
Figure Eight Curve With Offset 2D		y = a(x² - (x⁴/b²))^0.5 + Offset [web citation]
Gunary With Offset 2D		y = x / (a + bx + cx^0.5) + Offset
Hyperbola A Modified With Offset 2D		y = ax/(1+bx) + Offset
Hyperbola B Modified With Offset 2D		y = x/(a+bx) + Offset
Hyperbolic Decay With Offset 2D		y = ab/(b+x) + Offset
Lame's Cubic Transform With Offset 2D		y = (a³ - (bx + c)³)^1/3 + Offset [web citation]
Lame's Cubic With Offset 2D		y = (a³ - x³)^1/3 + Offset [web citation]
Miscellaneous 1 With Offset 2D		y = 1.0 + a(1.0 - exp(bx)) + Offset
Niele's Semi-cubical Parabola Transform With Offset 2D		y = (a(b*x+c)²)^1.0/3.0 + Offset [web citation]
Niele's Semi-cubical Parabola With Offset 2D		y = (ax²)^1.0/3.0 + Offset [web citation]
Pareto A With Offset 2D		y = 1 - x^-a + Offset
Pareto B With Offset 2D		y = a(1 - x^-b) + Offset
Pareto C With Offset 2D		y = 1.0 - (1.0 / (1 + ax)^b + Offset
Pareto D With Offset 2D		y = 1.0 - (1.0 / x^a) + Offset
Pear-shaped Quartic Transform With Offset 2D		y = a((dx+f)³(b-(dx+f)) / c²)^0.5 + Offset [web citation]
Pear-shaped Quartic With Offset 2D		y = a(x³(b-x) / c²)^0.5 + Offset [web citation]
Physicist Peter's Pendulum Traversal With Offset 2D		y = a*(x + b)^1/2 + Offset
Polytrope Transform With Offset 2D		y = a / (cx + d)^b + Offset [web citation]
Polytrope With Offset 2D		y = a / x^b + Offset [web citation]
Pursuit Curve Transform With Offset 2D		y = a(bx + c)² - log(bx + c) + Offset
Pursuit Curve With Offset 2D		y = ax² - log(x) + Offset
Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + Offset
Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx + Offset
Serpentine With Offset 2D		y = ax / (1.0 + bx²) + Offset
Shifted Reciprocal With Offset 2D		y = 1.0 / (a - x) + Offset
Square Modified Transform With Offset 2D		y = (bx + c)² - a(bx + c) + Offset
Square Modified With Offset 2D		y = x² - ax + Offset
Timothy Strobel's Custom Equation With Offset 2D		y = (A-BXC)(1-(0.5+(arctan((X-D)/E))/pi))+(F-GXH)(0.5+(arctan((X-D)/E))/pi) + Offset [web citation]
Transition State Rate Constant Law With Offset 2D		y = ax^b * exp(-c/x) + Offset
Trisectrix Of Maclaurin Transform With Offset 2D		y = a((cx+d)²(3b-(cx+d)) / (b+(cx+d)))^0.5 + Offset [web citation]
Trisectrix Of Maclaurin With Offset 2D		y = a(x²(3b-x) / (b+x))^0.5 + Offset [web citation]
Witch Of Maria Agnesi A With Offset 2D		y = 8a³ / (x² + 4a²) + Offset
Witch Of Maria Agnesi B With Offset 2D		y = a³ / (x² + a²) + Offset
Witch Of Maria Agnesi C With Offset 2D		y = a³ / ((x * b + c)² + a²) + Offset



Arrhenius Rate Constant Law Plus Line 2D		y = a * exp(-b/x) y = y + (c * x) + d
Catenary Plus Line 2D		y = a * cosh(x / a) y = y + (b * x) + c [web citation]
Cissoid Of Diocles Plus Line 2D		y = a(x³ / (2b-x))^0.5 y = y + (c * x) + d [web citation]
Figure Eight Curve Plus Line 2D		y = a(x² - (x⁴/b²))^0.5 y = y + (c * x) + d [web citation]
Hyperbola A Modified Plus Line 2D		y = ax/(1+bx) y = y + (c * x) + d
Hyperbola B Modified Plus Line 2D		y = x/(a+bx) y = y + (c * x) + d
Hyperbolic Decay Plus Line 2D		y = ab/(b+x) y = y + (c * x) + d
Lame's Cubic Plus Line 2D		y = (a³ - x³)^1/3 y = y + (b * x) + c [web citation]
Miscellaneous 1 Plus Line 2D		y = 1.0 + a(1.0 - exp(bx)) y = y + (c * x) + d
Niele's Semi-cubical Parabola Plus Line 2D		y = (ax²)^1.0/3.0 y = y + (b * x) + c [web citation]
Pareto A Plus Line 2D		y = 1 - x^-a y = y + (b * x) + c
Pareto B Plus Line 2D		y = a(1 - x^-b) y = y + (c * x) + d
Pareto C Plus Line 2D		y = 1.0 - (1.0 / (1 + ax)^b y = y + (c * x) + d
Pareto D Plus Line 2D		y = 1.0 - (1.0 / x^a) y = y + (b * x) + c
Physicist Peter's Pendulum Traversal Plus Line 2D		y = a(x + b)^1/2 y = y + (c x) + d
Polytrope Plus Line 2D		y = a / x^b y = y + (c * x) + d [web citation]
Pursuit Curve Plus Line 2D		y = ax² - log(x) y = y + (b * x) + c
Rectangular Hyperbola A Plus Line 2D		y = ax/(b+x) y = y + (c * x) + d
Serpentine Plus Line 2D		y = ax / (1.0 + bx²) y = y + (c * x) + d
Shifted Reciprocal Plus Line 2D		y = 1.0 / (a - x) y = y + (b * x) + c
Square Modified Plus Line 2D		y = x² - ax y = y + (b * x) + c
Trisectrix Of Maclaurin Plus Line 2D		y = a(x²(3b-x) / (b+x))^0.5 y = y + (c * x) + d [web citation]
Witch Of Maria Agnesi A Plus Line 2D		y = 8a³ / (x² + 4a²) y = y + (b * x) + c
Witch Of Maria Agnesi B Plus Line 2D		y = a³ / (x² + a²) y = y + (b * x) + c

2D NIST

NIST Bennett5 With Exponential Decay And Offset 2D		y = a * (b+x)^-1/c y = y / exp(x) + Offset [web citation]
NIST BoxBOD With Exponential Decay And Offset 2D		y = a * (1.0-exp(-b*x)) y = y / exp(x) + Offset [web citation]
NIST Chwirut With Exponential Decay And Offset 2D		y = exp(-ax) / (b + cx) y = y / (d * exp(x)) + Offset [web citation]
NIST DanWood With Exponential Decay And Offset 2D		y = a*x^b y = y / exp(x) + Offset [web citation]
NIST Eckerle4 With Exponential Decay And Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = y / exp(x) + Offset [web citation]
NIST Gauss With Exponential Decay And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y / (j * exp(x)) + Offset [web citation]
NIST Hahn With Exponential Decay And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * exp(x)) + Offset [web citation]
NIST Kirby With Exponential Decay And Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y / (g * exp(x)) + Offset [web citation]
NIST Lanczos With Exponential Decay And Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y / (h * exp(x)) + Offset [web citation]
NIST MGH09 With Exponential Decay And Offset 2D		y = a * (x² + bx) / (x² + cx + d) y = y / exp(x) + Offset [web citation]
NIST MGH10 With Exponential Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / exp(x) + Offset [web citation]
NIST Misra1a With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-b*x)) y = y / exp(x) + Offset [web citation]
NIST Misra1b With Exponential Decay And Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = y / exp(x) + Offset [web citation]
NIST Misra1c With Exponential Decay And Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y / exp(x) + Offset [web citation]
NIST Misra1d With Exponential Decay And Offset 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = y / exp(x) + Offset [web citation]
NIST Rat42 With Exponential Decay And Offset 2D		y = a / (1.0 + exp(b - c*x)) y = y / exp(x) + Offset [web citation]
NIST Rat43 With Exponential Decay And Offset 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = y / exp(x) + Offset [web citation]
NIST Thurber With Exponential Decay And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * exp(x)) + Offset [web citation]



NIST Bennett5 With Exponential Decay 2D		y = a * (b+x)^-1/c y = y / exp(x) [web citation]
NIST BoxBOD With Exponential Decay 2D		y = a * (1.0-exp(-b*x)) y = y / exp(x) [web citation]
NIST Chwirut With Exponential Decay 2D		y = exp(-ax) / (b + cx) y = y / (d * exp(x)) [web citation]
NIST DanWood With Exponential Decay 2D		y = a*x^b y = y / exp(x) [web citation]
NIST ENSO With Exponential Decay 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) y = y / (k * exp(x)) [web citation]
NIST Eckerle4 With Exponential Decay 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = y / exp(x) [web citation]
NIST Gauss With Exponential Decay 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y / (j * exp(x)) [web citation]
NIST Hahn With Exponential Decay 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * exp(x)) [web citation]
NIST Kirby With Exponential Decay 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y / (g * exp(x)) [web citation]
NIST Lanczos With Exponential Decay 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y / (h * exp(x)) [web citation]
NIST MGH09 With Exponential Decay 2D		y = a * (x² + bx) / (x² + cx + d) y = y / exp(x) [web citation]
NIST MGH10 With Exponential Decay 2D		y = a * exp(b/(x+c)) y = y / exp(x) [web citation]
NIST MGH17 With Exponential Decay 2D		y = a + bexp(-xd) + cexp(-xf) y = y / (g * exp(x)) [web citation]
NIST Misra1a With Exponential Decay 2D		y = a * (1.0 - exp(-b*x)) y = y / exp(x) [web citation]
NIST Misra1b With Exponential Decay 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = y / exp(x) [web citation]
NIST Misra1c With Exponential Decay 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y / exp(x) [web citation]
NIST Misra1d With Exponential Decay 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = y / exp(x) [web citation]
NIST Rat42 With Exponential Decay 2D		y = a / (1.0 + exp(b - c*x)) y = y / exp(x) [web citation]
NIST Rat43 With Exponential Decay 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = y / exp(x) [web citation]
NIST Roszman With Exponential Decay 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y / (f * exp(x)) [web citation]
NIST Thurber With Exponential Decay 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * exp(x)) [web citation]



NIST Bennett5 With Exponential Growth And Offset 2D		y = a * (b+x)^-1/c y = y * exp(x) + Offset [web citation]
NIST BoxBOD With Exponential Growth And Offset 2D		y = a * (1.0-exp(-bx)) y = y exp(x) + Offset [web citation]
NIST Chwirut With Exponential Growth And Offset 2D		y = exp(-ax) / (b + cx) y = y * (d * exp(x)) + Offset [web citation]
NIST DanWood With Exponential Growth And Offset 2D		y = ax^b y = y exp(x) + Offset [web citation]
NIST Eckerle4 With Exponential Growth And Offset 2D		y = (a/b) * exp(-0.5((x-c)/b)²) y = y exp(x) + Offset [web citation]
NIST Gauss With Exponential Growth And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y * (j * exp(x)) + Offset [web citation]
NIST Hahn With Exponential Growth And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * exp(x)) + Offset [web citation]
NIST Kirby With Exponential Growth And Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y * (g * exp(x)) + Offset [web citation]
NIST Lanczos With Exponential Growth And Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y * (h * exp(x)) + Offset [web citation]
NIST MGH09 With Exponential Growth And Offset 2D		y = a * (x² + bx) / (x² + cx + d) y = y * exp(x) + Offset [web citation]
NIST MGH10 With Exponential Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * exp(x) + Offset [web citation]
NIST Misra1a With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y exp(x) + Offset [web citation]
NIST Misra1b With Exponential Growth And Offset 2D		y = a * (1.0 - (1.0+bx/2.0)^-2.0) y = y exp(x) + Offset [web citation]
NIST Misra1c With Exponential Growth And Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y * exp(x) + Offset [web citation]
NIST Misra1d With Exponential Growth And Offset 2D		y = a * b * x * (1.0 + bx)^-1.0 y = y exp(x) + Offset [web citation]
NIST Rat42 With Exponential Growth And Offset 2D		y = a / (1.0 + exp(b - cx)) y = y exp(x) + Offset [web citation]
NIST Rat43 With Exponential Growth And Offset 2D		y = a / ((1.0 + exp(b - cx))^(1.0/d)) y = y exp(x) + Offset [web citation]
NIST Thurber With Exponential Growth And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * exp(x)) + Offset [web citation]



NIST Bennett5 With Exponential Growth 2D		y = a * (b+x)^-1/c y = y * exp(x) [web citation]
NIST BoxBOD With Exponential Growth 2D		y = a * (1.0-exp(-bx)) y = y exp(x) [web citation]
NIST Chwirut With Exponential Growth 2D		y = exp(-ax) / (b + cx) y = y * (d * exp(x)) [web citation]
NIST DanWood With Exponential Growth 2D		y = ax^b y = y exp(x) [web citation]
NIST ENSO With Exponential Growth 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) y = y * (k * exp(x)) [web citation]
NIST Eckerle4 With Exponential Growth 2D		y = (a/b) * exp(-0.5((x-c)/b)²) y = y exp(x) [web citation]
NIST Gauss With Exponential Growth 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y * (j * exp(x)) [web citation]
NIST Hahn With Exponential Growth 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * exp(x)) [web citation]
NIST Kirby With Exponential Growth 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y * (g * exp(x)) [web citation]
NIST Lanczos With Exponential Growth 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y * (h * exp(x)) [web citation]
NIST MGH09 With Exponential Growth 2D		y = a * (x² + bx) / (x² + cx + d) y = y * exp(x) [web citation]
NIST MGH10 With Exponential Growth 2D		y = a * exp(b/(x+c)) y = y * exp(x) [web citation]
NIST MGH17 With Exponential Growth 2D		y = a + bexp(-xd) + cexp(-xf) y = y * (g * exp(x)) [web citation]
NIST Misra1a With Exponential Growth 2D		y = a * (1.0 - exp(-bx)) y = y exp(x) [web citation]
NIST Misra1b With Exponential Growth 2D		y = a * (1.0 - (1.0+bx/2.0)^-2.0) y = y exp(x) [web citation]
NIST Misra1c With Exponential Growth 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y * exp(x) [web citation]
NIST Misra1d With Exponential Growth 2D		y = a * b * x * (1.0 + bx)^-1.0 y = y exp(x) [web citation]
NIST Rat42 With Exponential Growth 2D		y = a / (1.0 + exp(b - cx)) y = y exp(x) [web citation]
NIST Rat43 With Exponential Growth 2D		y = a / ((1.0 + exp(b - cx))^(1.0/d)) y = y exp(x) [web citation]
NIST Roszman With Exponential Growth 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y * (f * exp(x)) [web citation]
NIST Thurber With Exponential Growth 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * exp(x)) [web citation]



Inverse NIST Bennett5 2D		y = a * (b+x)^-1/c y = x / y [web citation]
Inverse NIST BoxBOD 2D		y = a * (1.0-exp(-b*x)) y = x / y [web citation]
Inverse NIST Chwirut 2D		y = exp(-ax) / (b + cx) y = x / y [web citation]
Inverse NIST DanWood 2D		y = a*x^b y = x / y [web citation]
Inverse NIST ENSO 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) y = x / y [web citation]
Inverse NIST Eckerle4 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = x / y [web citation]
Inverse NIST Gauss 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = x / y [web citation]
Inverse NIST Hahn 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = x / y [web citation]
Inverse NIST Kirby 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = x / y [web citation]
Inverse NIST Lanczos 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = x / y [web citation]
Inverse NIST MGH09 2D		y = a * (x² + bx) / (x² + cx + d) y = x / y [web citation]
Inverse NIST MGH10 2D		y = a * exp(b/(x+c)) y = x / y [web citation]
Inverse NIST MGH17 2D		y = a + bexp(-xd) + cexp(-xf) y = x / y [web citation]
Inverse NIST Misra1a 2D		y = a * (1.0 - exp(-b*x)) y = x / y [web citation]
Inverse NIST Misra1b 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = x / y [web citation]
Inverse NIST Misra1c 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = x / y [web citation]
Inverse NIST Misra1d 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = x / y [web citation]
Inverse NIST Rat42 2D		y = a / (1.0 + exp(b - c*x)) y = x / y [web citation]
Inverse NIST Rat43 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = x / y [web citation]
Inverse NIST Roszman 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = x / y [web citation]
Inverse NIST Thurber 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = x / y [web citation]



Inverse NIST Bennett5 With Offset 2D		y = a * (b+x)^-1/c y = x / y + Offset [web citation]
Inverse NIST BoxBOD With Offset 2D		y = a * (1.0-exp(-b*x)) y = x / y + Offset [web citation]
Inverse NIST Chwirut With Offset 2D		y = exp(-ax) / (b + cx) y = x / y + Offset [web citation]
Inverse NIST DanWood With Offset 2D		y = a*x^b y = x / y + Offset [web citation]
Inverse NIST Eckerle4 With Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = x / y + Offset [web citation]
Inverse NIST Gauss With Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = x / y + Offset [web citation]
Inverse NIST Hahn With Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = x / y + Offset [web citation]
Inverse NIST Kirby With Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = x / y + Offset [web citation]
Inverse NIST Lanczos With Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = x / y + Offset [web citation]
Inverse NIST MGH09 With Offset 2D		y = a * (x² + bx) / (x² + cx + d) y = x / y + Offset [web citation]
Inverse NIST MGH10 With Offset 2D		y = a * exp(b/(x+c)) y = x / y + Offset [web citation]
Inverse NIST Misra1a With Offset 2D		y = a * (1.0 - exp(-b*x)) y = x / y + Offset [web citation]
Inverse NIST Misra1b With Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = x / y + Offset [web citation]
Inverse NIST Misra1c With Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = x / y + Offset [web citation]
Inverse NIST Misra1d With Offset 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = x / y + Offset [web citation]
Inverse NIST Rat42 With Offset 2D		y = a / (1.0 + exp(b - c*x)) y = x / y + Offset [web citation]
Inverse NIST Rat43 With Offset 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = x / y + Offset [web citation]
Inverse NIST Thurber With Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = x / y + Offset [web citation]



NIST Bennett5 With Linear Decay And Offset 2D		y = a * (b+x)^-1/c y = y / x + Offset [web citation]
NIST BoxBOD With Linear Decay And Offset 2D		y = a * (1.0-exp(-b*x)) y = y / x + Offset [web citation]
NIST Chwirut With Linear Decay And Offset 2D		y = exp(-ax) / (b + cx) y = y / (d * x) + Offset [web citation]
NIST DanWood With Linear Decay And Offset 2D		y = a*x^b y = y / x + Offset [web citation]
NIST Eckerle4 With Linear Decay And Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = y / x + Offset [web citation]
NIST Gauss With Linear Decay And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y / (j * x) + Offset [web citation]
NIST Hahn With Linear Decay And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * x) + Offset [web citation]
NIST Kirby With Linear Decay And Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y / (g * x) + Offset [web citation]
NIST Lanczos With Linear Decay And Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y / (h * x) + Offset [web citation]
NIST MGH09 With Linear Decay And Offset 2D		y = a * (x² + bx) / (x² + cx + d) y = y / x + Offset [web citation]
NIST MGH10 With Linear Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / x + Offset [web citation]
NIST Misra1a With Linear Decay And Offset 2D		y = a * (1.0 - exp(-b*x)) y = y / x + Offset [web citation]
NIST Misra1b With Linear Decay And Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = y / x + Offset [web citation]
NIST Misra1c With Linear Decay And Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y / x + Offset [web citation]
NIST Misra1d With Linear Decay And Offset 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = y / x + Offset [web citation]
NIST Rat42 With Linear Decay And Offset 2D		y = a / (1.0 + exp(b - c*x)) y = y / x + Offset [web citation]
NIST Rat43 With Linear Decay And Offset 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = y / x + Offset [web citation]
NIST Thurber With Linear Decay And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * x) + Offset [web citation]



NIST Bennett5 With Linear Decay 2D		y = a * (b+x)^-1/c y = y / x [web citation]
NIST BoxBOD With Linear Decay 2D		y = a * (1.0-exp(-b*x)) y = y / x [web citation]
NIST Chwirut With Linear Decay 2D		y = exp(-ax) / (b + cx) y = y / (d * x) [web citation]
NIST DanWood With Linear Decay 2D		y = a*x^b y = y / x [web citation]
NIST ENSO With Linear Decay 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) y = y / (k * x) [web citation]
NIST Eckerle4 With Linear Decay 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = y / x [web citation]
NIST Gauss With Linear Decay 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y / (j * x) [web citation]
NIST Hahn With Linear Decay 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * x) [web citation]
NIST Kirby With Linear Decay 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y / (g * x) [web citation]
NIST Lanczos With Linear Decay 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y / (h * x) [web citation]
NIST MGH09 With Linear Decay 2D		y = a * (x² + bx) / (x² + cx + d) y = y / x [web citation]
NIST MGH10 With Linear Decay 2D		y = a * exp(b/(x+c)) y = y / x [web citation]
NIST MGH17 With Linear Decay 2D		y = a + bexp(-xd) + cexp(-xf) y = y / (g * x) [web citation]
NIST Misra1a With Linear Decay 2D		y = a * (1.0 - exp(-b*x)) y = y / x [web citation]
NIST Misra1b With Linear Decay 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = y / x [web citation]
NIST Misra1c With Linear Decay 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y / x [web citation]
NIST Misra1d With Linear Decay 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = y / x [web citation]
NIST Rat42 With Linear Decay 2D		y = a / (1.0 + exp(b - c*x)) y = y / x [web citation]
NIST Rat43 With Linear Decay 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = y / x [web citation]
NIST Roszman With Linear Decay 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y / (f * x) [web citation]
NIST Thurber With Linear Decay 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y / (i * x) [web citation]



NIST Bennett5 With Linear Growth And Offset 2D		y = a * (b+x)^-1/c y = y * x + Offset [web citation]
NIST BoxBOD With Linear Growth And Offset 2D		y = a * (1.0-exp(-bx)) y = y x + Offset [web citation]
NIST Chwirut With Linear Growth And Offset 2D		y = exp(-ax) / (b + cx) y = y * (d * x) + Offset [web citation]
NIST DanWood With Linear Growth And Offset 2D		y = ax^b y = y x + Offset [web citation]
NIST Eckerle4 With Linear Growth And Offset 2D		y = (a/b) * exp(-0.5((x-c)/b)²) y = y x + Offset [web citation]
NIST Gauss With Linear Growth And Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y * (j * x) + Offset [web citation]
NIST Hahn With Linear Growth And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * x) + Offset [web citation]
NIST Kirby With Linear Growth And Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y * (g * x) + Offset [web citation]
NIST Lanczos With Linear Growth And Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y * (h * x) + Offset [web citation]
NIST MGH09 With Linear Growth And Offset 2D		y = a * (x² + bx) / (x² + cx + d) y = y * x + Offset [web citation]
NIST MGH10 With Linear Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * x + Offset [web citation]
NIST Misra1a With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y x + Offset [web citation]
NIST Misra1b With Linear Growth And Offset 2D		y = a * (1.0 - (1.0+bx/2.0)^-2.0) y = y x + Offset [web citation]
NIST Misra1c With Linear Growth And Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y * x + Offset [web citation]
NIST Misra1d With Linear Growth And Offset 2D		y = a * b * x * (1.0 + bx)^-1.0 y = y x + Offset [web citation]
NIST Rat42 With Linear Growth And Offset 2D		y = a / (1.0 + exp(b - cx)) y = y x + Offset [web citation]
NIST Rat43 With Linear Growth And Offset 2D		y = a / ((1.0 + exp(b - cx))^(1.0/d)) y = y x + Offset [web citation]
NIST Thurber With Linear Growth And Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * x) + Offset [web citation]



NIST Bennett5 With Linear Growth 2D		y = a * (b+x)^-1/c y = y * x [web citation]
NIST BoxBOD With Linear Growth 2D		y = a * (1.0-exp(-bx)) y = y x [web citation]
NIST Chwirut With Linear Growth 2D		y = exp(-ax) / (b + cx) y = y * (d * x) [web citation]
NIST DanWood With Linear Growth 2D		y = ax^b y = y x [web citation]
NIST ENSO With Linear Growth 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) y = y * (k * x) [web citation]
NIST Eckerle4 With Linear Growth 2D		y = (a/b) * exp(-0.5((x-c)/b)²) y = y x [web citation]
NIST Gauss With Linear Growth 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = y * (j * x) [web citation]
NIST Hahn With Linear Growth 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * x) [web citation]
NIST Kirby With Linear Growth 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = y * (g * x) [web citation]
NIST Lanczos With Linear Growth 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = y * (h * x) [web citation]
NIST MGH09 With Linear Growth 2D		y = a * (x² + bx) / (x² + cx + d) y = y * x [web citation]
NIST MGH10 With Linear Growth 2D		y = a * exp(b/(x+c)) y = y * x [web citation]
NIST MGH17 With Linear Growth 2D		y = a + bexp(-xd) + cexp(-xf) y = y * (g * x) [web citation]
NIST Misra1a With Linear Growth 2D		y = a * (1.0 - exp(-bx)) y = y x [web citation]
NIST Misra1b With Linear Growth 2D		y = a * (1.0 - (1.0+bx/2.0)^-2.0) y = y x [web citation]
NIST Misra1c With Linear Growth 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y * x [web citation]
NIST Misra1d With Linear Growth 2D		y = a * b * x * (1.0 + bx)^-1.0 y = y x [web citation]
NIST Rat42 With Linear Growth 2D		y = a / (1.0 + exp(b - cx)) y = y x [web citation]
NIST Rat43 With Linear Growth 2D		y = a / ((1.0 + exp(b - cx))^(1.0/d)) y = y x [web citation]
NIST Roszman With Linear Growth 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y * (f * x) [web citation]
NIST Thurber With Linear Growth 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = y * (i * x) [web citation]



Reciprocal NIST Bennett5 2D		y = a * (b+x)^-1/c y = 1.0 / y [web citation]
Reciprocal NIST BoxBOD 2D		y = a * (1.0-exp(-b*x)) y = 1.0 / y [web citation]
Reciprocal NIST Chwirut 2D		y = exp(-ax) / (b + cx) y = 1.0 / y [web citation]
Reciprocal NIST DanWood 2D		y = a*x^b y = 1.0 / y [web citation]
Reciprocal NIST ENSO 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) y = 1.0 / y [web citation]
Reciprocal NIST Eckerle4 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = 1.0 / y [web citation]
Reciprocal NIST Gauss 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = 1.0 / y [web citation]
Reciprocal NIST Hahn 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = 1.0 / y [web citation]
Reciprocal NIST Kirby 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = 1.0 / y [web citation]
Reciprocal NIST Lanczos 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = 1.0 / y [web citation]
Reciprocal NIST MGH09 2D		y = a * (x² + bx) / (x² + cx + d) y = 1.0 / y [web citation]
Reciprocal NIST MGH10 2D		y = a * exp(b/(x+c)) y = 1.0 / y [web citation]
Reciprocal NIST MGH17 2D		y = a + bexp(-xd) + cexp(-xf) y = 1.0 / y [web citation]
Reciprocal NIST Misra1a 2D		y = a * (1.0 - exp(-b*x)) y = 1.0 / y [web citation]
Reciprocal NIST Misra1b 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = 1.0 / y [web citation]
Reciprocal NIST Misra1c 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = 1.0 / y [web citation]
Reciprocal NIST Misra1d 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = 1.0 / y [web citation]
Reciprocal NIST Rat42 2D		y = a / (1.0 + exp(b - c*x)) y = 1.0 / y [web citation]
Reciprocal NIST Rat43 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = 1.0 / y [web citation]
Reciprocal NIST Roszman 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = 1.0 / y [web citation]
Reciprocal NIST Thurber 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = 1.0 / y [web citation]



Reciprocal NIST Bennett5 With Offset 2D		y = a * (b+x)^-1/c y = 1.0 / y + Offset [web citation]
Reciprocal NIST BoxBOD With Offset 2D		y = a * (1.0-exp(-b*x)) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Chwirut With Offset 2D		y = exp(-ax) / (b + cx) y = 1.0 / y + Offset [web citation]
Reciprocal NIST DanWood With Offset 2D		y = a*x^b y = 1.0 / y + Offset [web citation]
Reciprocal NIST Eckerle4 With Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Gauss With Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Hahn With Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Kirby With Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Lanczos With Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) y = 1.0 / y + Offset [web citation]
Reciprocal NIST MGH09 With Offset 2D		y = a * (x² + bx) / (x² + cx + d) y = 1.0 / y + Offset [web citation]
Reciprocal NIST MGH10 With Offset 2D		y = a * exp(b/(x+c)) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Misra1a With Offset 2D		y = a * (1.0 - exp(-b*x)) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Misra1b With Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Misra1c With Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Misra1d With Offset 2D		y = a * b * x * (1.0 + b*x)^-1.0 y = 1.0 / y + Offset [web citation]
Reciprocal NIST Rat42 With Offset 2D		y = a / (1.0 + exp(b - c*x)) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Rat43 With Offset 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) y = 1.0 / y + Offset [web citation]
Reciprocal NIST Thurber With Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) y = 1.0 / y + Offset [web citation]



NIST Bennett5 2D		y = a * (b+x)^-1/c [web citation]
NIST BoxBOD 2D		y = a * (1.0-exp(-b*x)) [web citation]
NIST Chwirut 2D		y = exp(-ax) / (b + cx) [web citation]
NIST DanWood 2D		y = a*x^b [web citation]
NIST ENSO 2D		y = a + bcos(2pix/12) + csin(2pix/12) + fcos(2pix/d) + gsin(2pix/d) + icos(2pix/h) + jsin(2pix/h) [web citation]
NIST Eckerle4 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) [web citation]
NIST Gauss 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) [web citation]
NIST Hahn 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) [web citation]
NIST Kirby 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) [web citation]
NIST Lanczos 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) [web citation]
NIST MGH09 2D		y = a * (x² + bx) / (x² + cx + d) [web citation]
NIST MGH10 2D		y = a * exp(b/(x+c)) [web citation]
NIST MGH17 2D		y = a + bexp(-xd) + cexp(-xf) [web citation]
NIST Misra1a 2D		y = a * (1.0 - exp(-b*x)) [web citation]
NIST Misra1b 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) [web citation]
NIST Misra1c 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) [web citation]
NIST Misra1d 2D		y = a * b * x * (1.0 + b*x)^-1.0 [web citation]
NIST Rat42 2D		y = a / (1.0 + exp(b - c*x)) [web citation]
NIST Rat43 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) [web citation]
NIST Roszman 2D		y = a - bx - (arctan(c/(x-d)) / pi) [web citation]
NIST Thurber 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) [web citation]



NIST Bennett5 With Offset 2D		y = a * (b+x)^-1/c + Offset [web citation]
NIST BoxBOD With Offset 2D		y = a * (1.0-exp(-b*x)) + Offset [web citation]
NIST Chwirut With Offset 2D		y = exp(-ax) / (b + cx) + Offset [web citation]
NIST DanWood With Offset 2D		y = a*x^b + Offset [web citation]
NIST Eckerle4 With Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)²) + Offset [web citation]
NIST Gauss With Offset 2D		y = aexp(-bx) + cexp(-(x-d)² / f²) + gexp(-(x-h)² / i²) + Offset [web citation]
NIST Hahn With Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) + Offset [web citation]
NIST Kirby With Offset 2D		y = (a + bx + cx²) / (1.0 + dx + fx²) + Offset [web citation]
NIST Lanczos With Offset 2D		y = aexp(-bx) + cexp(-dx) + fexp(-gx) + Offset [web citation]
NIST MGH09 With Offset 2D		y = a * (x² + bx) / (x² + cx + d) + Offset [web citation]
NIST MGH10 With Offset 2D		y = a * exp(b/(x+c)) + Offset [web citation]
NIST Misra1a With Offset 2D		y = a * (1.0 - exp(-b*x)) + Offset [web citation]
NIST Misra1b With Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)^-2.0) + Offset [web citation]
NIST Misra1c With Offset 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) + Offset [web citation]
NIST Misra1d With Offset 2D		y = a * b * x * (1.0 + b*x)^-1.0 + Offset [web citation]
NIST Rat42 With Offset 2D		y = a / (1.0 + exp(b - c*x)) + Offset [web citation]
NIST Rat43 With Offset 2D		y = a / ((1.0 + exp(b - c*x))^(1.0/d)) + Offset [web citation]
NIST Thurber With Offset 2D		y = (a + bx + cx² + dx³) / (1.0 + fx + gx² + hx³) + Offset [web citation]



NIST BoxBOD Plus Line 2D		y = a * (1.0-exp(-bx)) y = y + (c x) + d [web citation]
NIST DanWood Plus Line 2D		y = ax^b y = y + (c x) + d [web citation]
NIST Misra1a Plus Line 2D		y = a * (1.0 - exp(-bx)) y = y + (c x) + d [web citation]
NIST Misra1b Plus Line 2D		y = a * (1.0 - (1.0+bx/2.0)^-2.0) y = y + (c x) + d [web citation]
NIST Misra1c Plus Line 2D		y = a * (1.0 - (1.0 + 2.0bx)^-0.5) y = y + (c * x) + d [web citation]
NIST Misra1d Plus Line 2D		y = a * b * x * (1.0 + bx)^-1.0 y = y + (c x) + d [web citation]

2D Optical

HARTMANN3b With Exponential Decay And Offset 2D		n = A/(x - B)^1.2 n = n / exp(x) + Offset [web citation]
SELLMOD3 With Exponential Decay And Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² / (g * exp(x)) + Offset [web citation]



CAUCHY With Exponential Decay 2D		n = A + B/x² + C/x⁴ n = n / (d * exp(x)) [web citation]
CONRADY1 With Exponential Decay 2D		n = A + B/x + C/x^3.5 n = n / (d * exp(x)) [web citation]
CONRADY2 With Exponential Decay 2D		n = A + B/x² + C/x^3.5 n = n / (d * exp(x)) [web citation]
HARTMANN1 With Exponential Decay 2D		n = A + B/(C - x) n = n / (d * exp(x)) [web citation]
HARTMANN2 With Exponential Decay 2D		n = A + B/(C - x)² n = n / (d * exp(x)) [web citation]
HARTMANN3a With Exponential Decay 2D		n = A + B/(C - x)^1.2 n = n / (d * exp(x)) [web citation]
HARTMANN3b With Exponential Decay 2D		n = A/(x - B)^1.2 n = n / exp(x) [web citation]
HARTMANN4 With Exponential Decay 2D		n = A + B/(C - x) + D/(E - x) n = n / (g * exp(x)) [web citation]
HERZBRGR2X2 With Exponential Decay 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² n = n / (f * exp(x)) [web citation]
HERZBRGR3X2 With Exponential Decay 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² n = n / (g * exp(x)) [web citation]
HERZBRGR3X3 With Exponential Decay 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ n = n / (h * exp(x)) [web citation]
HERZBRGR4X2 With Exponential Decay 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² n = n / (h * exp(x)) [web citation]
HERZBRGR5X2 With Exponential Decay 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² n = n / (i * exp(x)) [web citation]
HERZBRGRJK With Exponential Decay 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² n = n / (j * exp(x)) [web citation]
HoO1 With Exponential Decay 2D		n² = A + Bx² + C / (x² - D²) n² = n² / (f * exp(x)) [web citation]
HoO2 With Exponential Decay 2D		n² = A + Bx² + Cx² / (x² - D²) n² = n² / (f * exp(x)) [web citation]
KINGSLAKE1 With Exponential Decay 2D		n² = A + B/(x²-C²) + D/(x²-E²) n² = n² / (g * exp(x)) [web citation]
KINGSLAKE2 With Exponential Decay 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) n² = n² / (i * exp(x)) [web citation]
MISC01 With Exponential Decay 2D		n² = A + B/(x²-C²) n² = n² / (d * exp(x)) [web citation]
MISC02 With Exponential Decay 2D		n² = A + Bx² + C/(x²-D²) n² = n² / (f * exp(x)) [web citation]
MISC03 With Exponential Decay 2D		n² = A + B/x² + Cx²/(x²-D²) n² = n² / (f * exp(x)) [web citation]
MISC04 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) n² = n² / (i * exp(x)) [web citation]
SCHOTT2X3 With Exponential Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ n² = n² / (g * exp(x)) [web citation]
SCHOTT2X4 With Exponential Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ n² = n² / (h * exp(x)) [web citation]
SCHOTT2X5 With Exponential Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ n² = n² / (i * exp(x)) [web citation]
SCHOTT2X6 With Exponential Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² n² = n² / (j * exp(x)) [web citation]
SCHOTT3X3 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ n² = n² / (h * exp(x)) [web citation]
SCHOTT3X4 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ n² = n² / (i * exp(x)) [web citation]
SCHOTT3X5 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ n² = n² / (j * exp(x)) [web citation]
SCHOTT4X4 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ n² = n² / (j * exp(x)) [web citation]
SCHOTT5X5 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ n² = n² / (m * exp(x)) [web citation]
SELL1T With Exponential Decay 2D		n² = 1 + Ax² / (x² - B²) n² = n² / (c * exp(x)) [web citation]
SELL1TA With Exponential Decay 2D		n² = A + Bx² / (x² - C²) n² = n² / (d * exp(x)) [web citation]
SELL2T With Exponential Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) n² = n² / (f * exp(x)) [web citation]
SELL2TA With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELL3T With Exponential Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² / (h * exp(x)) [web citation]
SELL3TA With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² / (i * exp(x)) [web citation]
SELL4T With Exponential Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) n² = n² / (j * exp(x)) [web citation]
SELL4TA With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) n² = n² / (k * exp(x)) [web citation]
SELL5T With Exponential Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) n² = n² / (m * exp(x)) [web citation]
SELL5TA With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) n² = n² / (n * exp(x)) [web citation]
SELL6TA With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) n² = n² / (q * exp(x)) [web citation]
SELL7TA With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) n² = n² / (s * exp(x)) [web citation]
SELLMOD1 With Exponential Decay 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELLMOD1A With Exponential Decay 2D		n² = A + Bx + Cx² + D/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELLMOD2 With Exponential Decay 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELLMOD2A With Exponential Decay 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELLMOD3 With Exponential Decay 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELLMOD4 With Exponential Decay 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² / (i * exp(x)) [web citation]
SELLMOD4A With Exponential Decay 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) n² = n² / (i * exp(x)) [web citation]
SELLMOD5 With Exponential Decay 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² / (h * exp(x)) [web citation]
SELLMOD6 With Exponential Decay 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) n² = n² / (g * exp(x)) [web citation]
SELLMOD7 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² / (h * exp(x)) [web citation]
SELLMOD7A With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) n² = n² / (h * exp(x)) [web citation]
SELLMOD8 With Exponential Decay 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) n² = n² / (i * exp(x)) [web citation]
SELLMOD9 With Exponential Decay 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² / (h * exp(x)) [web citation]



HARTMANN3b With Exponential Growth And Offset 2D		n = A/(x - B)^1.2 n = n * exp(x) + Offset [web citation]
SELLMOD3 With Exponential Growth And Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² * (g * exp(x)) + Offset [web citation]



CAUCHY With Exponential Growth 2D		n = A + B/x² + C/x⁴ n = n * (d * exp(x)) [web citation]
CONRADY1 With Exponential Growth 2D		n = A + B/x + C/x^3.5 n = n * (d * exp(x)) [web citation]
CONRADY2 With Exponential Growth 2D		n = A + B/x² + C/x^3.5 n = n * (d * exp(x)) [web citation]
HARTMANN1 With Exponential Growth 2D		n = A + B/(C - x) n = n * (d * exp(x)) [web citation]
HARTMANN2 With Exponential Growth 2D		n = A + B/(C - x)² n = n * (d * exp(x)) [web citation]
HARTMANN3a With Exponential Growth 2D		n = A + B/(C - x)^1.2 n = n * (d * exp(x)) [web citation]
HARTMANN3b With Exponential Growth 2D		n = A/(x - B)^1.2 n = n * exp(x) [web citation]
HARTMANN4 With Exponential Growth 2D		n = A + B/(C - x) + D/(E - x) n = n * (g * exp(x)) [web citation]
HERZBRGR2X2 With Exponential Growth 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² n = n * (f * exp(x)) [web citation]
HERZBRGR3X2 With Exponential Growth 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² n = n * (g * exp(x)) [web citation]
HERZBRGR3X3 With Exponential Growth 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ n = n * (h * exp(x)) [web citation]
HERZBRGR4X2 With Exponential Growth 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² n = n * (h * exp(x)) [web citation]
HERZBRGR5X2 With Exponential Growth 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² n = n * (i * exp(x)) [web citation]
HERZBRGRJK With Exponential Growth 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² n = n * (j * exp(x)) [web citation]
HoO1 With Exponential Growth 2D		n² = A + Bx² + C / (x² - D²) n² = n² * (f * exp(x)) [web citation]
HoO2 With Exponential Growth 2D		n² = A + Bx² + Cx² / (x² - D²) n² = n² * (f * exp(x)) [web citation]
KINGSLAKE1 With Exponential Growth 2D		n² = A + B/(x²-C²) + D/(x²-E²) n² = n² * (g * exp(x)) [web citation]
KINGSLAKE2 With Exponential Growth 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) n² = n² * (i * exp(x)) [web citation]
MISC01 With Exponential Growth 2D		n² = A + B/(x²-C²) n² = n² * (d * exp(x)) [web citation]
MISC02 With Exponential Growth 2D		n² = A + Bx² + C/(x²-D²) n² = n² * (f * exp(x)) [web citation]
MISC03 With Exponential Growth 2D		n² = A + B/x² + Cx²/(x²-D²) n² = n² * (f * exp(x)) [web citation]
MISC04 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) n² = n² * (i * exp(x)) [web citation]
SCHOTT2X3 With Exponential Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ n² = n² * (g * exp(x)) [web citation]
SCHOTT2X4 With Exponential Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ n² = n² * (h * exp(x)) [web citation]
SCHOTT2X5 With Exponential Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ n² = n² * (i * exp(x)) [web citation]
SCHOTT2X6 With Exponential Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² n² = n² * (j * exp(x)) [web citation]
SCHOTT3X3 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ n² = n² * (h * exp(x)) [web citation]
SCHOTT3X4 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ n² = n² * (i * exp(x)) [web citation]
SCHOTT3X5 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ n² = n² * (j * exp(x)) [web citation]
SCHOTT4X4 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ n² = n² * (j * exp(x)) [web citation]
SCHOTT5X5 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ n² = n² * (m * exp(x)) [web citation]
SELL1T With Exponential Growth 2D		n² = 1 + Ax² / (x² - B²) n² = n² * (c * exp(x)) [web citation]
SELL1TA With Exponential Growth 2D		n² = A + Bx² / (x² - C²) n² = n² * (d * exp(x)) [web citation]
SELL2T With Exponential Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) n² = n² * (f * exp(x)) [web citation]
SELL2TA With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELL3T With Exponential Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² * (h * exp(x)) [web citation]
SELL3TA With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² * (i * exp(x)) [web citation]
SELL4T With Exponential Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) n² = n² * (j * exp(x)) [web citation]
SELL4TA With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) n² = n² * (k * exp(x)) [web citation]
SELL5T With Exponential Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) n² = n² * (m * exp(x)) [web citation]
SELL5TA With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) n² = n² * (n * exp(x)) [web citation]
SELL6TA With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) n² = n² * (q * exp(x)) [web citation]
SELL7TA With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) n² = n² * (s * exp(x)) [web citation]
SELLMOD1 With Exponential Growth 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELLMOD1A With Exponential Growth 2D		n² = A + Bx + Cx² + D/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELLMOD2 With Exponential Growth 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELLMOD2A With Exponential Growth 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELLMOD3 With Exponential Growth 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELLMOD4 With Exponential Growth 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² * (i * exp(x)) [web citation]
SELLMOD4A With Exponential Growth 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) n² = n² * (i * exp(x)) [web citation]
SELLMOD5 With Exponential Growth 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² * (h * exp(x)) [web citation]
SELLMOD6 With Exponential Growth 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) n² = n² * (g * exp(x)) [web citation]
SELLMOD7 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² * (h * exp(x)) [web citation]
SELLMOD7A With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) n² = n² * (h * exp(x)) [web citation]
SELLMOD8 With Exponential Growth 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) n² = n² * (i * exp(x)) [web citation]
SELLMOD9 With Exponential Growth 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² * (h * exp(x)) [web citation]



Inverse CAUCHY 2D		n = A + B/x² + C/x⁴ n = x / n [web citation]
Inverse CONRADY1 2D		n = A + B/x + C/x^3.5 n = x / n [web citation]
Inverse CONRADY2 2D		n = A + B/x² + C/x^3.5 n = x / n [web citation]
Inverse HARTMANN1 2D		n = A + B/(C - x) n = x / n [web citation]
Inverse HARTMANN2 2D		n = A + B/(C - x)² n = x / n [web citation]
Inverse HARTMANN3a 2D		n = A + B/(C - x)^1.2 n = x / n [web citation]
Inverse HARTMANN3b 2D		n = A/(x - B)^1.2 n = x / n [web citation]
Inverse HARTMANN4 2D		n = A + B/(C - x) + D/(E - x) n = x / n [web citation]
Inverse HERZBRGR2X2 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² n = x / n [web citation]
Inverse HERZBRGR3X2 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² n = x / n [web citation]
Inverse HERZBRGR3X3 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ n = x / n [web citation]
Inverse HERZBRGR4X2 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² n = x / n [web citation]
Inverse HERZBRGR5X2 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² n = x / n [web citation]
Inverse HERZBRGRJK 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² n = x / n [web citation]
Inverse HoO1 2D		n² = A + Bx² + C / (x² - D²) n² = x / n² [web citation]
Inverse HoO2 2D		n² = A + Bx² + Cx² / (x² - D²) n² = x / n² [web citation]
Inverse KINGSLAKE1 2D		n² = A + B/(x²-C²) + D/(x²-E²) n² = x / n² [web citation]
Inverse KINGSLAKE2 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) n² = x / n² [web citation]
Inverse MISC01 2D		n² = A + B/(x²-C²) n² = x / n² [web citation]
Inverse MISC02 2D		n² = A + Bx² + C/(x²-D²) n² = x / n² [web citation]
Inverse MISC03 2D		n² = A + B/x² + Cx²/(x²-D²) n² = x / n² [web citation]
Inverse MISC04 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) n² = x / n² [web citation]
Inverse SCHOTT2X3 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ n² = x / n² [web citation]
Inverse SCHOTT2X4 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ n² = x / n² [web citation]
Inverse SCHOTT2X5 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ n² = x / n² [web citation]
Inverse SCHOTT2X6 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² n² = x / n² [web citation]
Inverse SCHOTT3X3 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ n² = x / n² [web citation]
Inverse SCHOTT3X4 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ n² = x / n² [web citation]
Inverse SCHOTT3X5 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ n² = x / n² [web citation]
Inverse SCHOTT4X4 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ n² = x / n² [web citation]
Inverse SCHOTT5X5 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ n² = x / n² [web citation]
Inverse SELL1T 2D		n² = 1 + Ax² / (x² - B²) n² = x / n² [web citation]
Inverse SELL1TA 2D		n² = A + Bx² / (x² - C²) n² = x / n² [web citation]
Inverse SELL2T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) n² = x / n² [web citation]
Inverse SELL2TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) n² = x / n² [web citation]
Inverse SELL3T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) n² = x / n² [web citation]
Inverse SELL3TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) n² = x / n² [web citation]
Inverse SELL4T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) n² = x / n² [web citation]
Inverse SELL4TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) n² = x / n² [web citation]
Inverse SELL5T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) n² = x / n² [web citation]
Inverse SELL5TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) n² = x / n² [web citation]
Inverse SELL6TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) n² = x / n² [web citation]
Inverse SELL7TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) n² = x / n² [web citation]
Inverse SELLMOD1 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) n² = x / n² [web citation]
Inverse SELLMOD1A 2D		n² = A + Bx + Cx² + D/(x²-E²) n² = x / n² [web citation]
Inverse SELLMOD2 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) n² = x / n² [web citation]
Inverse SELLMOD2A 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) n² = x / n² [web citation]
Inverse SELLMOD3 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = x / n² [web citation]
Inverse SELLMOD4 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) n² = x / n² [web citation]
Inverse SELLMOD4A 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) n² = x / n² [web citation]
Inverse SELLMOD5 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) n² = x / n² [web citation]
Inverse SELLMOD6 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) n² = x / n² [web citation]
Inverse SELLMOD7 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) n² = x / n² [web citation]
Inverse SELLMOD7A 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) n² = x / n² [web citation]
Inverse SELLMOD8 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) n² = x / n² [web citation]
Inverse SELLMOD9 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) n² = x / n² [web citation]



Inverse HARTMANN3b With Offset 2D		n = A/(x - B)^1.2 n = x / n + Offset [web citation]
Inverse SELLMOD3 With Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = x / n² + Offset [web citation]



HARTMANN3b With Linear Decay And Offset 2D		n = A/(x - B)^1.2 n = n / x + Offset [web citation]
SELLMOD3 With Linear Decay And Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² / (g * x) + Offset [web citation]



CAUCHY With Linear Decay 2D		n = A + B/x² + C/x⁴ n = n / (d * x) [web citation]
CONRADY1 With Linear Decay 2D		n = A + B/x + C/x^3.5 n = n / (d * x) [web citation]
CONRADY2 With Linear Decay 2D		n = A + B/x² + C/x^3.5 n = n / (d * x) [web citation]
HARTMANN1 With Linear Decay 2D		n = A + B/(C - x) n = n / (d * x) [web citation]
HARTMANN2 With Linear Decay 2D		n = A + B/(C - x)² n = n / (d * x) [web citation]
HARTMANN3a With Linear Decay 2D		n = A + B/(C - x)^1.2 n = n / (d * x) [web citation]
HARTMANN3b With Linear Decay 2D		n = A/(x - B)^1.2 n = n / x [web citation]
HARTMANN4 With Linear Decay 2D		n = A + B/(C - x) + D/(E - x) n = n / (g * x) [web citation]
HERZBRGR2X2 With Linear Decay 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² n = n / (f * x) [web citation]
HERZBRGR3X2 With Linear Decay 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² n = n / (g * x) [web citation]
HERZBRGR3X3 With Linear Decay 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ n = n / (h * x) [web citation]
HERZBRGR4X2 With Linear Decay 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² n = n / (h * x) [web citation]
HERZBRGR5X2 With Linear Decay 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² n = n / (i * x) [web citation]
HERZBRGRJK With Linear Decay 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² n = n / (j * x) [web citation]
HoO1 With Linear Decay 2D		n² = A + Bx² + C / (x² - D²) n² = n² / (f * x) [web citation]
HoO2 With Linear Decay 2D		n² = A + Bx² + Cx² / (x² - D²) n² = n² / (f * x) [web citation]
KINGSLAKE1 With Linear Decay 2D		n² = A + B/(x²-C²) + D/(x²-E²) n² = n² / (g * x) [web citation]
KINGSLAKE2 With Linear Decay 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) n² = n² / (i * x) [web citation]
MISC01 With Linear Decay 2D		n² = A + B/(x²-C²) n² = n² / (d * x) [web citation]
MISC02 With Linear Decay 2D		n² = A + Bx² + C/(x²-D²) n² = n² / (f * x) [web citation]
MISC03 With Linear Decay 2D		n² = A + B/x² + Cx²/(x²-D²) n² = n² / (f * x) [web citation]
MISC04 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) n² = n² / (i * x) [web citation]
SCHOTT2X3 With Linear Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ n² = n² / (g * x) [web citation]
SCHOTT2X4 With Linear Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ n² = n² / (h * x) [web citation]
SCHOTT2X5 With Linear Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ n² = n² / (i * x) [web citation]
SCHOTT2X6 With Linear Decay 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² n² = n² / (j * x) [web citation]
SCHOTT3X3 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ n² = n² / (h * x) [web citation]
SCHOTT3X4 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ n² = n² / (i * x) [web citation]
SCHOTT3X5 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ n² = n² / (j * x) [web citation]
SCHOTT4X4 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ n² = n² / (j * x) [web citation]
SCHOTT5X5 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ n² = n² / (m * x) [web citation]
SELL1T With Linear Decay 2D		n² = 1 + Ax² / (x² - B²) n² = n² / (c * x) [web citation]
SELL1TA With Linear Decay 2D		n² = A + Bx² / (x² - C²) n² = n² / (d * x) [web citation]
SELL2T With Linear Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) n² = n² / (f * x) [web citation]
SELL2TA With Linear Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) n² = n² / (g * x) [web citation]
SELL3T With Linear Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² / (h * x) [web citation]
SELL3TA With Linear Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² / (i * x) [web citation]
SELL4T With Linear Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) n² = n² / (j * x) [web citation]
SELL4TA With Linear Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) n² = n² / (k * x) [web citation]
SELL5T With Linear Decay 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) n² = n² / (m * x) [web citation]
SELL5TA With Linear Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) n² = n² / (n * x) [web citation]
SELL6TA With Linear Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) n² = n² / (q * x) [web citation]
SELL7TA With Linear Decay 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) n² = n² / (s * x) [web citation]
SELLMOD1 With Linear Decay 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) n² = n² / (g * x) [web citation]
SELLMOD1A With Linear Decay 2D		n² = A + Bx + Cx² + D/(x²-E²) n² = n² / (g * x) [web citation]
SELLMOD2 With Linear Decay 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) n² = n² / (g * x) [web citation]
SELLMOD2A With Linear Decay 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) n² = n² / (g * x) [web citation]
SELLMOD3 With Linear Decay 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² / (g * x) [web citation]
SELLMOD4 With Linear Decay 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² / (i * x) [web citation]
SELLMOD4A With Linear Decay 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) n² = n² / (i * x) [web citation]
SELLMOD5 With Linear Decay 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² / (h * x) [web citation]
SELLMOD6 With Linear Decay 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) n² = n² / (g * x) [web citation]
SELLMOD7 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² / (h * x) [web citation]
SELLMOD7A With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) n² = n² / (h * x) [web citation]
SELLMOD8 With Linear Decay 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) n² = n² / (i * x) [web citation]
SELLMOD9 With Linear Decay 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² / (h * x) [web citation]



HARTMANN3b With Linear Growth And Offset 2D		n = A/(x - B)^1.2 n = n * x + Offset [web citation]
SELLMOD3 With Linear Growth And Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² * (g * x) + Offset [web citation]



CAUCHY With Linear Growth 2D		n = A + B/x² + C/x⁴ n = n * (d * x) [web citation]
CONRADY1 With Linear Growth 2D		n = A + B/x + C/x^3.5 n = n * (d * x) [web citation]
CONRADY2 With Linear Growth 2D		n = A + B/x² + C/x^3.5 n = n * (d * x) [web citation]
HARTMANN1 With Linear Growth 2D		n = A + B/(C - x) n = n * (d * x) [web citation]
HARTMANN2 With Linear Growth 2D		n = A + B/(C - x)² n = n * (d * x) [web citation]
HARTMANN3a With Linear Growth 2D		n = A + B/(C - x)^1.2 n = n * (d * x) [web citation]
HARTMANN3b With Linear Growth 2D		n = A/(x - B)^1.2 n = n * x [web citation]
HARTMANN4 With Linear Growth 2D		n = A + B/(C - x) + D/(E - x) n = n * (g * x) [web citation]
HERZBRGR2X2 With Linear Growth 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² n = n * (f * x) [web citation]
HERZBRGR3X2 With Linear Growth 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² n = n * (g * x) [web citation]
HERZBRGR3X3 With Linear Growth 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ n = n * (h * x) [web citation]
HERZBRGR4X2 With Linear Growth 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² n = n * (h * x) [web citation]
HERZBRGR5X2 With Linear Growth 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² n = n * (i * x) [web citation]
HERZBRGRJK With Linear Growth 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² n = n * (j * x) [web citation]
HoO1 With Linear Growth 2D		n² = A + Bx² + C / (x² - D²) n² = n² * (f * x) [web citation]
HoO2 With Linear Growth 2D		n² = A + Bx² + Cx² / (x² - D²) n² = n² * (f * x) [web citation]
KINGSLAKE1 With Linear Growth 2D		n² = A + B/(x²-C²) + D/(x²-E²) n² = n² * (g * x) [web citation]
KINGSLAKE2 With Linear Growth 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) n² = n² * (i * x) [web citation]
MISC01 With Linear Growth 2D		n² = A + B/(x²-C²) n² = n² * (d * x) [web citation]
MISC02 With Linear Growth 2D		n² = A + Bx² + C/(x²-D²) n² = n² * (f * x) [web citation]
MISC03 With Linear Growth 2D		n² = A + B/x² + Cx²/(x²-D²) n² = n² * (f * x) [web citation]
MISC04 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) n² = n² * (i * x) [web citation]
SCHOTT2X3 With Linear Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ n² = n² * (g * x) [web citation]
SCHOTT2X4 With Linear Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ n² = n² * (h * x) [web citation]
SCHOTT2X5 With Linear Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ n² = n² * (i * x) [web citation]
SCHOTT2X6 With Linear Growth 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² n² = n² * (j * x) [web citation]
SCHOTT3X3 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ n² = n² * (h * x) [web citation]
SCHOTT3X4 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ n² = n² * (i * x) [web citation]
SCHOTT3X5 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ n² = n² * (j * x) [web citation]
SCHOTT4X4 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ n² = n² * (j * x) [web citation]
SCHOTT5X5 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ n² = n² * (m * x) [web citation]
SELL1T With Linear Growth 2D		n² = 1 + Ax² / (x² - B²) n² = n² * (c * x) [web citation]
SELL1TA With Linear Growth 2D		n² = A + Bx² / (x² - C²) n² = n² * (d * x) [web citation]
SELL2T With Linear Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) n² = n² * (f * x) [web citation]
SELL2TA With Linear Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) n² = n² * (g * x) [web citation]
SELL3T With Linear Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² * (h * x) [web citation]
SELL3TA With Linear Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² * (i * x) [web citation]
SELL4T With Linear Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) n² = n² * (j * x) [web citation]
SELL4TA With Linear Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) n² = n² * (k * x) [web citation]
SELL5T With Linear Growth 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) n² = n² * (m * x) [web citation]
SELL5TA With Linear Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) n² = n² * (n * x) [web citation]
SELL6TA With Linear Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) n² = n² * (q * x) [web citation]
SELL7TA With Linear Growth 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) n² = n² * (s * x) [web citation]
SELLMOD1 With Linear Growth 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) n² = n² * (g * x) [web citation]
SELLMOD1A With Linear Growth 2D		n² = A + Bx + Cx² + D/(x²-E²) n² = n² * (g * x) [web citation]
SELLMOD2 With Linear Growth 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) n² = n² * (g * x) [web citation]
SELLMOD2A With Linear Growth 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) n² = n² * (g * x) [web citation]
SELLMOD3 With Linear Growth 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = n² * (g * x) [web citation]
SELLMOD4 With Linear Growth 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) n² = n² * (i * x) [web citation]
SELLMOD4A With Linear Growth 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) n² = n² * (i * x) [web citation]
SELLMOD5 With Linear Growth 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) n² = n² * (h * x) [web citation]
SELLMOD6 With Linear Growth 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) n² = n² * (g * x) [web citation]
SELLMOD7 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² * (h * x) [web citation]
SELLMOD7A With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) n² = n² * (h * x) [web citation]
SELLMOD8 With Linear Growth 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) n² = n² * (i * x) [web citation]
SELLMOD9 With Linear Growth 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) n² = n² * (h * x) [web citation]



Reciprocal CAUCHY 2D		n = A + B/x² + C/x⁴ n = 1.0 / n [web citation]
Reciprocal CONRADY1 2D		n = A + B/x + C/x^3.5 n = 1.0 / n [web citation]
Reciprocal CONRADY2 2D		n = A + B/x² + C/x^3.5 n = 1.0 / n [web citation]
Reciprocal HARTMANN1 2D		n = A + B/(C - x) n = 1.0 / n [web citation]
Reciprocal HARTMANN2 2D		n = A + B/(C - x)² n = 1.0 / n [web citation]
Reciprocal HARTMANN3a 2D		n = A + B/(C - x)^1.2 n = 1.0 / n [web citation]
Reciprocal HARTMANN3b 2D		n = A/(x - B)^1.2 n = 1.0 / n [web citation]
Reciprocal HARTMANN4 2D		n = A + B/(C - x) + D/(E - x) n = 1.0 / n [web citation]
Reciprocal HERZBRGR2X2 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² n = 1.0 / n [web citation]
Reciprocal HERZBRGR3X2 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² n = 1.0 / n [web citation]
Reciprocal HERZBRGR3X3 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ n = 1.0 / n [web citation]
Reciprocal HERZBRGR4X2 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² n = 1.0 / n [web citation]
Reciprocal HERZBRGR5X2 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² n = 1.0 / n [web citation]
Reciprocal HERZBRGRJK 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² n = 1.0 / n [web citation]
Reciprocal HoO1 2D		n² = A + Bx² + C / (x² - D²) n² = 1.0 / n² [web citation]
Reciprocal HoO2 2D		n² = A + Bx² + Cx² / (x² - D²) n² = 1.0 / n² [web citation]
Reciprocal KINGSLAKE1 2D		n² = A + B/(x²-C²) + D/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal KINGSLAKE2 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) n² = 1.0 / n² [web citation]
Reciprocal MISC01 2D		n² = A + B/(x²-C²) n² = 1.0 / n² [web citation]
Reciprocal MISC02 2D		n² = A + Bx² + C/(x²-D²) n² = 1.0 / n² [web citation]
Reciprocal MISC03 2D		n² = A + B/x² + Cx²/(x²-D²) n² = 1.0 / n² [web citation]
Reciprocal MISC04 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) n² = 1.0 / n² [web citation]
Reciprocal SCHOTT2X3 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT2X4 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT2X5 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT2X6 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² n² = 1.0 / n² [web citation]
Reciprocal SCHOTT3X3 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT3X4 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT3X5 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT4X4 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ n² = 1.0 / n² [web citation]
Reciprocal SCHOTT5X5 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ n² = 1.0 / n² [web citation]
Reciprocal SELL1T 2D		n² = 1 + Ax² / (x² - B²) n² = 1.0 / n² [web citation]
Reciprocal SELL1TA 2D		n² = A + Bx² / (x² - C²) n² = 1.0 / n² [web citation]
Reciprocal SELL2T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) n² = 1.0 / n² [web citation]
Reciprocal SELL2TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELL3T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) n² = 1.0 / n² [web citation]
Reciprocal SELL3TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) n² = 1.0 / n² [web citation]
Reciprocal SELL4T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) n² = 1.0 / n² [web citation]
Reciprocal SELL4TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) n² = 1.0 / n² [web citation]
Reciprocal SELL5T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) n² = 1.0 / n² [web citation]
Reciprocal SELL5TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) n² = 1.0 / n² [web citation]
Reciprocal SELL6TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) n² = 1.0 / n² [web citation]
Reciprocal SELL7TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD1 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD1A 2D		n² = A + Bx + Cx² + D/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD2 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD2A 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD3 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD4 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD4A 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD5 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD6 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD7 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD7A 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD8 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) n² = 1.0 / n² [web citation]
Reciprocal SELLMOD9 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) n² = 1.0 / n² [web citation]



Reciprocal HARTMANN3b With Offset 2D		n = A/(x - B)^1.2 n = 1.0 / n + Offset [web citation]
Reciprocal SELLMOD3 With Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) n² = 1.0 / n² + Offset [web citation]



CAUCHY 2D		n = A + B/x² + C/x⁴ [web citation]
CONRADY1 2D		n = A + B/x + C/x^3.5 [web citation]
CONRADY2 2D		n = A + B/x² + C/x^3.5 [web citation]
HARTMANN1 2D		n = A + B/(C - x) [web citation]
HARTMANN2 2D		n = A + B/(C - x)² [web citation]
HARTMANN3a 2D		n = A + B/(C - x)^1.2 [web citation]
HARTMANN3b 2D		n = A/(x - B)^1.2 [web citation]
HARTMANN4 2D		n = A + B/(C - x) + D/(E - x) [web citation]
HERZBRGR2X2 2D		n = A + Bx² + C / (x² - 0.028) + D / (x² - 0.028)² [web citation]
HERZBRGR3X2 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² [web citation]
HERZBRGR3X3 2D		n = A + Bx² + Cx⁴ + D / (x² - 0.028) + E / (x² - 0.028)² + F / (x² - 0.028)⁴ [web citation]
HERZBRGR4X2 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - 0.028) + F / (x² - 0.028)² [web citation]
HERZBRGR5X2 2D		n = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F / (x² - 0.028) + G / (x² - 0.028)² [web citation]
HERZBRGRJK 2D		n = A + Bx² + Cx⁴ + Dx⁶ + E / (x² - J) + F / (x² - K)² [web citation]
HoO1 2D		n² = A + Bx² + C / (x² - D²) [web citation]
HoO2 2D		n² = A + Bx² + Cx² / (x² - D²) [web citation]
KINGSLAKE1 2D		n² = A + B/(x²-C²) + D/(x²-E²) [web citation]
KINGSLAKE2 2D		n² = A + B/(x²-C²) + D/(x²-E²) + F/(x²-G²) [web citation]
MISC01 2D		n² = A + B/(x²-C²) [web citation]
MISC02 2D		n² = A + Bx² + C/(x²-D²) [web citation]
MISC03 2D		n² = A + B/x² + Cx²/(x²-D²) [web citation]
MISC04 2D		n² = A + Bx² + Cx⁴ + D/x² + Ex²/(x²-F+(Gx²/(x²-F))) [web citation]
SCHOTT2X3 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ [web citation]
SCHOTT2X4 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ [web citation]
SCHOTT2X5 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ [web citation]
SCHOTT2X6 2D		n² = A + Bx² + C/x² + D/x⁴ + E/x⁶ + F/x⁸ + G/x¹⁰ + H/x¹² [web citation]
SCHOTT3X3 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ [web citation]
SCHOTT3X4 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ [web citation]
SCHOTT3X5 2D		n² = A + Bx² + Cx⁴ + D/x² + E/x⁴ + F/x⁶ + G/x⁸ + H/x¹⁰ [web citation]
SCHOTT4X4 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + E/x² + F/x⁴ + G/x⁶ + H/x⁸ [web citation]
SCHOTT5X5 2D		n² = A + Bx² + Cx⁴ + Dx⁶ + Ex⁸ + F/x² + G/x⁴ + H/x⁶ + J/x⁸ + K/x¹⁰ [web citation]
SELL1T 2D		n² = 1 + Ax² / (x² - B²) [web citation]
SELL1TA 2D		n² = A + Bx² / (x² - C²) [web citation]
SELL2T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) [web citation]
SELL2TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) [web citation]
SELL3T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) [web citation]
SELL3TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) [web citation]
SELL4T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) [web citation]
SELL4TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) [web citation]
SELL5T 2D		n² = 1 + Ax²/(x²-B²) + Cx²/(x²-D²) + Ex²/(x²-F²) + Gx²/(x²-H²) + Jx²/(x²-K²) [web citation]
SELL5TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) [web citation]
SELL6TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) [web citation]
SELL7TA 2D		n² = A + Bx²/(x²-C²) + Dx²/(x²-E²) + Fx²/(x²-G²) + Hx²/(x²-J²) + Kx²/(x²-M²) + Nx²/(x²-P²) + Qx²/(x²-R²) [web citation]
SELLMOD1 2D		n² = A + Bx + Cx² + Dx²/(x²-E²) [web citation]
SELLMOD1A 2D		n² = A + Bx + Cx² + D/(x²-E²) [web citation]
SELLMOD2 2D		n² = A + Bx + Cx⁴ + Dx²/(x²-E²) [web citation]
SELLMOD2A 2D		n² = A + Bx + Cx⁴ + D/(x²-E²) [web citation]
SELLMOD3 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) [web citation]
SELLMOD4 2D		n² = A + Bx² + C/x² + Dx²/(x²-E²) + Fx²/(x²-G²) [web citation]
SELLMOD4A 2D		n² = A + Bx² + C/x² + D/(x²-E²) + F/(x²-G²) [web citation]
SELLMOD5 2D		n² = A + Bx² + Cx²/(x²-D²) + Ex²/(x²-F²) [web citation]
SELLMOD6 2D		n² = A + Bx²/(x²-C²) + D/(x²-E²) [web citation]
SELLMOD7 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + Ex²/(x²-F²) [web citation]
SELLMOD7A 2D		n² = A + Bx² + Cx⁴ + D/x⁶ + E/(x²-F²) [web citation]
SELLMOD8 2D		n² = A + Bx² + Cx⁴ + D/(x²-E²) + F/(x²-G²) [web citation]
SELLMOD9 2D		n² = A + B/x² + C/x⁴ + D/x⁶ + Ex²/(x²-F²) [web citation]



HARTMANN3b With Offset 2D		n = A/(x - B)^1.2 + Offset [web citation]
SELLMOD3 With Offset 2D		n² = (Ax²+B)/(x²-C²) + Dx²/(x²-E²) + Offset [web citation]



HARTMANN3b Plus Line 2D		n = A/(x - B)^1.2 n = n + (c * x) + d [web citation]

2D Peak

Arnold Cohen Log-Normal Peak Shifted With Exponential Decay And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y / exp(x) + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Decay And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y / (f * exp(x)) + Offset
Box Lucas A Shifted With Exponential Decay And Offset 2D		y = a * (1.0 - b^x-c) y = y / exp(x) + Offset
Box Lucas A With Exponential Decay And Offset 2D		y = a * (1.0 - b^x) y = y / exp(x) + Offset
Box Lucas B Shifted With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y / exp(x) + Offset
Box Lucas B With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x) + Offset
Box Lucas C With Exponential Decay And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / exp(x) + Offset
Box Lucas C shifted With Exponential Decay And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / exp(x) + Offset
Extreme Value 4 Parameter Peak With Exponential Decay And Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y / exp(x) + Offset
Extreme Value Area With Exponential Decay And Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y / exp(x) + Offset
Extreme Value Peak With Exponential Decay And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / exp(x) + Offset
Gaussian Area With Exponential Decay And Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y / exp(x) + Offset
Gaussian Peak Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y / exp(x) + Offset
Gaussian Peak With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y / exp(x) + Offset
Hamilton With Exponential Decay And Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb / (g * exp(x)) + Offset
Laplace Area With Exponential Decay And Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / exp(x) + Offset
Laplace Peak With Exponential Decay And Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / exp(x) + Offset
Log-Normal 4 Parameter With Exponential Decay And Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = y / exp(x) + Offset
Log-Normal Peak A Modified Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y / exp(x) + Offset
Log-Normal Peak A Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y / exp(x) + Offset
Log-Normal Peak A Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y / exp(x) + Offset
Log-Normal Peak A With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y / exp(x) + Offset
Log-Normal Peak B Modified Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / exp(x) + Offset
Log-Normal Peak B Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / exp(x) + Offset
Log-Normal Peak B Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y / exp(x) + Offset
Log-Normal Peak B With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / exp(x) + Offset
Logistic Area With Exponential Decay And Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y / exp(x) + Offset
Logistic Peak With Exponential Decay And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y / exp(x) + Offset
Lorentzian Modified Peak A With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)^b) y = y / (c * exp(x)) + Offset
Lorentzian Modified Peak B With Exponential Decay And Offset 2D		y = 1.0 / (a + (x-b)^c) y = y / (d * exp(x)) + Offset
Lorentzian Modified Peak C With Exponential Decay And Offset 2D		y = a / (b + (x-c)^d) y = y / exp(x) + Offset
Lorentzian Modified Peak D With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y / (d * exp(x)) + Offset
Lorentzian Modified Peak E With Exponential Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y / (f * exp(x)) + Offset
Lorentzian Modified Peak F With Exponential Decay And Offset 2D		y = a / (b + ((x-c)/d)^f) y = y / exp(x) + Offset
Lorentzian Modified Peak G With Exponential Decay And Offset 2D		y = a / (1.0 + ((x-b)/c)^d) y = y / exp(x) + Offset
Lorentzian Peak A With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)²) y = y / (b * exp(x)) + Offset
Lorentzian Peak B With Exponential Decay And Offset 2D		y = 1.0 / (a + (x-b)²) y = y / (c * exp(x)) + Offset
Lorentzian Peak C With Exponential Decay And Offset 2D		y = a / (b + (x-c)²) y = y / exp(x) + Offset
Lorentzian Peak D With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y / (c * exp(x)) + Offset
Lorentzian Peak E With Exponential Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)²) y = y / (d * exp(x)) + Offset
Lorentzian Peak F With Exponential Decay And Offset 2D		y = a / (b + ((x-c)/d)²) y = y / exp(x) + Offset
Lorentzian Peak G With Exponential Decay And Offset 2D		y = a / (1.0 + ((x-b)/c)²) y = y / exp(x) + Offset
Pseudo-Voight Peak Modified With Exponential Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y / exp(x) + Offset
Pseudo-Voight Peak With Exponential Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y / exp(x) + Offset
Pulse Peak With Exponential Decay And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / exp(x) + Offset
UVED Fruit Growth Rate B With Exponential Decay And Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / exp(x) + Offset [web citation]
UVED Fruit Growth Rate Scaled B With Exponential Decay And Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / exp(x) + Offset [web citation]
UVED Fruit Growth Rate Scaled With Exponential Decay And Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (d * exp(x)) + Offset [web citation]
UVED Fruit Growth Rate Transform B With Exponential Decay And Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / exp(x) + Offset [web citation]
UVED Fruit Growth Rate Transform With Exponential Decay And Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (f * exp(x)) + Offset [web citation]
UVED Fruit Growth Rate With Exponential Decay And Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (c * exp(x)) + Offset [web citation]
Weibull Peak Modified Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / exp(x) + Offset
Weibull Peak Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / exp(x) + Offset
Weibull Peak Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y / exp(x) + Offset
Weibull Peak With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / exp(x) + Offset



Arnold Cohen Log-Normal Peak Shifted With Exponential Decay 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y / exp(x)
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Decay 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y / (f * exp(x))
Box Lucas A Shifted With Exponential Decay 2D		y = a * (1.0 - b^x-c) y = y / exp(x)
Box Lucas A With Exponential Decay 2D		y = a * (1.0 - b^x) y = y / exp(x)
Box Lucas B Shifted With Exponential Decay 2D		y = a * (1.0 - exp(-b(x-c))) y = y / exp(x)
Box Lucas B With Exponential Decay 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x)
Box Lucas C With Exponential Decay 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / exp(x)
Box Lucas C shifted With Exponential Decay 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / exp(x)
Extreme Value 4 Parameter Peak With Exponential Decay 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y / exp(x)
Extreme Value Area With Exponential Decay 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y / exp(x)
Extreme Value Peak With Exponential Decay 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / exp(x)
Gaussian Area With Exponential Decay 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y / exp(x)
Gaussian Peak Modified With Exponential Decay 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y / exp(x)
Gaussian Peak With Exponential Decay 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y / exp(x)
Hamilton With Exponential Decay 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb / (g * exp(x))
Laplace Area With Exponential Decay 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / exp(x)
Laplace Peak With Exponential Decay 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / exp(x)
Log-Normal 4 Parameter With Exponential Decay 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = y / exp(x)
Log-Normal Peak A Modified Shifted With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y / exp(x)
Log-Normal Peak A Modified With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y / exp(x)
Log-Normal Peak A Shifted With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y / exp(x)
Log-Normal Peak A With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y / exp(x)
Log-Normal Peak B Modified Shifted With Exponential Decay 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / exp(x)
Log-Normal Peak B Modified With Exponential Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / exp(x)
Log-Normal Peak B Shifted With Exponential Decay 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y / exp(x)
Log-Normal Peak B With Exponential Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / exp(x)
Logistic Area With Exponential Decay 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y / exp(x)
Logistic Peak With Exponential Decay 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y / exp(x)
Lorentzian Modified Peak A With Exponential Decay 2D		y = 1.0 / (1.0 + (x-a)^b) y = y / (c * exp(x))
Lorentzian Modified Peak B With Exponential Decay 2D		y = 1.0 / (a + (x-b)^c) y = y / (d * exp(x))
Lorentzian Modified Peak C With Exponential Decay 2D		y = a / (b + (x-c)^d) y = y / exp(x)
Lorentzian Modified Peak D With Exponential Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y / (d * exp(x))
Lorentzian Modified Peak E With Exponential Decay 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y / (f * exp(x))
Lorentzian Modified Peak F With Exponential Decay 2D		y = a / (b + ((x-c)/d)^f) y = y / exp(x)
Lorentzian Modified Peak G With Exponential Decay 2D		y = a / (1.0 + ((x-b)/c)^d) y = y / exp(x)
Lorentzian Peak A With Exponential Decay 2D		y = 1.0 / (1.0 + (x-a)²) y = y / (b * exp(x))
Lorentzian Peak B With Exponential Decay 2D		y = 1.0 / (a + (x-b)²) y = y / (c * exp(x))
Lorentzian Peak C With Exponential Decay 2D		y = a / (b + (x-c)²) y = y / exp(x)
Lorentzian Peak D With Exponential Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y / (c * exp(x))
Lorentzian Peak E With Exponential Decay 2D		y = 1.0 / (a + ((x-b)/c)²) y = y / (d * exp(x))
Lorentzian Peak F With Exponential Decay 2D		y = a / (b + ((x-c)/d)²) y = y / exp(x)
Lorentzian Peak G With Exponential Decay 2D		y = a / (1.0 + ((x-b)/c)²) y = y / exp(x)
Pseudo-Voight Peak Modified With Exponential Decay 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y / exp(x)
Pseudo-Voight Peak With Exponential Decay 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y / exp(x)
Pulse Peak With Exponential Decay 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / exp(x)
UVED Fruit Growth Rate B With Exponential Decay 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / exp(x) [web citation]
UVED Fruit Growth Rate Scaled B With Exponential Decay 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / exp(x) [web citation]
UVED Fruit Growth Rate Scaled With Exponential Decay 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (d * exp(x)) [web citation]
UVED Fruit Growth Rate Transform B With Exponential Decay 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / exp(x) [web citation]
UVED Fruit Growth Rate Transform With Exponential Decay 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (f * exp(x)) [web citation]
UVED Fruit Growth Rate With Exponential Decay 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (c * exp(x)) [web citation]
Weibull Peak Modified Shifted With Exponential Decay 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / exp(x)
Weibull Peak Modified With Exponential Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / exp(x)
Weibull Peak Shifted With Exponential Decay 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y / exp(x)
Weibull Peak With Exponential Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / exp(x)



Arnold Cohen Log-Normal Peak Shifted With Exponential Growth And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y * exp(x) + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Growth And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y * (f * exp(x)) + Offset
Box Lucas A Shifted With Exponential Growth And Offset 2D		y = a * (1.0 - b^x-c) y = y * exp(x) + Offset
Box Lucas A With Exponential Growth And Offset 2D		y = a * (1.0 - b^x) y = y * exp(x) + Offset
Box Lucas B Shifted With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y * exp(x) + Offset
Box Lucas B With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x) + Offset
Box Lucas C With Exponential Growth And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * exp(x) + Offset
Box Lucas C shifted With Exponential Growth And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * exp(x) + Offset
Extreme Value 4 Parameter Peak With Exponential Growth And Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y * exp(x) + Offset
Extreme Value Area With Exponential Growth And Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y * exp(x) + Offset
Extreme Value Peak With Exponential Growth And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * exp(x) + Offset
Gaussian Area With Exponential Growth And Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y * exp(x) + Offset
Gaussian Peak Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y * exp(x) + Offset
Gaussian Peak With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y * exp(x) + Offset
Hamilton With Exponential Growth And Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb * (g * exp(x)) + Offset
Laplace Area With Exponential Growth And Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * exp(x) + Offset
Laplace Peak With Exponential Growth And Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * exp(x) + Offset
Log-Normal 4 Parameter With Exponential Growth And Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (cd)) + 1.0)²) / ln(d)²) y = y exp(x) + Offset
Log-Normal Peak A Modified Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y * exp(x) + Offset
Log-Normal Peak A Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y * exp(x) + Offset
Log-Normal Peak A Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y * exp(x) + Offset
Log-Normal Peak A With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y * exp(x) + Offset
Log-Normal Peak B Modified Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * exp(x) + Offset
Log-Normal Peak B Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * exp(x) + Offset
Log-Normal Peak B Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y * exp(x) + Offset
Log-Normal Peak B With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * exp(x) + Offset
Logistic Area With Exponential Growth And Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y * exp(x) + Offset
Logistic Peak With Exponential Growth And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y * exp(x) + Offset
Lorentzian Modified Peak A With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)^b) y = y * (c * exp(x)) + Offset
Lorentzian Modified Peak B With Exponential Growth And Offset 2D		y = 1.0 / (a + (x-b)^c) y = y * (d * exp(x)) + Offset
Lorentzian Modified Peak C With Exponential Growth And Offset 2D		y = a / (b + (x-c)^d) y = y * exp(x) + Offset
Lorentzian Modified Peak D With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y * (d * exp(x)) + Offset
Lorentzian Modified Peak E With Exponential Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y * (f * exp(x)) + Offset
Lorentzian Modified Peak F With Exponential Growth And Offset 2D		y = a / (b + ((x-c)/d)^f) y = y * exp(x) + Offset
Lorentzian Modified Peak G With Exponential Growth And Offset 2D		y = a / (1.0 + ((x-b)/c)^d) y = y * exp(x) + Offset
Lorentzian Peak A With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)²) y = y * (b * exp(x)) + Offset
Lorentzian Peak B With Exponential Growth And Offset 2D		y = 1.0 / (a + (x-b)²) y = y * (c * exp(x)) + Offset
Lorentzian Peak C With Exponential Growth And Offset 2D		y = a / (b + (x-c)²) y = y * exp(x) + Offset
Lorentzian Peak D With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y * (c * exp(x)) + Offset
Lorentzian Peak E With Exponential Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)²) y = y * (d * exp(x)) + Offset
Lorentzian Peak F With Exponential Growth And Offset 2D		y = a / (b + ((x-c)/d)²) y = y * exp(x) + Offset
Lorentzian Peak G With Exponential Growth And Offset 2D		y = a / (1.0 + ((x-b)/c)²) y = y * exp(x) + Offset
Pseudo-Voight Peak Modified With Exponential Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y * exp(x) + Offset
Pseudo-Voight Peak With Exponential Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y * exp(x) + Offset
Pulse Peak With Exponential Growth And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * exp(x) + Offset
UVED Fruit Growth Rate B With Exponential Growth And Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * exp(x) + Offset [web citation]
UVED Fruit Growth Rate Scaled B With Exponential Growth And Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * exp(x) + Offset [web citation]
UVED Fruit Growth Rate Scaled With Exponential Growth And Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (d * exp(x)) + Offset [web citation]
UVED Fruit Growth Rate Transform B With Exponential Growth And Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * exp(x) + Offset [web citation]
UVED Fruit Growth Rate Transform With Exponential Growth And Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (f * exp(x)) + Offset [web citation]
UVED Fruit Growth Rate With Exponential Growth And Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (c * exp(x)) + Offset [web citation]
Weibull Peak Modified Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * exp(x) + Offset
Weibull Peak Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * exp(x) + Offset
Weibull Peak Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y * exp(x) + Offset
Weibull Peak With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * exp(x) + Offset



Arnold Cohen Log-Normal Peak Shifted With Exponential Growth 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y * exp(x)
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Growth 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y * (f * exp(x))
Box Lucas A Shifted With Exponential Growth 2D		y = a * (1.0 - b^x-c) y = y * exp(x)
Box Lucas A With Exponential Growth 2D		y = a * (1.0 - b^x) y = y * exp(x)
Box Lucas B Shifted With Exponential Growth 2D		y = a * (1.0 - exp(-b(x-c))) y = y * exp(x)
Box Lucas B With Exponential Growth 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x)
Box Lucas C With Exponential Growth 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * exp(x)
Box Lucas C shifted With Exponential Growth 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * exp(x)
Extreme Value 4 Parameter Peak With Exponential Growth 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y * exp(x)
Extreme Value Area With Exponential Growth 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y * exp(x)
Extreme Value Peak With Exponential Growth 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * exp(x)
Gaussian Area With Exponential Growth 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y * exp(x)
Gaussian Peak Modified With Exponential Growth 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y * exp(x)
Gaussian Peak With Exponential Growth 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y * exp(x)
Hamilton With Exponential Growth 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb * (g * exp(x))
Laplace Area With Exponential Growth 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * exp(x)
Laplace Peak With Exponential Growth 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * exp(x)
Log-Normal 4 Parameter With Exponential Growth 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (cd)) + 1.0)²) / ln(d)²) y = y exp(x)
Log-Normal Peak A Modified Shifted With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y * exp(x)
Log-Normal Peak A Modified With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y * exp(x)
Log-Normal Peak A Shifted With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y * exp(x)
Log-Normal Peak A With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y * exp(x)
Log-Normal Peak B Modified Shifted With Exponential Growth 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * exp(x)
Log-Normal Peak B Modified With Exponential Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * exp(x)
Log-Normal Peak B Shifted With Exponential Growth 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y * exp(x)
Log-Normal Peak B With Exponential Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * exp(x)
Logistic Area With Exponential Growth 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y * exp(x)
Logistic Peak With Exponential Growth 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y * exp(x)
Lorentzian Modified Peak A With Exponential Growth 2D		y = 1.0 / (1.0 + (x-a)^b) y = y * (c * exp(x))
Lorentzian Modified Peak B With Exponential Growth 2D		y = 1.0 / (a + (x-b)^c) y = y * (d * exp(x))
Lorentzian Modified Peak C With Exponential Growth 2D		y = a / (b + (x-c)^d) y = y * exp(x)
Lorentzian Modified Peak D With Exponential Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y * (d * exp(x))
Lorentzian Modified Peak E With Exponential Growth 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y * (f * exp(x))
Lorentzian Modified Peak F With Exponential Growth 2D		y = a / (b + ((x-c)/d)^f) y = y * exp(x)
Lorentzian Modified Peak G With Exponential Growth 2D		y = a / (1.0 + ((x-b)/c)^d) y = y * exp(x)
Lorentzian Peak A With Exponential Growth 2D		y = 1.0 / (1.0 + (x-a)²) y = y * (b * exp(x))
Lorentzian Peak B With Exponential Growth 2D		y = 1.0 / (a + (x-b)²) y = y * (c * exp(x))
Lorentzian Peak C With Exponential Growth 2D		y = a / (b + (x-c)²) y = y * exp(x)
Lorentzian Peak D With Exponential Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y * (c * exp(x))
Lorentzian Peak E With Exponential Growth 2D		y = 1.0 / (a + ((x-b)/c)²) y = y * (d * exp(x))
Lorentzian Peak F With Exponential Growth 2D		y = a / (b + ((x-c)/d)²) y = y * exp(x)
Lorentzian Peak G With Exponential Growth 2D		y = a / (1.0 + ((x-b)/c)²) y = y * exp(x)
Pseudo-Voight Peak Modified With Exponential Growth 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y * exp(x)
Pseudo-Voight Peak With Exponential Growth 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y * exp(x)
Pulse Peak With Exponential Growth 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * exp(x)
UVED Fruit Growth Rate B With Exponential Growth 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * exp(x) [web citation]
UVED Fruit Growth Rate Scaled B With Exponential Growth 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * exp(x) [web citation]
UVED Fruit Growth Rate Scaled With Exponential Growth 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (d * exp(x)) [web citation]
UVED Fruit Growth Rate Transform B With Exponential Growth 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * exp(x) [web citation]
UVED Fruit Growth Rate Transform With Exponential Growth 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (f * exp(x)) [web citation]
UVED Fruit Growth Rate With Exponential Growth 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (c * exp(x)) [web citation]
Weibull Peak Modified Shifted With Exponential Growth 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * exp(x)
Weibull Peak Modified With Exponential Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * exp(x)
Weibull Peak Shifted With Exponential Growth 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y * exp(x)
Weibull Peak With Exponential Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * exp(x)



Inverse Arnold Cohen Log-Normal Peak Shifted 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = x / y
Inverse Arnold Cohen Two-Parameter Log-Normal Peak Shifted 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = x / y
Inverse Box Lucas A 2D		y = a * (1.0 - b^x) y = x / y
Inverse Box Lucas A Shifted 2D		y = a * (1.0 - b^x-c) y = x / y
Inverse Box Lucas B 2D		y = a * (1.0 - exp(-bx)) y = x / y
Inverse Box Lucas B Shifted 2D		y = a * (1.0 - exp(-b(x-c))) y = x / y
Inverse Box Lucas C 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = x / y
Inverse Box Lucas C shifted 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = x / y
Inverse Extreme Value 4 Parameter Peak 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = x / y
Inverse Extreme Value Area 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = x / y
Inverse Extreme Value Peak 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = x / y
Inverse Gaussian Area 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = x / y
Inverse Gaussian Peak 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = x / y
Inverse Gaussian Peak Modified 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = x / y
Inverse Hamilton 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = x / Vb
Inverse Laplace Area 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = x / y
Inverse Laplace Peak 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = x / y
Inverse Log-Normal 4 Parameter 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = x / y
Inverse Log-Normal Peak A 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = x / y
Inverse Log-Normal Peak A Modified 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = x / y
Inverse Log-Normal Peak A Modified Shifted 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = x / y
Inverse Log-Normal Peak A Shifted 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = x / y
Inverse Log-Normal Peak B 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = x / y
Inverse Log-Normal Peak B Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = x / y
Inverse Log-Normal Peak B Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = x / y
Inverse Log-Normal Peak B Shifted 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = x / y
Inverse Logistic Area 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = x / y
Inverse Logistic Peak 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = x / y
Inverse Lorentzian Modified Peak A 2D		y = 1.0 / (1.0 + (x-a)^b) y = x / y
Inverse Lorentzian Modified Peak B 2D		y = 1.0 / (a + (x-b)^c) y = x / y
Inverse Lorentzian Modified Peak C 2D		y = a / (b + (x-c)^d) y = x / y
Inverse Lorentzian Modified Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = x / y
Inverse Lorentzian Modified Peak E 2D		y = 1.0 / (a + ((x-b)/c)^d) y = x / y
Inverse Lorentzian Modified Peak F 2D		y = a / (b + ((x-c)/d)^f) y = x / y
Inverse Lorentzian Modified Peak G 2D		y = a / (1.0 + ((x-b)/c)^d) y = x / y
Inverse Lorentzian Peak A 2D		y = 1.0 / (1.0 + (x-a)²) y = x / y
Inverse Lorentzian Peak B 2D		y = 1.0 / (a + (x-b)²) y = x / y
Inverse Lorentzian Peak C 2D		y = a / (b + (x-c)²) y = x / y
Inverse Lorentzian Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = x / y
Inverse Lorentzian Peak E 2D		y = 1.0 / (a + ((x-b)/c)²) y = x / y
Inverse Lorentzian Peak F 2D		y = a / (b + ((x-c)/d)²) y = x / y
Inverse Lorentzian Peak G 2D		y = a / (1.0 + ((x-b)/c)²) y = x / y
Inverse Pseudo-Voight Peak 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = x / y
Inverse Pseudo-Voight Peak Modified 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = x / y
Inverse Pulse Peak 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = x / y
Inverse UVED Fruit Growth Rate 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y [web citation]
Inverse UVED Fruit Growth Rate B 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y [web citation]
Inverse UVED Fruit Growth Rate Scaled 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y [web citation]
Inverse UVED Fruit Growth Rate Scaled B 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y [web citation]
Inverse UVED Fruit Growth Rate Transform 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y [web citation]
Inverse UVED Fruit Growth Rate Transform B 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y [web citation]
Inverse Weibull Peak 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = x / y
Inverse Weibull Peak Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = x / y
Inverse Weibull Peak Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = x / y
Inverse Weibull Peak Shifted 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = x / y



Inverse Arnold Cohen Log-Normal Peak Shifted With Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = x / y + Offset
Inverse Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = x / y + Offset
Inverse Box Lucas A Shifted With Offset 2D		y = a * (1.0 - b^x-c) y = x / y + Offset
Inverse Box Lucas A With Offset 2D		y = a * (1.0 - b^x) y = x / y + Offset
Inverse Box Lucas B Shifted With Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = x / y + Offset
Inverse Box Lucas B With Offset 2D		y = a * (1.0 - exp(-bx)) y = x / y + Offset
Inverse Box Lucas C With Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = x / y + Offset
Inverse Box Lucas C shifted With Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = x / y + Offset
Inverse Extreme Value 4 Parameter Peak With Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = x / y + Offset
Inverse Extreme Value Area With Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = x / y + Offset
Inverse Extreme Value Peak With Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = x / y + Offset
Inverse Gaussian Area With Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = x / y + Offset
Inverse Gaussian Peak Modified With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = x / y + Offset
Inverse Gaussian Peak With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = x / y + Offset
Inverse Hamilton With Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = x / Vb + Offset
Inverse Laplace Area With Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = x / y + Offset
Inverse Laplace Peak With Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = x / y + Offset
Inverse Log-Normal 4 Parameter With Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = x / y + Offset
Inverse Log-Normal Peak A Modified Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = x / y + Offset
Inverse Log-Normal Peak A Modified With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = x / y + Offset
Inverse Log-Normal Peak A Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = x / y + Offset
Inverse Log-Normal Peak A With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = x / y + Offset
Inverse Log-Normal Peak B Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = x / y + Offset
Inverse Log-Normal Peak B Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = x / y + Offset
Inverse Log-Normal Peak B Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = x / y + Offset
Inverse Log-Normal Peak B With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = x / y + Offset
Inverse Logistic Area With Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = x / y + Offset
Inverse Logistic Peak With Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = x / y + Offset
Inverse Lorentzian Modified Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)^b) y = x / y + Offset
Inverse Lorentzian Modified Peak B With Offset 2D		y = 1.0 / (a + (x-b)^c) y = x / y + Offset
Inverse Lorentzian Modified Peak C With Offset 2D		y = a / (b + (x-c)^d) y = x / y + Offset
Inverse Lorentzian Modified Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = x / y + Offset
Inverse Lorentzian Modified Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) y = x / y + Offset
Inverse Lorentzian Modified Peak F With Offset 2D		y = a / (b + ((x-c)/d)^f) y = x / y + Offset
Inverse Lorentzian Modified Peak G With Offset 2D		y = a / (1.0 + ((x-b)/c)^d) y = x / y + Offset
Inverse Lorentzian Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)²) y = x / y + Offset
Inverse Lorentzian Peak B With Offset 2D		y = 1.0 / (a + (x-b)²) y = x / y + Offset
Inverse Lorentzian Peak C With Offset 2D		y = a / (b + (x-c)²) y = x / y + Offset
Inverse Lorentzian Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = x / y + Offset
Inverse Lorentzian Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)²) y = x / y + Offset
Inverse Lorentzian Peak F With Offset 2D		y = a / (b + ((x-c)/d)²) y = x / y + Offset
Inverse Lorentzian Peak G With Offset 2D		y = a / (1.0 + ((x-b)/c)²) y = x / y + Offset
Inverse Pseudo-Voight Peak Modified With Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = x / y + Offset
Inverse Pseudo-Voight Peak With Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = x / y + Offset
Inverse Pulse Peak With Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = x / y + Offset
Inverse UVED Fruit Growth Rate B With Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y + Offset [web citation]
Inverse UVED Fruit Growth Rate Scaled B With Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y + Offset [web citation]
Inverse UVED Fruit Growth Rate Scaled With Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y + Offset [web citation]
Inverse UVED Fruit Growth Rate Transform B With Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y + Offset [web citation]
Inverse UVED Fruit Growth Rate Transform With Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y + Offset [web citation]
Inverse UVED Fruit Growth Rate With Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = x / y + Offset [web citation]
Inverse Weibull Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = x / y + Offset
Inverse Weibull Peak Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = x / y + Offset
Inverse Weibull Peak Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = x / y + Offset
Inverse Weibull Peak With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = x / y + Offset



Arnold Cohen Log-Normal Peak Shifted With Linear Decay And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y / x + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Decay And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y / (f * x) + Offset
Box Lucas A Shifted With Linear Decay And Offset 2D		y = a * (1.0 - b^x-c) y = y / x + Offset
Box Lucas A With Linear Decay And Offset 2D		y = a * (1.0 - b^x) y = y / x + Offset
Box Lucas B Shifted With Linear Decay And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y / x + Offset
Box Lucas B With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / x + Offset
Box Lucas C With Linear Decay And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / x + Offset
Box Lucas C shifted With Linear Decay And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / x + Offset
Extreme Value 4 Parameter Peak With Linear Decay And Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y / x + Offset
Extreme Value Area With Linear Decay And Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y / x + Offset
Extreme Value Peak With Linear Decay And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / x + Offset
Gaussian Area With Linear Decay And Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y / x + Offset
Gaussian Peak Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y / x + Offset
Gaussian Peak With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y / x + Offset
Hamilton With Linear Decay And Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb / (g * x) + Offset
Laplace Area With Linear Decay And Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / x + Offset
Laplace Peak With Linear Decay And Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / x + Offset
Log-Normal 4 Parameter With Linear Decay And Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = y / x + Offset
Log-Normal Peak A Modified Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y / x + Offset
Log-Normal Peak A Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y / x + Offset
Log-Normal Peak A Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y / x + Offset
Log-Normal Peak A With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y / x + Offset
Log-Normal Peak B Modified Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / x + Offset
Log-Normal Peak B Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / x + Offset
Log-Normal Peak B Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y / x + Offset
Log-Normal Peak B With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / x + Offset
Logistic Area With Linear Decay And Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y / x + Offset
Logistic Peak With Linear Decay And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y / x + Offset
Lorentzian Modified Peak A With Linear Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)^b) y = y / (c * x) + Offset
Lorentzian Modified Peak B With Linear Decay And Offset 2D		y = 1.0 / (a + (x-b)^c) y = y / (d * x) + Offset
Lorentzian Modified Peak C With Linear Decay And Offset 2D		y = a / (b + (x-c)^d) y = y / x + Offset
Lorentzian Modified Peak D With Linear Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y / (d * x) + Offset
Lorentzian Modified Peak E With Linear Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y / (f * x) + Offset
Lorentzian Modified Peak F With Linear Decay And Offset 2D		y = a / (b + ((x-c)/d)^f) y = y / x + Offset
Lorentzian Modified Peak G With Linear Decay And Offset 2D		y = a / (1.0 + ((x-b)/c)^d) y = y / x + Offset
Lorentzian Peak A With Linear Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)²) y = y / (b * x) + Offset
Lorentzian Peak B With Linear Decay And Offset 2D		y = 1.0 / (a + (x-b)²) y = y / (c * x) + Offset
Lorentzian Peak C With Linear Decay And Offset 2D		y = a / (b + (x-c)²) y = y / x + Offset
Lorentzian Peak D With Linear Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y / (c * x) + Offset
Lorentzian Peak E With Linear Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)²) y = y / (d * x) + Offset
Lorentzian Peak F With Linear Decay And Offset 2D		y = a / (b + ((x-c)/d)²) y = y / x + Offset
Lorentzian Peak G With Linear Decay And Offset 2D		y = a / (1.0 + ((x-b)/c)²) y = y / x + Offset
Pseudo-Voight Peak Modified With Linear Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y / x + Offset
Pseudo-Voight Peak With Linear Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y / x + Offset
Pulse Peak With Linear Decay And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / x + Offset
UVED Fruit Growth Rate B With Linear Decay And Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / x + Offset [web citation]
UVED Fruit Growth Rate Scaled B With Linear Decay And Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / x + Offset [web citation]
UVED Fruit Growth Rate Scaled With Linear Decay And Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (d * x) + Offset [web citation]
UVED Fruit Growth Rate Transform B With Linear Decay And Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / x + Offset [web citation]
UVED Fruit Growth Rate Transform With Linear Decay And Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (f * x) + Offset [web citation]
UVED Fruit Growth Rate With Linear Decay And Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (c * x) + Offset [web citation]
Weibull Peak Modified Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / x + Offset
Weibull Peak Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / x + Offset
Weibull Peak Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y / x + Offset
Weibull Peak With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / x + Offset



Arnold Cohen Log-Normal Peak Shifted With Linear Decay 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y / x
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Decay 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y / (f * x)
Box Lucas A Shifted With Linear Decay 2D		y = a * (1.0 - b^x-c) y = y / x
Box Lucas A With Linear Decay 2D		y = a * (1.0 - b^x) y = y / x
Box Lucas B Shifted With Linear Decay 2D		y = a * (1.0 - exp(-b(x-c))) y = y / x
Box Lucas B With Linear Decay 2D		y = a * (1.0 - exp(-bx)) y = y / x
Box Lucas C With Linear Decay 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / x
Box Lucas C shifted With Linear Decay 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / x
Extreme Value 4 Parameter Peak With Linear Decay 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y / x
Extreme Value Area With Linear Decay 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y / x
Extreme Value Peak With Linear Decay 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / x
Gaussian Area With Linear Decay 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y / x
Gaussian Peak Modified With Linear Decay 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y / x
Gaussian Peak With Linear Decay 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y / x
Hamilton With Linear Decay 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb / (g * x)
Laplace Area With Linear Decay 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / x
Laplace Peak With Linear Decay 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y / x
Log-Normal 4 Parameter With Linear Decay 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = y / x
Log-Normal Peak A Modified Shifted With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y / x
Log-Normal Peak A Modified With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y / x
Log-Normal Peak A Shifted With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y / x
Log-Normal Peak A With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y / x
Log-Normal Peak B Modified Shifted With Linear Decay 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / x
Log-Normal Peak B Modified With Linear Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / x
Log-Normal Peak B Shifted With Linear Decay 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y / x
Log-Normal Peak B With Linear Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / x
Logistic Area With Linear Decay 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y / x
Logistic Peak With Linear Decay 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y / x
Lorentzian Modified Peak A With Linear Decay 2D		y = 1.0 / (1.0 + (x-a)^b) y = y / (c * x)
Lorentzian Modified Peak B With Linear Decay 2D		y = 1.0 / (a + (x-b)^c) y = y / (d * x)
Lorentzian Modified Peak C With Linear Decay 2D		y = a / (b + (x-c)^d) y = y / x
Lorentzian Modified Peak D With Linear Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y / (d * x)
Lorentzian Modified Peak E With Linear Decay 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y / (f * x)
Lorentzian Modified Peak F With Linear Decay 2D		y = a / (b + ((x-c)/d)^f) y = y / x
Lorentzian Modified Peak G With Linear Decay 2D		y = a / (1.0 + ((x-b)/c)^d) y = y / x
Lorentzian Peak A With Linear Decay 2D		y = 1.0 / (1.0 + (x-a)²) y = y / (b * x)
Lorentzian Peak B With Linear Decay 2D		y = 1.0 / (a + (x-b)²) y = y / (c * x)
Lorentzian Peak C With Linear Decay 2D		y = a / (b + (x-c)²) y = y / x
Lorentzian Peak D With Linear Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y / (c * x)
Lorentzian Peak E With Linear Decay 2D		y = 1.0 / (a + ((x-b)/c)²) y = y / (d * x)
Lorentzian Peak F With Linear Decay 2D		y = a / (b + ((x-c)/d)²) y = y / x
Lorentzian Peak G With Linear Decay 2D		y = a / (1.0 + ((x-b)/c)²) y = y / x
Pseudo-Voight Peak Modified With Linear Decay 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y / x
Pseudo-Voight Peak With Linear Decay 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y / x
Pulse Peak With Linear Decay 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / x
UVED Fruit Growth Rate B With Linear Decay 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / x [web citation]
UVED Fruit Growth Rate Scaled B With Linear Decay 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / x [web citation]
UVED Fruit Growth Rate Scaled With Linear Decay 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (d * x) [web citation]
UVED Fruit Growth Rate Transform B With Linear Decay 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / x [web citation]
UVED Fruit Growth Rate Transform With Linear Decay 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (f * x) [web citation]
UVED Fruit Growth Rate With Linear Decay 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y / (c * x) [web citation]
Weibull Peak Modified Shifted With Linear Decay 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y / x
Weibull Peak Modified With Linear Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y / x
Weibull Peak Shifted With Linear Decay 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y / x
Weibull Peak With Linear Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y / x



Arnold Cohen Log-Normal Peak Shifted With Linear Growth And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y * x + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Growth And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y * (f * x) + Offset
Box Lucas A Shifted With Linear Growth And Offset 2D		y = a * (1.0 - b^x-c) y = y * x + Offset
Box Lucas A With Linear Growth And Offset 2D		y = a * (1.0 - b^x) y = y * x + Offset
Box Lucas B Shifted With Linear Growth And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y * x + Offset
Box Lucas B With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * x + Offset
Box Lucas C With Linear Growth And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * x + Offset
Box Lucas C shifted With Linear Growth And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * x + Offset
Extreme Value 4 Parameter Peak With Linear Growth And Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y * x + Offset
Extreme Value Area With Linear Growth And Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y * x + Offset
Extreme Value Peak With Linear Growth And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * x + Offset
Gaussian Area With Linear Growth And Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y * x + Offset
Gaussian Peak Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y * x + Offset
Gaussian Peak With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y * x + Offset
Hamilton With Linear Growth And Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb * (g * x) + Offset
Laplace Area With Linear Growth And Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * x + Offset
Laplace Peak With Linear Growth And Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * x + Offset
Log-Normal 4 Parameter With Linear Growth And Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (cd)) + 1.0)²) / ln(d)²) y = y x + Offset
Log-Normal Peak A Modified Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y * x + Offset
Log-Normal Peak A Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y * x + Offset
Log-Normal Peak A Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y * x + Offset
Log-Normal Peak A With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y * x + Offset
Log-Normal Peak B Modified Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * x + Offset
Log-Normal Peak B Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * x + Offset
Log-Normal Peak B Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y * x + Offset
Log-Normal Peak B With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * x + Offset
Logistic Area With Linear Growth And Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y * x + Offset
Logistic Peak With Linear Growth And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y * x + Offset
Lorentzian Modified Peak A With Linear Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)^b) y = y * (c * x) + Offset
Lorentzian Modified Peak B With Linear Growth And Offset 2D		y = 1.0 / (a + (x-b)^c) y = y * (d * x) + Offset
Lorentzian Modified Peak C With Linear Growth And Offset 2D		y = a / (b + (x-c)^d) y = y * x + Offset
Lorentzian Modified Peak D With Linear Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y * (d * x) + Offset
Lorentzian Modified Peak E With Linear Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y * (f * x) + Offset
Lorentzian Modified Peak F With Linear Growth And Offset 2D		y = a / (b + ((x-c)/d)^f) y = y * x + Offset
Lorentzian Modified Peak G With Linear Growth And Offset 2D		y = a / (1.0 + ((x-b)/c)^d) y = y * x + Offset
Lorentzian Peak A With Linear Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)²) y = y * (b * x) + Offset
Lorentzian Peak B With Linear Growth And Offset 2D		y = 1.0 / (a + (x-b)²) y = y * (c * x) + Offset
Lorentzian Peak C With Linear Growth And Offset 2D		y = a / (b + (x-c)²) y = y * x + Offset
Lorentzian Peak D With Linear Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y * (c * x) + Offset
Lorentzian Peak E With Linear Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)²) y = y * (d * x) + Offset
Lorentzian Peak F With Linear Growth And Offset 2D		y = a / (b + ((x-c)/d)²) y = y * x + Offset
Lorentzian Peak G With Linear Growth And Offset 2D		y = a / (1.0 + ((x-b)/c)²) y = y * x + Offset
Pseudo-Voight Peak Modified With Linear Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y * x + Offset
Pseudo-Voight Peak With Linear Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y * x + Offset
Pulse Peak With Linear Growth And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * x + Offset
UVED Fruit Growth Rate B With Linear Growth And Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * x + Offset [web citation]
UVED Fruit Growth Rate Scaled B With Linear Growth And Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * x + Offset [web citation]
UVED Fruit Growth Rate Scaled With Linear Growth And Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (d * x) + Offset [web citation]
UVED Fruit Growth Rate Transform B With Linear Growth And Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * x + Offset [web citation]
UVED Fruit Growth Rate Transform With Linear Growth And Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (f * x) + Offset [web citation]
UVED Fruit Growth Rate With Linear Growth And Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (c * x) + Offset [web citation]
Weibull Peak Modified Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * x + Offset
Weibull Peak Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * x + Offset
Weibull Peak Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y * x + Offset
Weibull Peak With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * x + Offset



Arnold Cohen Log-Normal Peak Shifted With Linear Growth 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = y * x
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Growth 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = y * (f * x)
Box Lucas A Shifted With Linear Growth 2D		y = a * (1.0 - b^x-c) y = y * x
Box Lucas A With Linear Growth 2D		y = a * (1.0 - b^x) y = y * x
Box Lucas B Shifted With Linear Growth 2D		y = a * (1.0 - exp(-b(x-c))) y = y * x
Box Lucas B With Linear Growth 2D		y = a * (1.0 - exp(-bx)) y = y * x
Box Lucas C With Linear Growth 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * x
Box Lucas C shifted With Linear Growth 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * x
Extreme Value 4 Parameter Peak With Linear Growth 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = y * x
Extreme Value Area With Linear Growth 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = y * x
Extreme Value Peak With Linear Growth 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * x
Gaussian Area With Linear Growth 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = y * x
Gaussian Peak Modified With Linear Growth 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = y * x
Gaussian Peak With Linear Growth 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = y * x
Hamilton With Linear Growth 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = Vb * (g * x)
Laplace Area With Linear Growth 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * x
Laplace Peak With Linear Growth 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = y * x
Log-Normal 4 Parameter With Linear Growth 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (cd)) + 1.0)²) / ln(d)²) y = y x
Log-Normal Peak A Modified Shifted With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = y * x
Log-Normal Peak A Modified With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = y * x
Log-Normal Peak A Shifted With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = y * x
Log-Normal Peak A With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = y * x
Log-Normal Peak B Modified Shifted With Linear Growth 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * x
Log-Normal Peak B Modified With Linear Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * x
Log-Normal Peak B Shifted With Linear Growth 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = y * x
Log-Normal Peak B With Linear Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * x
Logistic Area With Linear Growth 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = y * x
Logistic Peak With Linear Growth 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = y * x
Lorentzian Modified Peak A With Linear Growth 2D		y = 1.0 / (1.0 + (x-a)^b) y = y * (c * x)
Lorentzian Modified Peak B With Linear Growth 2D		y = 1.0 / (a + (x-b)^c) y = y * (d * x)
Lorentzian Modified Peak C With Linear Growth 2D		y = a / (b + (x-c)^d) y = y * x
Lorentzian Modified Peak D With Linear Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = y * (d * x)
Lorentzian Modified Peak E With Linear Growth 2D		y = 1.0 / (a + ((x-b)/c)^d) y = y * (f * x)
Lorentzian Modified Peak F With Linear Growth 2D		y = a / (b + ((x-c)/d)^f) y = y * x
Lorentzian Modified Peak G With Linear Growth 2D		y = a / (1.0 + ((x-b)/c)^d) y = y * x
Lorentzian Peak A With Linear Growth 2D		y = 1.0 / (1.0 + (x-a)²) y = y * (b * x)
Lorentzian Peak B With Linear Growth 2D		y = 1.0 / (a + (x-b)²) y = y * (c * x)
Lorentzian Peak C With Linear Growth 2D		y = a / (b + (x-c)²) y = y * x
Lorentzian Peak D With Linear Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y * (c * x)
Lorentzian Peak E With Linear Growth 2D		y = 1.0 / (a + ((x-b)/c)²) y = y * (d * x)
Lorentzian Peak F With Linear Growth 2D		y = a / (b + ((x-c)/d)²) y = y * x
Lorentzian Peak G With Linear Growth 2D		y = a / (1.0 + ((x-b)/c)²) y = y * x
Pseudo-Voight Peak Modified With Linear Growth 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = y * x
Pseudo-Voight Peak With Linear Growth 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = y * x
Pulse Peak With Linear Growth 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * x
UVED Fruit Growth Rate B With Linear Growth 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * x [web citation]
UVED Fruit Growth Rate Scaled B With Linear Growth 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * x [web citation]
UVED Fruit Growth Rate Scaled With Linear Growth 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (d * x) [web citation]
UVED Fruit Growth Rate Transform B With Linear Growth 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * x [web citation]
UVED Fruit Growth Rate Transform With Linear Growth 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (f * x) [web citation]
UVED Fruit Growth Rate With Linear Growth 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y * (c * x) [web citation]
Weibull Peak Modified Shifted With Linear Growth 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = y * x
Weibull Peak Modified With Linear Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = y * x
Weibull Peak Shifted With Linear Growth 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = y * x
Weibull Peak With Linear Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = y * x



Reciprocal Arnold Cohen Log-Normal Peak Shifted 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = 1.0 / y
Reciprocal Arnold Cohen Two-Parameter Log-Normal Peak Shifted 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = 1.0 / y
Reciprocal Box Lucas A 2D		y = a * (1.0 - b^x) y = 1.0 / y
Reciprocal Box Lucas A Shifted 2D		y = a * (1.0 - b^x-c) y = 1.0 / y
Reciprocal Box Lucas B 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y
Reciprocal Box Lucas B Shifted 2D		y = a * (1.0 - exp(-b(x-c))) y = 1.0 / y
Reciprocal Box Lucas C 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = 1.0 / y
Reciprocal Box Lucas C shifted 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = 1.0 / y
Reciprocal Extreme Value 4 Parameter Peak 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = 1.0 / y
Reciprocal Extreme Value Area 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = 1.0 / y
Reciprocal Extreme Value Peak 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = 1.0 / y
Reciprocal Gaussian Area 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = 1.0 / y
Reciprocal Gaussian Peak 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = 1.0 / y
Reciprocal Gaussian Peak Modified 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = 1.0 / y
Reciprocal Hamilton 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = 1.0 / Vb
Reciprocal Laplace Area 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = 1.0 / y
Reciprocal Laplace Peak 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = 1.0 / y
Reciprocal Log-Normal 4 Parameter 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = 1.0 / y
Reciprocal Log-Normal Peak A 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = 1.0 / y
Reciprocal Log-Normal Peak A Modified 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = 1.0 / y
Reciprocal Log-Normal Peak A Modified Shifted 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = 1.0 / y
Reciprocal Log-Normal Peak A Shifted 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = 1.0 / y
Reciprocal Log-Normal Peak B 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = 1.0 / y
Reciprocal Log-Normal Peak B Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = 1.0 / y
Reciprocal Log-Normal Peak B Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = 1.0 / y
Reciprocal Log-Normal Peak B Shifted 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = 1.0 / y
Reciprocal Logistic Area 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = 1.0 / y
Reciprocal Logistic Peak 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = 1.0 / y
Reciprocal Lorentzian Modified Peak A 2D		y = 1.0 / (1.0 + (x-a)^b) y = 1.0 / y
Reciprocal Lorentzian Modified Peak B 2D		y = 1.0 / (a + (x-b)^c) y = 1.0 / y
Reciprocal Lorentzian Modified Peak C 2D		y = a / (b + (x-c)^d) y = 1.0 / y
Reciprocal Lorentzian Modified Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = 1.0 / y
Reciprocal Lorentzian Modified Peak E 2D		y = 1.0 / (a + ((x-b)/c)^d) y = 1.0 / y
Reciprocal Lorentzian Modified Peak F 2D		y = a / (b + ((x-c)/d)^f) y = 1.0 / y
Reciprocal Lorentzian Modified Peak G 2D		y = a / (1.0 + ((x-b)/c)^d) y = 1.0 / y
Reciprocal Lorentzian Peak A 2D		y = 1.0 / (1.0 + (x-a)²) y = 1.0 / y
Reciprocal Lorentzian Peak B 2D		y = 1.0 / (a + (x-b)²) y = 1.0 / y
Reciprocal Lorentzian Peak C 2D		y = a / (b + (x-c)²) y = 1.0 / y
Reciprocal Lorentzian Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = 1.0 / y
Reciprocal Lorentzian Peak E 2D		y = 1.0 / (a + ((x-b)/c)²) y = 1.0 / y
Reciprocal Lorentzian Peak F 2D		y = a / (b + ((x-c)/d)²) y = 1.0 / y
Reciprocal Lorentzian Peak G 2D		y = a / (1.0 + ((x-b)/c)²) y = 1.0 / y
Reciprocal Pseudo-Voight Peak 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = 1.0 / y
Reciprocal Pseudo-Voight Peak Modified 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = 1.0 / y
Reciprocal Pulse Peak 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = 1.0 / y
Reciprocal UVED Fruit Growth Rate 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y [web citation]
Reciprocal UVED Fruit Growth Rate B 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y [web citation]
Reciprocal UVED Fruit Growth Rate Scaled 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y [web citation]
Reciprocal UVED Fruit Growth Rate Scaled B 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y [web citation]
Reciprocal UVED Fruit Growth Rate Transform 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y [web citation]
Reciprocal UVED Fruit Growth Rate Transform B 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y [web citation]
Reciprocal Weibull Peak 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = 1.0 / y
Reciprocal Weibull Peak Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = 1.0 / y
Reciprocal Weibull Peak Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = 1.0 / y
Reciprocal Weibull Peak Shifted 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = 1.0 / y



Reciprocal Arnold Cohen Log-Normal Peak Shifted With Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) y = 1.0 / y + Offset
Reciprocal Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) y = 1.0 / y + Offset
Reciprocal Box Lucas A Shifted With Offset 2D		y = a * (1.0 - b^x-c) y = 1.0 / y + Offset
Reciprocal Box Lucas A With Offset 2D		y = a * (1.0 - b^x) y = 1.0 / y + Offset
Reciprocal Box Lucas B Shifted With Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = 1.0 / y + Offset
Reciprocal Box Lucas B With Offset 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y + Offset
Reciprocal Box Lucas C With Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = 1.0 / y + Offset
Reciprocal Box Lucas C shifted With Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = 1.0 / y + Offset
Reciprocal Extreme Value 4 Parameter Peak With Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) y = 1.0 / y + Offset
Reciprocal Extreme Value Area With Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) y = 1.0 / y + Offset
Reciprocal Extreme Value Peak With Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = 1.0 / y + Offset
Reciprocal Gaussian Area With Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) y = 1.0 / y + Offset
Reciprocal Gaussian Peak Modified With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) y = 1.0 / y + Offset
Reciprocal Gaussian Peak With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) y = 1.0 / y + Offset
Reciprocal Hamilton With Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) Vb = 1.0 / Vb + Offset
Reciprocal Laplace Area With Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = 1.0 / y + Offset
Reciprocal Laplace Peak With Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) y = 1.0 / y + Offset
Reciprocal Log-Normal 4 Parameter With Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak A Modified Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak A Modified With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak A Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak A With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak B Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak B Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak B Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak B With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = 1.0 / y + Offset
Reciprocal Logistic Area With Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) y = 1.0 / y + Offset
Reciprocal Logistic Peak With Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)^b) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak B With Offset 2D		y = 1.0 / (a + (x-b)^c) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak C With Offset 2D		y = a / (b + (x-c)^d) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak F With Offset 2D		y = a / (b + ((x-c)/d)^f) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak G With Offset 2D		y = a / (1.0 + ((x-b)/c)^d) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)²) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak B With Offset 2D		y = 1.0 / (a + (x-b)²) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak C With Offset 2D		y = a / (b + (x-c)²) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)²) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak F With Offset 2D		y = a / (b + ((x-c)/d)²) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak G With Offset 2D		y = a / (1.0 + ((x-b)/c)²) y = 1.0 / y + Offset
Reciprocal Pseudo-Voight Peak Modified With Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) y = 1.0 / y + Offset
Reciprocal Pseudo-Voight Peak With Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) y = 1.0 / y + Offset
Reciprocal Pulse Peak With Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = 1.0 / y + Offset
Reciprocal UVED Fruit Growth Rate B With Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y + Offset [web citation]
Reciprocal UVED Fruit Growth Rate Scaled B With Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y + Offset [web citation]
Reciprocal UVED Fruit Growth Rate Scaled With Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y + Offset [web citation]
Reciprocal UVED Fruit Growth Rate Transform B With Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y + Offset [web citation]
Reciprocal UVED Fruit Growth Rate Transform With Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y + Offset [web citation]
Reciprocal UVED Fruit Growth Rate With Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = 1.0 / y + Offset [web citation]
Reciprocal Weibull Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) y = 1.0 / y + Offset
Reciprocal Weibull Peak Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) y = 1.0 / y + Offset
Reciprocal Weibull Peak Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) y = 1.0 / y + Offset
Reciprocal Weibull Peak With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) y = 1.0 / y + Offset



Arnold Cohen Log-Normal Peak Shifted 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g))
Arnold Cohen Two-Parameter Log-Normal Peak Shifted 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f))
Box Lucas A 2D		y = a * (1.0 - b^x)
Box Lucas A Shifted 2D		y = a * (1.0 - b^x-c)
Box Lucas B 2D		y = a * (1.0 - exp(-bx))
Box Lucas B Shifted 2D		y = a * (1.0 - exp(-b(x-c)))
Box Lucas C 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax))
Box Lucas C shifted 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c)))
Extreme Value 4 Parameter Peak 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd))
Extreme Value Area 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c))
Extreme Value Peak 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0)
Gaussian Area 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²)
Gaussian Peak 2D		y = a * exp(-0.5 * ((x-b)/c)²)
Gaussian Peak Modified 2D		y = a * exp(-0.5 * ((x-b)/c)^d)
Hamilton 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b)
Laplace Area 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c)
Laplace Peak 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c)
Log-Normal 4 Parameter 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²)
Log-Normal Peak A 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²)
Log-Normal Peak A Modified 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d)
Log-Normal Peak A Modified Shifted 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d)
Log-Normal Peak A Shifted 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²)
Log-Normal Peak B 2D		y = a * exp(-0.5 * (ln(x/b)/c)²)
Log-Normal Peak B Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d)
Log-Normal Peak B Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d)
Log-Normal Peak B Shifted 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²)
Logistic Area 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²)
Logistic Peak 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))²
Lorentzian Modified Peak A 2D		y = 1.0 / (1.0 + (x-a)^b)
Lorentzian Modified Peak B 2D		y = 1.0 / (a + (x-b)^c)
Lorentzian Modified Peak C 2D		y = a / (b + (x-c)^d)
Lorentzian Modified Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)^c)
Lorentzian Modified Peak E 2D		y = 1.0 / (a + ((x-b)/c)^d)
Lorentzian Modified Peak F 2D		y = a / (b + ((x-c)/d)^f)
Lorentzian Modified Peak G 2D		y = a / (1.0 + ((x-b)/c)^d)
Lorentzian Peak A 2D		y = 1.0 / (1.0 + (x-a)²)
Lorentzian Peak B 2D		y = 1.0 / (a + (x-b)²)
Lorentzian Peak C 2D		y = a / (b + (x-c)²)
Lorentzian Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)²)
Lorentzian Peak E 2D		y = 1.0 / (a + ((x-b)/c)²)
Lorentzian Peak F 2D		y = a / (b + ((x-c)/d)²)
Lorentzian Peak G 2D		y = a / (1.0 + ((x-b)/c)²)
Pseudo-Voight Peak 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²))
Pseudo-Voight Peak Modified 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g))
Pulse Peak 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c))
UVED Fruit Growth Rate 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) [web citation]
UVED Fruit Growth Rate B 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) [web citation]
UVED Fruit Growth Rate Scaled 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) [web citation]
UVED Fruit Growth Rate Scaled B 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) [web citation]
UVED Fruit Growth Rate Transform 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) [web citation]
UVED Fruit Growth Rate Transform B 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) [web citation]
Weibull Peak 2D		y = a * exp(-0.5 * (ln(x/b)/c)²)
Weibull Peak Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d)
Weibull Peak Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d)
Weibull Peak Shifted 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²)



Arnold Cohen Log-Normal Peak Shifted With Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)²)) / (d * (x-g)) + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)²) / (sqrt(2pi) c * (x-f)) + Offset
Box Lucas A Shifted With Offset 2D		y = a * (1.0 - b^x-c) + Offset
Box Lucas A With Offset 2D		y = a * (1.0 - b^x) + Offset
Box Lucas B Shifted With Offset 2D		y = a * (1.0 - exp(-b(x-c))) + Offset
Box Lucas B With Offset 2D		y = a * (1.0 - exp(-bx)) + Offset
Box Lucas C With Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) + Offset
Box Lucas C shifted With Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) + Offset
Extreme Value 4 Parameter Peak With Offset 2D		y = a * exp(-x + b + c - cdexp(-1.0 * ((x + cln(d) - b) / c)) / (cd)) + Offset
Extreme Value Area With Offset 2D		y = (a/c) * exp(-exp(-((x-b)/c))-((x-b)/c)) + Offset
Extreme Value Peak With Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) + Offset
Gaussian Area With Offset 2D		y = (a / (pow(2pi, 0.5) c)) * exp(-0.5 * ((x-b)/c)²) + Offset
Gaussian Peak Modified With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)^d) + Offset
Gaussian Peak With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)²) + Offset
Hamilton With Offset 2D		Vb = Gb * (I/mu)^{ln(mu/I)/(BB)} + (Vb_max I)/(I + sigma_b) + Offset
Laplace Area With Offset 2D		y = (a / (pow(2.0, 0.5) * c)) * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) + Offset
Laplace Peak With Offset 2D		y = a * exp((-1.0 * pow(2.0, 0.5) * abs(x-b))/c) + Offset
Log-Normal 4 Parameter With Offset 2D		y = a * exp(-1.0 * (ln(2) * ln((((x-b) * (d²-1)) / (c*d)) + 1.0)²) / ln(d)²) + Offset
Log-Normal Peak A Modified Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-f)-b)/c)^d) + Offset
Log-Normal Peak A Modified With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)^d) + Offset
Log-Normal Peak A Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)²) + Offset
Log-Normal Peak A With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)²) + Offset
Log-Normal Peak B Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) + Offset
Log-Normal Peak B Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) + Offset
Log-Normal Peak B Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d/b))/c)²) + Offset
Log-Normal Peak B With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) + Offset
Logistic Area With Offset 2D		y = a * exp(-1.0 * (x-b) / c) / (c * (1.0 + exp(-1.0 * (x-b) / c))²) + Offset
Logistic Peak With Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))² + Offset
Lorentzian Modified Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)^b) + Offset
Lorentzian Modified Peak B With Offset 2D		y = 1.0 / (a + (x-b)^c) + Offset
Lorentzian Modified Peak C With Offset 2D		y = a / (b + (x-c)^d) + Offset
Lorentzian Modified Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)^c) + Offset
Lorentzian Modified Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)^d) + Offset
Lorentzian Modified Peak F With Offset 2D		y = a / (b + ((x-c)/d)^f) + Offset
Lorentzian Modified Peak G With Offset 2D		y = a / (1.0 + ((x-b)/c)^d) + Offset
Lorentzian Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)²) + Offset
Lorentzian Peak B With Offset 2D		y = 1.0 / (a + (x-b)²) + Offset
Lorentzian Peak C With Offset 2D		y = a / (b + (x-c)²) + Offset
Lorentzian Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)²) + Offset
Lorentzian Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)²) + Offset
Lorentzian Peak F With Offset 2D		y = a / (b + ((x-c)/d)²) + Offset
Lorentzian Peak G With Offset 2D		y = a / (1.0 + ((x-b)/c)²) + Offset
Pseudo-Voight Peak Modified With Offset 2D		y = a * (d * (1/(1+((x-b)/c)^f)) + (1-d) * exp(-0.5 * ((x-b)/c)^g)) + Offset
Pseudo-Voight Peak With Offset 2D		y = a * (d * (1/(1+((x-b)/c)²)) + (1-d) * exp(-0.5 * ((x-b)/c)²)) + Offset
Pulse Peak With Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) + Offset
UVED Fruit Growth Rate B With Offset 2D		y = c * ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) + Offset [web citation]
UVED Fruit Growth Rate Scaled B With Offset 2D		y = d * (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) + Offset [web citation]
UVED Fruit Growth Rate Scaled With Offset 2D		y = (ct)^(a-1)(1-(ct)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) + Offset [web citation]
UVED Fruit Growth Rate Transform B With Offset 2D		y = f * (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) + Offset [web citation]
UVED Fruit Growth Rate Transform With Offset 2D		y = (ct+d)^(a-1)(1-(ct+d)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) + Offset [web citation]
UVED Fruit Growth Rate With Offset 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) + Offset [web citation]
Weibull Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-f)/b)/c)^d) + Offset
Weibull Peak Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)^d) + Offset
Weibull Peak Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)²) + Offset
Weibull Peak With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)²) + Offset



Box Lucas A Plus Line 2D		y = a * (1.0 - b^x) y = y + (c * x) + d
Box Lucas B Plus Line 2D		y = a * (1.0 - exp(-bx)) y = y + (c * x) + d
Box Lucas C Plus Line 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y + (c * x) + d
Lorentzian Modified Peak A Plus Line 2D		y = 1.0 / (1.0 + (x-a)^b) y = y + (c * x) + d
Lorentzian Peak A Plus Line 2D		y = 1.0 / (1.0 + (x-a)²) y = y + (b * x) + c
Lorentzian Peak B Plus Line 2D		y = 1.0 / (a + (x-b)²) y = y + (c * x) + d
Lorentzian Peak D Plus Line 2D		y = 1.0 / (1.0 + ((x-a)/b)²) y = y + (c * x) + d
UVED Fruit Growth Rate Plus Line 2D		y = ((t/5)^(a-1)(1-t/5)^(b-1))/(((a-1)/(a+b-2))^(a-1)((b-1)/(a+b-2))^(b-1)) y = y + (c * x) + d [web citation]

2D Polyfunctional

User-Selectable Polyfunctional 2D		y = user-selectable function

2D Polynomial

Inverse 1st Order (Linear) 2D		y = a + bx y = x / y
Inverse 2nd Order (Quadratic) 2D		y = a + bx + cx² y = x / y
Inverse 3rd Order (Cubic) 2D		y = a + bx + cx² + dx³ y = x / y
Inverse 4th Order (Quartic) 2D		y = a + bx + cx² + dx³ + fx⁴ y = x / y
Inverse 5th Order (Quintic) 2D		y = a + bx + cx² + dx³ + fx⁴ + gx⁵ y = x / y
Inverse Marc Plante's Custom Quadratic 2D		y = (-b + (b² - 4 a (c - x))^0.5) / 2 / a y = x / y



Inverse Marc Plante's Custom Quadratic With Offset 2D		y = (-b + (b² - 4 a (c - x))^0.5) / 2 / a y = x / y + Offset



Reciprocal 1st Order (Linear) 2D		y = a + bx y = 1.0 / y
Reciprocal 2nd Order (Quadratic) 2D		y = a + bx + cx² y = 1.0 / y
Reciprocal 3rd Order (Cubic) 2D		y = a + bx + cx² + dx³ y = 1.0 / y
Reciprocal 4th Order (Quartic) 2D		y = a + bx + cx² + dx³ + fx⁴ y = 1.0 / y
Reciprocal 5th Order (Quintic) 2D		y = a + bx + cx² + dx³ + fx⁴ + gx⁵ y = 1.0 / y
Reciprocal Marc Plante's Custom Quadratic 2D		y = (-b + (b² - 4 a (c - x))^0.5) / 2 / a y = 1.0 / y



Reciprocal Marc Plante's Custom Quadratic With Offset 2D		y = (-b + (b² - 4 a (c - x))^0.5) / 2 / a y = 1.0 / y + Offset



1st Order (Linear) 2D		y = a + bx
2nd Order (Quadratic) 2D		y = a + bx + cx²
3rd Order (Cubic) 2D		y = a + bx + cx² + dx³
4th Order (Quartic) 2D		y = a + bx + cx² + dx³ + fx⁴
5th Order (Quintic) 2D		y = a + bx + cx² + dx³ + fx⁴ + gx⁵
Marc Plante's Custom Quadratic 2D		y = (-b + (b² - 4 a (c - x))^0.5) / 2 / a
User-Customizable Polynomial 2D		y = user-customizable polynomial
User-Selectable Polynomial 2D		y = user-selectable polynomial



Marc Plante's Custom Quadratic With Offset 2D		y = (-b + (b² - 4 a (c - x))^0.5) / 2 / a + Offset

2D Power

Geometric Modified With Exponential Decay And Offset 2D		y = a * x^(b/x) y = y / exp(x) + Offset
Power A Modified Transform With Exponential Decay And Offset 2D		y = a * b^{cx + d} y = y / exp(x) + Offset
Power A Modified With Exponential Decay And Offset 2D		y = a * b^x y = y / exp(x) + Offset
Power B Modified Transform With Exponential Decay And Offset 2D		y = a^{ln(bx + c)} y = y / (d * exp(x)) + Offset
Power B Modified With Exponential Decay And Offset 2D		y = a^ln(x) y = y / (b * exp(x)) + Offset
Power C Modified Transform With Exponential Decay And Offset 2D		y = (a + bx)^c y = y / (d * exp(x)) + Offset
Power C Modified With Exponential Decay And Offset 2D		y = (a + x)^b y = y / (c * exp(x)) + Offset
Power Law With Exponential Cutoff With Exponential Decay And Offset 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) / exp(x) + Offset
Root With Exponential Decay And Offset 2D		y = a^(1.0/x) y = y / (b * exp(x)) + Offset
Simple Power With Exponential Decay And Offset 2D		y = x^a y = y / (b * exp(x)) + Offset
Standard Geometric With Exponential Decay And Offset 2D		y = a * x^bx y = y / exp(x) + Offset
Standard Power With Exponential Decay And Offset 2D		y = a * x^b y = y / exp(x) + Offset
X Shifted Power With Exponential Decay And Offset 2D		y = a * (x-b)^c y = y / exp(x) + Offset



Geometric Modified With Exponential Decay 2D		y = a * x^(b/x) y = y / exp(x)
Power A Modified Transform With Exponential Decay 2D		y = a * b^{cx + d} y = y / exp(x)
Power A Modified With Exponential Decay 2D		y = a * b^x y = y / exp(x)
Power B Modified Transform With Exponential Decay 2D		y = a^{ln(bx + c)} y = y / (d * exp(x))
Power B Modified With Exponential Decay 2D		y = a^ln(x) y = y / (b * exp(x))
Power C Modified Transform With Exponential Decay 2D		y = (a + bx)^c y = y / (d * exp(x))
Power C Modified With Exponential Decay 2D		y = (a + x)^b y = y / (c * exp(x))
Power Law With Exponential Cutoff With Exponential Decay 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) / exp(x)
Root With Exponential Decay 2D		y = a^(1.0/x) y = y / (b * exp(x))
Simple Power With Exponential Decay 2D		y = x^a y = y / (b * exp(x))
Standard Geometric With Exponential Decay 2D		y = a * x^bx y = y / exp(x)
Standard Power With Exponential Decay 2D		y = a * x^b y = y / exp(x)
X Shifted Power With Exponential Decay 2D		y = a * (x-b)^c y = y / exp(x)



Geometric Modified With Exponential Growth And Offset 2D		y = a * x^(b/x) y = y * exp(x) + Offset
Power A Modified Transform With Exponential Growth And Offset 2D		y = a * b^{cx + d} y = y * exp(x) + Offset
Power A Modified With Exponential Growth And Offset 2D		y = a * b^x y = y * exp(x) + Offset
Power B Modified Transform With Exponential Growth And Offset 2D		y = a^{ln(bx + c)} y = y * (d * exp(x)) + Offset
Power B Modified With Exponential Growth And Offset 2D		y = a^ln(x) y = y * (b * exp(x)) + Offset
Power C Modified Transform With Exponential Growth And Offset 2D		y = (a + bx)^c y = y * (d * exp(x)) + Offset
Power C Modified With Exponential Growth And Offset 2D		y = (a + x)^b y = y * (c * exp(x)) + Offset
Power Law With Exponential Cutoff With Exponential Growth And Offset 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) * exp(x) + Offset
Root With Exponential Growth And Offset 2D		y = a^(1.0/x) y = y * (b * exp(x)) + Offset
Simple Power With Exponential Growth And Offset 2D		y = x^a y = y * (b * exp(x)) + Offset
Standard Geometric With Exponential Growth And Offset 2D		y = a * x^bx y = y * exp(x) + Offset
Standard Power With Exponential Growth And Offset 2D		y = a * x^b y = y * exp(x) + Offset
X Shifted Power With Exponential Growth And Offset 2D		y = a * (x-b)^c y = y * exp(x) + Offset



Geometric Modified With Exponential Growth 2D		y = a * x^(b/x) y = y * exp(x)
Power A Modified Transform With Exponential Growth 2D		y = a * b^{cx + d} y = y * exp(x)
Power A Modified With Exponential Growth 2D		y = a * b^x y = y * exp(x)
Power B Modified Transform With Exponential Growth 2D		y = a^{ln(bx + c)} y = y * (d * exp(x))
Power B Modified With Exponential Growth 2D		y = a^ln(x) y = y * (b * exp(x))
Power C Modified Transform With Exponential Growth 2D		y = (a + bx)^c y = y * (d * exp(x))
Power C Modified With Exponential Growth 2D		y = (a + x)^b y = y * (c * exp(x))
Power Law With Exponential Cutoff With Exponential Growth 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) * exp(x)
Root With Exponential Growth 2D		y = a^(1.0/x) y = y * (b * exp(x))
Simple Power With Exponential Growth 2D		y = x^a y = y * (b * exp(x))
Standard Geometric With Exponential Growth 2D		y = a * x^bx y = y * exp(x)
Standard Power With Exponential Growth 2D		y = a * x^b y = y * exp(x)
X Shifted Power With Exponential Growth 2D		y = a * (x-b)^c y = y * exp(x)



Inverse Geometric Modified 2D		y = a * x^(b/x) y = x / y
Inverse Power A Modified 2D		y = a * b^x y = x / y
Inverse Power A Modified Transform 2D		y = a * b^{cx + d} y = x / y
Inverse Power B Modified 2D		y = a^ln(x) y = x / y
Inverse Power B Modified Transform 2D		y = a^{ln(bx + c)} y = x / y
Inverse Power C Modified 2D		y = (a + x)^b y = x / y
Inverse Power C Modified Transform 2D		y = (a + bx)^c y = x / y
Inverse Power Law With Exponential Cutoff 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = x / p(k)
Inverse Root 2D		y = a^(1.0/x) y = x / y
Inverse Standard Geometric 2D		y = a * x^bx y = x / y
Inverse X Shifted Power 2D		y = a * (x-b)^c y = x / y



Inverse Geometric Modified With Offset 2D		y = a * x^(b/x) y = x / y + Offset
Inverse Power A Modified Transform With Offset 2D		y = a * b^{cx + d} y = x / y + Offset
Inverse Power A Modified With Offset 2D		y = a * b^x y = x / y + Offset
Inverse Power B Modified Transform With Offset 2D		y = a^{ln(bx + c)} y = x / y + Offset
Inverse Power B Modified With Offset 2D		y = a^ln(x) y = x / y + Offset
Inverse Power C Modified Transform With Offset 2D		y = (a + bx)^c y = x / y + Offset
Inverse Power C Modified With Offset 2D		y = (a + x)^b y = x / y + Offset
Inverse Power Law With Exponential Cutoff With Offset 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = x / p(k) + Offset
Inverse Root With Offset 2D		y = a^(1.0/x) y = x / y + Offset
Inverse Standard Geometric With Offset 2D		y = a * x^bx y = x / y + Offset
Inverse X Shifted Power With Offset 2D		y = a * (x-b)^c y = x / y + Offset



Geometric Modified With Linear Decay And Offset 2D		y = a * x^(b/x) y = y / x + Offset
Power A Modified Transform With Linear Decay And Offset 2D		y = a * b^{cx + d} y = y / x + Offset
Power A Modified With Linear Decay And Offset 2D		y = a * b^x y = y / x + Offset
Power B Modified Transform With Linear Decay And Offset 2D		y = a^{ln(bx + c)} y = y / (d * x) + Offset
Power B Modified With Linear Decay And Offset 2D		y = a^ln(x) y = y / (b * x) + Offset
Power C Modified Transform With Linear Decay And Offset 2D		y = (a + bx)^c y = y / (d * x) + Offset
Power C Modified With Linear Decay And Offset 2D		y = (a + x)^b y = y / (c * x) + Offset
Power Law With Exponential Cutoff With Linear Decay And Offset 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) / x + Offset
Root With Linear Decay And Offset 2D		y = a^(1.0/x) y = y / (b * x) + Offset
Simple Power With Linear Decay And Offset 2D		y = x^a y = y / (b * x) + Offset
Standard Geometric With Linear Decay And Offset 2D		y = a * x^bx y = y / x + Offset
Standard Power With Linear Decay And Offset 2D		y = a * x^b y = y / x + Offset
X Shifted Power With Linear Decay And Offset 2D		y = a * (x-b)^c y = y / x + Offset



Geometric Modified With Linear Decay 2D		y = a * x^(b/x) y = y / x
Power A Modified Transform With Linear Decay 2D		y = a * b^{cx + d} y = y / x
Power A Modified With Linear Decay 2D		y = a * b^x y = y / x
Power B Modified Transform With Linear Decay 2D		y = a^{ln(bx + c)} y = y / (d * x)
Power B Modified With Linear Decay 2D		y = a^ln(x) y = y / (b * x)
Power C Modified Transform With Linear Decay 2D		y = (a + bx)^c y = y / (d * x)
Power C Modified With Linear Decay 2D		y = (a + x)^b y = y / (c * x)
Power Law With Exponential Cutoff With Linear Decay 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) / x
Root With Linear Decay 2D		y = a^(1.0/x) y = y / (b * x)
Simple Power With Linear Decay 2D		y = x^a y = y / (b * x)
Standard Geometric With Linear Decay 2D		y = a * x^bx y = y / x
Standard Power With Linear Decay 2D		y = a * x^b y = y / x
X Shifted Power With Linear Decay 2D		y = a * (x-b)^c y = y / x



Geometric Modified With Linear Growth And Offset 2D		y = a * x^(b/x) y = y * x + Offset
Power A Modified Transform With Linear Growth And Offset 2D		y = a * b^{cx + d} y = y * x + Offset
Power A Modified With Linear Growth And Offset 2D		y = a * b^x y = y * x + Offset
Power B Modified Transform With Linear Growth And Offset 2D		y = a^{ln(bx + c)} y = y * (d * x) + Offset
Power B Modified With Linear Growth And Offset 2D		y = a^ln(x) y = y * (b * x) + Offset
Power C Modified Transform With Linear Growth And Offset 2D		y = (a + bx)^c y = y * (d * x) + Offset
Power C Modified With Linear Growth And Offset 2D		y = (a + x)^b y = y * (c * x) + Offset
Power Law With Exponential Cutoff With Linear Growth And Offset 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) * x + Offset
Root With Linear Growth And Offset 2D		y = a^(1.0/x) y = y * (b * x) + Offset
Simple Power With Linear Growth And Offset 2D		y = x^a y = y * (b * x) + Offset
Standard Geometric With Linear Growth And Offset 2D		y = a * x^bx y = y * x + Offset
Standard Power With Linear Growth And Offset 2D		y = a * x^b y = y * x + Offset
X Shifted Power With Linear Growth And Offset 2D		y = a * (x-b)^c y = y * x + Offset



Geometric Modified With Linear Growth 2D		y = a * x^(b/x) y = y * x
Power A Modified Transform With Linear Growth 2D		y = a * b^{cx + d} y = y * x
Power A Modified With Linear Growth 2D		y = a * b^x y = y * x
Power B Modified Transform With Linear Growth 2D		y = a^{ln(bx + c)} y = y * (d * x)
Power B Modified With Linear Growth 2D		y = a^ln(x) y = y * (b * x)
Power C Modified Transform With Linear Growth 2D		y = (a + bx)^c y = y * (d * x)
Power C Modified With Linear Growth 2D		y = (a + x)^b y = y * (c * x)
Power Law With Exponential Cutoff With Linear Growth 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = p(k) * x
Root With Linear Growth 2D		y = a^(1.0/x) y = y * (b * x)
Simple Power With Linear Growth 2D		y = x^a y = y * (b * x)
Standard Geometric With Linear Growth 2D		y = a * x^bx y = y * x
Standard Power With Linear Growth 2D		y = a * x^b y = y * x
X Shifted Power With Linear Growth 2D		y = a * (x-b)^c y = y * x



Reciprocal Geometric Modified 2D		y = a * x^(b/x) y = 1.0 / y
Reciprocal Power A Modified 2D		y = a * b^x y = 1.0 / y
Reciprocal Power A Modified Transform 2D		y = a * b^{cx + d} y = 1.0 / y
Reciprocal Power B Modified 2D		y = a^ln(x) y = 1.0 / y
Reciprocal Power B Modified Transform 2D		y = a^{ln(bx + c)} y = 1.0 / y
Reciprocal Power C Modified 2D		y = (a + x)^b y = 1.0 / y
Reciprocal Power C Modified Transform 2D		y = (a + bx)^c y = 1.0 / y
Reciprocal Power Law With Exponential Cutoff 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = 1.0 / p(k)
Reciprocal Root 2D		y = a^(1.0/x) y = 1.0 / y
Reciprocal Simple Power 2D		y = x^a y = 1.0 / y
Reciprocal Standard Geometric 2D		y = a * x^bx y = 1.0 / y
Reciprocal Standard Power 2D		y = a * x^b y = 1.0 / y
Reciprocal X Shifted Power 2D		y = a * (x-b)^c y = 1.0 / y



Reciprocal Geometric Modified With Offset 2D		y = a * x^(b/x) y = 1.0 / y + Offset
Reciprocal Power A Modified Transform With Offset 2D		y = a * b^{cx + d} y = 1.0 / y + Offset
Reciprocal Power A Modified With Offset 2D		y = a * b^x y = 1.0 / y + Offset
Reciprocal Power B Modified Transform With Offset 2D		y = a^{ln(bx + c)} y = 1.0 / y + Offset
Reciprocal Power B Modified With Offset 2D		y = a^ln(x) y = 1.0 / y + Offset
Reciprocal Power C Modified Transform With Offset 2D		y = (a + bx)^c y = 1.0 / y + Offset
Reciprocal Power C Modified With Offset 2D		y = (a + x)^b y = 1.0 / y + Offset
Reciprocal Power Law With Exponential Cutoff With Offset 2D		p(k) = C * k^(-T) * exp(-k/K) p(k) = 1.0 / p(k) + Offset
Reciprocal Root With Offset 2D		y = a^(1.0/x) y = 1.0 / y + Offset
Reciprocal Simple Power With Offset 2D		y = x^a y = 1.0 / y + Offset
Reciprocal Standard Geometric With Offset 2D		y = a * x^bx y = 1.0 / y + Offset
Reciprocal Standard Power With Offset 2D		y = a * x^b y = 1.0 / y + Offset
Reciprocal X Shifted Power With Offset 2D		y = a * (x-b)^c y = 1.0 / y + Offset



Geometric Modified 2D		y = a * x^(b/x)
Power A Modified 2D		y = a * b^x
Power A Modified Transform 2D		y = a * b^{cx + d}
Power B Modified 2D		y = a^ln(x)
Power B Modified Transform 2D		y = a^{ln(bx + c)}
Power C Modified 2D		y = (a + x)^b
Power C Modified Transform 2D		y = (a + bx)^c
Power Law With Exponential Cutoff 2D		p(k) = C * k^(-T) * exp(-k/K)
Root 2D		y = a^(1.0/x)
Simple Power 2D		y = x^a
Standard Geometric 2D		y = a * x^bx
Standard Power 2D		y = a * x^b
X Shifted Power 2D		y = a * (x-b)^c



Geometric Modified With Offset 2D		y = a * x^(b/x) + Offset
Power A Modified Transform With Offset 2D		y = a * b^{cx + d} + Offset
Power A Modified With Offset 2D		y = a * b^x + Offset
Power B Modified Transform With Offset 2D		y = a^{ln(bx + c)} + Offset
Power B Modified With Offset 2D		y = a^ln(x) + Offset
Power C Modified Transform With Offset 2D		y = (a + bx)^c + Offset
Power C Modified With Offset 2D		y = (a + x)^b + Offset
Power Law With Exponential Cutoff With Offset 2D		p(k) = C * k^(-T) * exp(-k/K) + Offset
Root With Offset 2D		y = a^(1.0/x) + Offset
Simple Power With Offset 2D		y = x^a + Offset
Standard Geometric With Offset 2D		y = a * x^bx + Offset
Standard Power With Offset 2D		y = a * x^b + Offset
X Shifted Power With Offset 2D		y = a * (x-b)^c + Offset



Geometric Modified Plus Line 2D		y = a * x^(b/x) y = y + (c * x) + d
Power A Modified Plus Line 2D		y = a * b^x y = y + (c * x) + d
Power B Modified Plus Line 2D		y = a^ln(x) y = y + (b * x) + c
Power C Modified Plus Line 2D		y = (a + x)^b y = y + (c * x) + d
Root Plus Line 2D		y = a^(1.0/x) y = y + (b * x) + c
Simple Power Plus Line 2D		y = x^a y = y + (b * x) + c
Standard Geometric Plus Line 2D		y = a * x^bx y = y + (c * x) + d
Standard Power Plus Line 2D		y = a * x^b y = y + (c * x) + d

2D Rational

User-Selectable Rational 2D		y = user-selectable rational

2D Sigmoidal

BET Sigmoidal A With Exponential Decay And Offset 2D		y = x / (a + bx - (a+b)x²) y = y / (c * exp(x)) + Offset
BET Sigmoidal B With Exponential Decay And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y / exp(x) + Offset
Chapman With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y / exp(x) + Offset
Don Levin Sigmoid With Exponential Decay And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (k * exp(x)) + Offset
Gompertz A With Exponential Decay And Offset 2D		y = a * exp(-exp(b - cx)) y = y / exp(x) + Offset
Gompertz B With Exponential Decay And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y / exp(x) + Offset
Gompertz C With Exponential Decay And Offset 2D		y = a * exp(b * exp(c * x)) y = y / exp(x) + Offset
Hill With Exponential Decay And Offset 2D		y = ax^b / (c^b + x^b) y = y / (d * exp(x)) + Offset
JJacquelin Generalised Logistic With Exponential Decay And Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = y / exp(x) + Offset [web citation]
Logistic A With Exponential Decay And Offset 2D		y = a / (1.0 + b*exp(-cx)) y = y / exp(x) + Offset
Logistic B With Exponential Decay And Offset 2D		y = a / (1.0 + (x/b)^c) y = y / exp(x) + Offset
Lomolino With Exponential Decay And Offset 2D		y = a / (1.0 + b^ln(c/x)) y = y / exp(x) + Offset
Magnetic Saturation With Exponential Decay And Offset 2D		y = ax * (1.0 + b*exp(cx)) y = y / exp(x) + Offset
Morgan-Mercer-Flodin (MMF) With Exponential Decay And Offset 2D		y = (a * b + c * x^d) / (b + x^d) y = y / (f * exp(x)) + Offset
Peters-Baskin Step-Stool: y (1) With Exponential Decay And Offset 2D		y = ln(c + exp(bdx)) / d y = y / exp(x) + Offset [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Decay And Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI / (d * exp(x)) + Offset [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Decay And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII / (f exp(x)) + Offset [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Decay And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII / (h * exp(x)) + Offset [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Decay And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (h exp(x)) + Offset [web citation]
Richards With Exponential Decay And Offset 2D		y = 1.0 / (a + b * e^(cx))^d y = y / (f exp(x)) + Offset
Sigmoid A Modified With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y / (d * exp(x)) + Offset
Sigmoid A With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (c * exp(x)) + Offset
Sigmoid B Modified With Exponential Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y / exp(x) + Offset
Sigmoid B With Exponential Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / exp(x) + Offset
Weibull CDF Scaled With Exponential Decay And Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y / exp(x) + Offset
Weibull CDF With Exponential Decay And Offset 2D		y = 1.0 - exp(-(x/b)^a) y = y / (c * exp(x)) + Offset
Weibull PDF With Exponential Decay And Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y / (c * exp(x)) + Offset



BET Sigmoidal A With Exponential Decay 2D		y = x / (a + bx - (a+b)x²) y = y / (c * exp(x))
BET Sigmoidal B With Exponential Decay 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y / exp(x)
Boltzmann Sigmoid A With Exponential Decay 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y / (f * exp(x))
Boltzmann Sigmoid B With Exponential Decay 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b y = y / (f * exp(x))
Chapman With Exponential Decay 2D		y = a * (1.0 - exp(-bx))^c y = y / exp(x)
Don Levin Sigmoid With Exponential Decay 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (k * exp(x))
Five-Parameter Logistic With Exponential Decay 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f y = y / (g * exp(x))
Four-Parameter Logistic With Exponential Decay 2D		y = d + (a-d) / (1.0 + (x/c)^b) y = y / (f * exp(x))
Generalised Logistic With Exponential Decay 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T y = y / (g * exp(x)) [web citation]
Gompertz A With Exponential Decay 2D		y = a * exp(-exp(b - cx)) y = y / exp(x)
Gompertz B With Exponential Decay 2D		y = a * exp(-exp((x-b)/c)) y = y / exp(x)
Gompertz C With Exponential Decay 2D		y = a * exp(b * exp(c * x)) y = y / exp(x)
Hill With Exponential Decay 2D		y = ax^b / (c^b + x^b) y = y / (d * exp(x))
JJacquelin Generalised Logistic With Exponential Decay 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = y / exp(x) [web citation]
Janoschek Growth Modified With Exponential Decay 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) w = w / (f * exp(x)) [web citation]
Janoschek Growth With Exponential Decay 2D		w = a - (1.0 - exp(-b * t^c)) w = w / (d * exp(x)) [web citation]
Logistic A With Exponential Decay 2D		y = a / (1.0 + b*exp(-cx)) y = y / exp(x)
Logistic B With Exponential Decay 2D		y = a / (1.0 + (x/b)^c) y = y / exp(x)
Lomolino With Exponential Decay 2D		y = a / (1.0 + b^ln(c/x)) y = y / exp(x)
Magnetic Saturation With Exponential Decay 2D		y = ax * (1.0 + b*exp(cx)) y = y / exp(x)
Morgan-Mercer-Flodin (MMF) With Exponential Decay 2D		y = (a * b + c * x^d) / (b + x^d) y = y / (f * exp(x))
Peters-Baskin Step-Stool: y (1) With Exponential Decay 2D		y = ln(c + exp(bdx)) / d y = y / exp(x) [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Decay 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI / (d * exp(x)) [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII / (f exp(x)) [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII / (h * exp(x)) [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (h exp(x)) [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Exponential Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q yIV = yIV / (j * exp(x)) [web citation]
Peters-Baskin Step-Stool: yV (10) With Exponential Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV / (i exp(x)) [web citation]
Richards With Exponential Decay 2D		y = 1.0 / (a + b * e^(cx))^d y = y / (f exp(x))
Sigmoid A Modified With Exponential Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y / (d * exp(x))
Sigmoid A With Exponential Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (c * exp(x))
Sigmoid B Modified With Exponential Decay 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y / exp(x)
Sigmoid B With Exponential Decay 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / exp(x)
Weibull CDF Scaled With Exponential Decay 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y / exp(x)
Weibull CDF With Exponential Decay 2D		y = 1.0 - exp(-(x/b)^a) y = y / (c * exp(x))
Weibull PDF With Exponential Decay 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y / (c * exp(x))
Weibull With Exponential Decay 2D		y = a - bexp(-cx^d) y = y / (f exp(x))



BET Sigmoidal A With Exponential Growth And Offset 2D		y = x / (a + bx - (a+b)x²) y = y * (c * exp(x)) + Offset
BET Sigmoidal B With Exponential Growth And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y * exp(x) + Offset
Chapman With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y * exp(x) + Offset
Don Levin Sigmoid With Exponential Growth And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (k * exp(x)) + Offset
Gompertz A With Exponential Growth And Offset 2D		y = a * exp(-exp(b - cx)) y = y * exp(x) + Offset
Gompertz B With Exponential Growth And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y * exp(x) + Offset
Gompertz C With Exponential Growth And Offset 2D		y = a * exp(b * exp(c * x)) y = y * exp(x) + Offset
Hill With Exponential Growth And Offset 2D		y = ax^b / (c^b + x^b) y = y * (d * exp(x)) + Offset
JJacquelin Generalised Logistic With Exponential Growth And Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(ht))) y = y exp(x) + Offset [web citation]
Logistic A With Exponential Growth And Offset 2D		y = a / (1.0 + bexp(-cx)) y = y exp(x) + Offset
Logistic B With Exponential Growth And Offset 2D		y = a / (1.0 + (x/b)^c) y = y * exp(x) + Offset
Lomolino With Exponential Growth And Offset 2D		y = a / (1.0 + b^ln(c/x)) y = y * exp(x) + Offset
Magnetic Saturation With Exponential Growth And Offset 2D		y = ax * (1.0 + bexp(cx)) y = y exp(x) + Offset
Morgan-Mercer-Flodin (MMF) With Exponential Growth And Offset 2D		y = (a * b + c * x^d) / (b + x^d) y = y * (f * exp(x)) + Offset
Peters-Baskin Step-Stool: y (1) With Exponential Growth And Offset 2D		y = ln(c + exp(bdx)) / d y = y * exp(x) + Offset [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Growth And Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI * (d * exp(x)) + Offset [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Growth And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII (f * exp(x)) + Offset [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Growth And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII * (h * exp(x)) + Offset [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Growth And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV (h * exp(x)) + Offset [web citation]
Richards With Exponential Growth And Offset 2D		y = 1.0 / (a + b * e^(cx))^d y = y (f * exp(x)) + Offset
Sigmoid A Modified With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y * (d * exp(x)) + Offset
Sigmoid A With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (c * exp(x)) + Offset
Sigmoid B Modified With Exponential Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y * exp(x) + Offset
Sigmoid B With Exponential Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * exp(x) + Offset
Weibull CDF Scaled With Exponential Growth And Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y * exp(x) + Offset
Weibull CDF With Exponential Growth And Offset 2D		y = 1.0 - exp(-(x/b)^a) y = y * (c * exp(x)) + Offset
Weibull PDF With Exponential Growth And Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y * (c * exp(x)) + Offset



BET Sigmoidal A With Exponential Growth 2D		y = x / (a + bx - (a+b)x²) y = y * (c * exp(x))
BET Sigmoidal B With Exponential Growth 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y * exp(x)
Boltzmann Sigmoid A With Exponential Growth 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y * (f * exp(x))
Boltzmann Sigmoid B With Exponential Growth 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b y = y * (f * exp(x))
Chapman With Exponential Growth 2D		y = a * (1.0 - exp(-bx))^c y = y * exp(x)
Don Levin Sigmoid With Exponential Growth 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (k * exp(x))
Five-Parameter Logistic With Exponential Growth 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f y = y * (g * exp(x))
Four-Parameter Logistic With Exponential Growth 2D		y = d + (a-d) / (1.0 + (x/c)^b) y = y * (f * exp(x))
Generalised Logistic With Exponential Growth 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T y = y * (g * exp(x)) [web citation]
Gompertz A With Exponential Growth 2D		y = a * exp(-exp(b - cx)) y = y * exp(x)
Gompertz B With Exponential Growth 2D		y = a * exp(-exp((x-b)/c)) y = y * exp(x)
Gompertz C With Exponential Growth 2D		y = a * exp(b * exp(c * x)) y = y * exp(x)
Hill With Exponential Growth 2D		y = ax^b / (c^b + x^b) y = y * (d * exp(x))
JJacquelin Generalised Logistic With Exponential Growth 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(ht))) y = y exp(x) [web citation]
Janoschek Growth Modified With Exponential Growth 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) w = w * (f * exp(x)) [web citation]
Janoschek Growth With Exponential Growth 2D		w = a - (1.0 - exp(-b * t^c)) w = w * (d * exp(x)) [web citation]
Logistic A With Exponential Growth 2D		y = a / (1.0 + bexp(-cx)) y = y exp(x)
Logistic B With Exponential Growth 2D		y = a / (1.0 + (x/b)^c) y = y * exp(x)
Lomolino With Exponential Growth 2D		y = a / (1.0 + b^ln(c/x)) y = y * exp(x)
Magnetic Saturation With Exponential Growth 2D		y = ax * (1.0 + bexp(cx)) y = y exp(x)
Morgan-Mercer-Flodin (MMF) With Exponential Growth 2D		y = (a * b + c * x^d) / (b + x^d) y = y * (f * exp(x))
Peters-Baskin Step-Stool: y (1) With Exponential Growth 2D		y = ln(c + exp(bdx)) / d y = y * exp(x) [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Growth 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI * (d * exp(x)) [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII (f * exp(x)) [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII * (h * exp(x)) [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV (h * exp(x)) [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Exponential Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q yIV = yIV * (j * exp(x)) [web citation]
Peters-Baskin Step-Stool: yV (10) With Exponential Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV (i * exp(x)) [web citation]
Richards With Exponential Growth 2D		y = 1.0 / (a + b * e^(cx))^d y = y (f * exp(x))
Sigmoid A Modified With Exponential Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y * (d * exp(x))
Sigmoid A With Exponential Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (c * exp(x))
Sigmoid B Modified With Exponential Growth 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y * exp(x)
Sigmoid B With Exponential Growth 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * exp(x)
Weibull CDF Scaled With Exponential Growth 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y * exp(x)
Weibull CDF With Exponential Growth 2D		y = 1.0 - exp(-(x/b)^a) y = y * (c * exp(x))
Weibull PDF With Exponential Growth 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y * (c * exp(x))
Weibull With Exponential Growth 2D		y = a - bexp(-cx^d) y = y (f * exp(x))



Inverse Boltzmann Sigmoid A 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = x / y
Inverse Boltzmann Sigmoid B 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b y = x / y
Inverse Chapman 2D		y = a * (1.0 - exp(-bx))^c y = x / y
Inverse Don Levin Sigmoid 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = x / y
Inverse Five-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f y = x / y
Inverse Four-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)^b) y = x / y
Inverse Generalised Logistic 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T y = x / y [web citation]
Inverse Gompertz A 2D		y = a * exp(-exp(b - cx)) y = x / y
Inverse Gompertz B 2D		y = a * exp(-exp((x-b)/c)) y = x / y
Inverse Gompertz C 2D		y = a * exp(b * exp(c * x)) y = x / y
Inverse Hill 2D		y = ax^b / (c^b + x^b) y = x / y
Inverse JJacquelin Generalised Logistic 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = x / y [web citation]
Inverse Janoschek Growth 2D		w = a - (1.0 - exp(-b * t^c)) w = x / w [web citation]
Inverse Janoschek Growth Modified 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) w = x / w [web citation]
Inverse Logistic A 2D		y = a / (1.0 + b*exp(-cx)) y = x / y
Inverse Logistic B 2D		y = a / (1.0 + (x/b)^c) y = x / y
Inverse Lomolino 2D		y = a / (1.0 + b^ln(c/x)) y = x / y
Inverse Morgan-Mercer-Flodin (MMF) 2D		y = (a * b + c * x^d) / (b + x^d) y = x / y
Inverse Peters-Baskin Step-Stool: y (1) 2D		y = ln(c + exp(bdx)) / d y = x / y [web citation]
Inverse Peters-Baskin Step-Stool: yI (2) 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = x / yI [web citation]
Inverse Peters-Baskin Step-Stool: yII (3) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1*x + K/d1 yII = x / yII [web citation]
Inverse Peters-Baskin Step-Stool: yIII (6) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = x / yIII [web citation]
Inverse Peters-Baskin Step-Stool: yIV (9) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = x / yIV [web citation]
Inverse Peters-Baskin Step-Stool: yV (10) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = x / yIV [web citation]
Inverse Peters-Baskin Step-Stool: yV (10) Scaled 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q yIV = x / yIV [web citation]
Inverse Richards 2D		y = 1.0 / (a + b * e^(c*x))^d y = x / y
Inverse Sigmoid A 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = x / y
Inverse Sigmoid A Modified 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = x / y
Inverse Sigmoid B 2D		y = a / (1.0 + exp(-(x-b)/c)) y = x / y
Inverse Sigmoid B Modified 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = x / y
Inverse Weibull 2D		y = a - b*exp(-cx^d) y = x / y
Inverse Weibull CDF 2D		y = 1.0 - exp(-(x/b)^a) y = x / y
Inverse Weibull CDF Scaled 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = x / y
Inverse Weibull PDF 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = x / y



Inverse Chapman With Offset 2D		y = a * (1.0 - exp(-bx))^c y = x / y + Offset
Inverse Don Levin Sigmoid With Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = x / y + Offset
Inverse Gompertz A With Offset 2D		y = a * exp(-exp(b - cx)) y = x / y + Offset
Inverse Gompertz B With Offset 2D		y = a * exp(-exp((x-b)/c)) y = x / y + Offset
Inverse Gompertz C With Offset 2D		y = a * exp(b * exp(c * x)) y = x / y + Offset
Inverse Hill With Offset 2D		y = ax^b / (c^b + x^b) y = x / y + Offset
Inverse JJacquelin Generalised Logistic With Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = x / y + Offset [web citation]
Inverse Logistic A With Offset 2D		y = a / (1.0 + b*exp(-cx)) y = x / y + Offset
Inverse Logistic B With Offset 2D		y = a / (1.0 + (x/b)^c) y = x / y + Offset
Inverse Lomolino With Offset 2D		y = a / (1.0 + b^ln(c/x)) y = x / y + Offset
Inverse Morgan-Mercer-Flodin (MMF) With Offset 2D		y = (a * b + c * x^d) / (b + x^d) y = x / y + Offset
Inverse Peters-Baskin Step-Stool: y (1) With Offset 2D		y = ln(c + exp(bdx)) / d y = x / y + Offset [web citation]
Inverse Peters-Baskin Step-Stool: yI (2) With Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = x / yI + Offset [web citation]
Inverse Peters-Baskin Step-Stool: yII (3) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1*x + K/d1 yII = x / yII + Offset [web citation]
Inverse Peters-Baskin Step-Stool: yIII (6) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = x / yIII + Offset [web citation]
Inverse Peters-Baskin Step-Stool: yIV (9) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = x / yIV + Offset [web citation]
Inverse Richards With Offset 2D		y = 1.0 / (a + b * e^(c*x))^d y = x / y + Offset
Inverse Sigmoid A Modified With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = x / y + Offset
Inverse Sigmoid A With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = x / y + Offset
Inverse Sigmoid B Modified With Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = x / y + Offset
Inverse Sigmoid B With Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = x / y + Offset
Inverse Weibull CDF Scaled With Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = x / y + Offset
Inverse Weibull CDF With Offset 2D		y = 1.0 - exp(-(x/b)^a) y = x / y + Offset
Inverse Weibull PDF With Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = x / y + Offset



BET Sigmoidal A With Linear Decay And Offset 2D		y = x / (a + bx - (a+b)x²) y = y / (c * x) + Offset
BET Sigmoidal B With Linear Decay And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y / x + Offset
Chapman With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y / x + Offset
Don Levin Sigmoid With Linear Decay And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (k * x) + Offset
Gompertz A With Linear Decay And Offset 2D		y = a * exp(-exp(b - cx)) y = y / x + Offset
Gompertz B With Linear Decay And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y / x + Offset
Gompertz C With Linear Decay And Offset 2D		y = a * exp(b * exp(c * x)) y = y / x + Offset
Hill With Linear Decay And Offset 2D		y = ax^b / (c^b + x^b) y = y / (d * x) + Offset
JJacquelin Generalised Logistic With Linear Decay And Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = y / x + Offset [web citation]
Logistic A With Linear Decay And Offset 2D		y = a / (1.0 + b*exp(-cx)) y = y / x + Offset
Logistic B With Linear Decay And Offset 2D		y = a / (1.0 + (x/b)^c) y = y / x + Offset
Lomolino With Linear Decay And Offset 2D		y = a / (1.0 + b^ln(c/x)) y = y / x + Offset
Magnetic Saturation With Linear Decay And Offset 2D		y = ax * (1.0 + b*exp(cx)) y = y / x + Offset
Morgan-Mercer-Flodin (MMF) With Linear Decay And Offset 2D		y = (a * b + c * x^d) / (b + x^d) y = y / (f * x) + Offset
Peters-Baskin Step-Stool: y (1) With Linear Decay And Offset 2D		y = ln(c + exp(bdx)) / d y = y / x + Offset [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Decay And Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI / (d * x) + Offset [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Decay And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII / (f x) + Offset [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Decay And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII / (h * x) + Offset [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Decay And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (h x) + Offset [web citation]
Richards With Linear Decay And Offset 2D		y = 1.0 / (a + b * e^(cx))^d y = y / (f x) + Offset
Sigmoid A Modified With Linear Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y / (d * x) + Offset
Sigmoid A With Linear Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (c * x) + Offset
Sigmoid B Modified With Linear Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y / x + Offset
Sigmoid B With Linear Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / x + Offset
Weibull CDF Scaled With Linear Decay And Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y / x + Offset
Weibull CDF With Linear Decay And Offset 2D		y = 1.0 - exp(-(x/b)^a) y = y / (c * x) + Offset
Weibull PDF With Linear Decay And Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y / (c * x) + Offset



BET Sigmoidal A With Linear Decay 2D		y = x / (a + bx - (a+b)x²) y = y / (c * x)
BET Sigmoidal B With Linear Decay 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y / x
Boltzmann Sigmoid A With Linear Decay 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y / (f * x)
Boltzmann Sigmoid B With Linear Decay 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b y = y / (f * x)
Chapman With Linear Decay 2D		y = a * (1.0 - exp(-bx))^c y = y / x
Don Levin Sigmoid With Linear Decay 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (k * x)
Five-Parameter Logistic With Linear Decay 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f y = y / (g * x)
Four-Parameter Logistic With Linear Decay 2D		y = d + (a-d) / (1.0 + (x/c)^b) y = y / (f * x)
Generalised Logistic With Linear Decay 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T y = y / (g * x) [web citation]
Gompertz A With Linear Decay 2D		y = a * exp(-exp(b - cx)) y = y / x
Gompertz B With Linear Decay 2D		y = a * exp(-exp((x-b)/c)) y = y / x
Gompertz C With Linear Decay 2D		y = a * exp(b * exp(c * x)) y = y / x
Hill With Linear Decay 2D		y = ax^b / (c^b + x^b) y = y / (d * x)
JJacquelin Generalised Logistic With Linear Decay 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = y / x [web citation]
Janoschek Growth Modified With Linear Decay 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) w = w / (f * x) [web citation]
Janoschek Growth With Linear Decay 2D		w = a - (1.0 - exp(-b * t^c)) w = w / (d * x) [web citation]
Logistic A With Linear Decay 2D		y = a / (1.0 + b*exp(-cx)) y = y / x
Logistic B With Linear Decay 2D		y = a / (1.0 + (x/b)^c) y = y / x
Lomolino With Linear Decay 2D		y = a / (1.0 + b^ln(c/x)) y = y / x
Magnetic Saturation With Linear Decay 2D		y = ax * (1.0 + b*exp(cx)) y = y / x
Morgan-Mercer-Flodin (MMF) With Linear Decay 2D		y = (a * b + c * x^d) / (b + x^d) y = y / (f * x)
Peters-Baskin Step-Stool: y (1) With Linear Decay 2D		y = ln(c + exp(bdx)) / d y = y / x [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Decay 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI / (d * x) [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII / (f x) [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII / (h * x) [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (h x) [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Linear Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q yIV = yIV / (j * x) [web citation]
Peters-Baskin Step-Stool: yV (10) With Linear Decay 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV / (i x) [web citation]
Richards With Linear Decay 2D		y = 1.0 / (a + b * e^(cx))^d y = y / (f x)
Sigmoid A Modified With Linear Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y / (d * x)
Sigmoid A With Linear Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (c * x)
Sigmoid B Modified With Linear Decay 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y / x
Sigmoid B With Linear Decay 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / x
Weibull CDF Scaled With Linear Decay 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y / x
Weibull CDF With Linear Decay 2D		y = 1.0 - exp(-(x/b)^a) y = y / (c * x)
Weibull PDF With Linear Decay 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y / (c * x)
Weibull With Linear Decay 2D		y = a - bexp(-cx^d) y = y / (f x)



BET Sigmoidal A With Linear Growth And Offset 2D		y = x / (a + bx - (a+b)x²) y = y * (c * x) + Offset
BET Sigmoidal B With Linear Growth And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y * x + Offset
Chapman With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx))^c y = y * x + Offset
Don Levin Sigmoid With Linear Growth And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (k * x) + Offset
Gompertz A With Linear Growth And Offset 2D		y = a * exp(-exp(b - cx)) y = y * x + Offset
Gompertz B With Linear Growth And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y * x + Offset
Gompertz C With Linear Growth And Offset 2D		y = a * exp(b * exp(c * x)) y = y * x + Offset
Hill With Linear Growth And Offset 2D		y = ax^b / (c^b + x^b) y = y * (d * x) + Offset
JJacquelin Generalised Logistic With Linear Growth And Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(ht))) y = y x + Offset [web citation]
Logistic A With Linear Growth And Offset 2D		y = a / (1.0 + bexp(-cx)) y = y x + Offset
Logistic B With Linear Growth And Offset 2D		y = a / (1.0 + (x/b)^c) y = y * x + Offset
Lomolino With Linear Growth And Offset 2D		y = a / (1.0 + b^ln(c/x)) y = y * x + Offset
Magnetic Saturation With Linear Growth And Offset 2D		y = ax * (1.0 + bexp(cx)) y = y x + Offset
Morgan-Mercer-Flodin (MMF) With Linear Growth And Offset 2D		y = (a * b + c * x^d) / (b + x^d) y = y * (f * x) + Offset
Peters-Baskin Step-Stool: y (1) With Linear Growth And Offset 2D		y = ln(c + exp(bdx)) / d y = y * x + Offset [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Growth And Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI * (d * x) + Offset [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Growth And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII (f * x) + Offset [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Growth And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII * (h * x) + Offset [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Growth And Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV (h * x) + Offset [web citation]
Richards With Linear Growth And Offset 2D		y = 1.0 / (a + b * e^(cx))^d y = y (f * x) + Offset
Sigmoid A Modified With Linear Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y * (d * x) + Offset
Sigmoid A With Linear Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (c * x) + Offset
Sigmoid B Modified With Linear Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y * x + Offset
Sigmoid B With Linear Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * x + Offset
Weibull CDF Scaled With Linear Growth And Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y * x + Offset
Weibull CDF With Linear Growth And Offset 2D		y = 1.0 - exp(-(x/b)^a) y = y * (c * x) + Offset
Weibull PDF With Linear Growth And Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y * (c * x) + Offset



BET Sigmoidal A With Linear Growth 2D		y = x / (a + bx - (a+b)x²) y = y * (c * x)
BET Sigmoidal B With Linear Growth 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y * x
Boltzmann Sigmoid A With Linear Growth 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y * (f * x)
Boltzmann Sigmoid B With Linear Growth 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b y = y * (f * x)
Chapman With Linear Growth 2D		y = a * (1.0 - exp(-bx))^c y = y * x
Don Levin Sigmoid With Linear Growth 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (k * x)
Five-Parameter Logistic With Linear Growth 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f y = y * (g * x)
Four-Parameter Logistic With Linear Growth 2D		y = d + (a-d) / (1.0 + (x/c)^b) y = y * (f * x)
Generalised Logistic With Linear Growth 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T y = y * (g * x) [web citation]
Gompertz A With Linear Growth 2D		y = a * exp(-exp(b - cx)) y = y * x
Gompertz B With Linear Growth 2D		y = a * exp(-exp((x-b)/c)) y = y * x
Gompertz C With Linear Growth 2D		y = a * exp(b * exp(c * x)) y = y * x
Hill With Linear Growth 2D		y = ax^b / (c^b + x^b) y = y * (d * x)
JJacquelin Generalised Logistic With Linear Growth 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(ht))) y = y x [web citation]
Janoschek Growth Modified With Linear Growth 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) w = w * (f * x) [web citation]
Janoschek Growth With Linear Growth 2D		w = a - (1.0 - exp(-b * t^c)) w = w * (d * x) [web citation]
Logistic A With Linear Growth 2D		y = a / (1.0 + bexp(-cx)) y = y x
Logistic B With Linear Growth 2D		y = a / (1.0 + (x/b)^c) y = y * x
Lomolino With Linear Growth 2D		y = a / (1.0 + b^ln(c/x)) y = y * x
Magnetic Saturation With Linear Growth 2D		y = ax * (1.0 + bexp(cx)) y = y x
Morgan-Mercer-Flodin (MMF) With Linear Growth 2D		y = (a * b + c * x^d) / (b + x^d) y = y * (f * x)
Peters-Baskin Step-Stool: y (1) With Linear Growth 2D		y = ln(c + exp(bdx)) / d y = y * x [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Growth 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = yI * (d * x) [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 yII = yII (f * x) [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = yIII * (h * x) [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV (h * x) [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Linear Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q yIV = yIV * (j * x) [web citation]
Peters-Baskin Step-Stool: yV (10) With Linear Growth 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV (i * x) [web citation]
Richards With Linear Growth 2D		y = 1.0 / (a + b * e^(cx))^d y = y (f * x)
Sigmoid A Modified With Linear Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = y * (d * x)
Sigmoid A With Linear Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (c * x)
Sigmoid B Modified With Linear Growth 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = y * x
Sigmoid B With Linear Growth 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * x
Weibull CDF Scaled With Linear Growth 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = y * x
Weibull CDF With Linear Growth 2D		y = 1.0 - exp(-(x/b)^a) y = y * (c * x)
Weibull PDF With Linear Growth 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y * (c * x)
Weibull With Linear Growth 2D		y = a - bexp(-cx^d) y = y (f * x)



Reciprocal BET Sigmoidal A 2D		y = x / (a + bx - (a+b)x²) y = 1.0 / y
Reciprocal BET Sigmoidal B 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = 1.0 / y
Reciprocal Boltzmann Sigmoid A 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = 1.0 / y
Reciprocal Boltzmann Sigmoid B 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b y = 1.0 / y
Reciprocal Chapman 2D		y = a * (1.0 - exp(-bx))^c y = 1.0 / y
Reciprocal Don Levin Sigmoid 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = 1.0 / y
Reciprocal Five-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f y = 1.0 / y
Reciprocal Four-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)^b) y = 1.0 / y
Reciprocal Generalised Logistic 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T y = 1.0 / y [web citation]
Reciprocal Gompertz A 2D		y = a * exp(-exp(b - cx)) y = 1.0 / y
Reciprocal Gompertz B 2D		y = a * exp(-exp((x-b)/c)) y = 1.0 / y
Reciprocal Gompertz C 2D		y = a * exp(b * exp(c * x)) y = 1.0 / y
Reciprocal Hill 2D		y = ax^b / (c^b + x^b) y = 1.0 / y
Reciprocal JJacquelin Generalised Logistic 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = 1.0 / y [web citation]
Reciprocal Janoschek Growth 2D		w = a - (1.0 - exp(-b * t^c)) w = 1.0 / w [web citation]
Reciprocal Janoschek Growth Modified 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) w = 1.0 / w [web citation]
Reciprocal Logistic A 2D		y = a / (1.0 + b*exp(-cx)) y = 1.0 / y
Reciprocal Logistic B 2D		y = a / (1.0 + (x/b)^c) y = 1.0 / y
Reciprocal Lomolino 2D		y = a / (1.0 + b^ln(c/x)) y = 1.0 / y
Reciprocal Magnetic Saturation 2D		y = ax * (1.0 + b*exp(cx)) y = 1.0 / y
Reciprocal Morgan-Mercer-Flodin (MMF) 2D		y = (a * b + c * x^d) / (b + x^d) y = 1.0 / y
Reciprocal Peters-Baskin Step-Stool: y (1) 2D		y = ln(c + exp(bdx)) / d y = 1.0 / y [web citation]
Reciprocal Peters-Baskin Step-Stool: yI (2) 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = 1.0 / yI [web citation]
Reciprocal Peters-Baskin Step-Stool: yII (3) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1*x + K/d1 yII = 1.0 / yII [web citation]
Reciprocal Peters-Baskin Step-Stool: yIII (6) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = 1.0 / yIII [web citation]
Reciprocal Peters-Baskin Step-Stool: yIV (9) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = 1.0 / yIV [web citation]
Reciprocal Peters-Baskin Step-Stool: yV (10) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = 1.0 / yIV [web citation]
Reciprocal Peters-Baskin Step-Stool: yV (10) Scaled 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q yIV = 1.0 / yIV [web citation]
Reciprocal Richards 2D		y = 1.0 / (a + b * e^(c*x))^d y = 1.0 / y
Reciprocal Sigmoid A 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = 1.0 / y
Reciprocal Sigmoid A Modified 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = 1.0 / y
Reciprocal Sigmoid B 2D		y = a / (1.0 + exp(-(x-b)/c)) y = 1.0 / y
Reciprocal Sigmoid B Modified 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = 1.0 / y
Reciprocal Weibull 2D		y = a - b*exp(-cx^d) y = 1.0 / y
Reciprocal Weibull CDF 2D		y = 1.0 - exp(-(x/b)^a) y = 1.0 / y
Reciprocal Weibull CDF Scaled 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = 1.0 / y
Reciprocal Weibull PDF 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = 1.0 / y



Reciprocal BET Sigmoidal A With Offset 2D		y = x / (a + bx - (a+b)x²) y = 1.0 / y + Offset
Reciprocal BET Sigmoidal B With Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = 1.0 / y + Offset
Reciprocal Chapman With Offset 2D		y = a * (1.0 - exp(-bx))^c y = 1.0 / y + Offset
Reciprocal Don Levin Sigmoid With Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = 1.0 / y + Offset
Reciprocal Gompertz A With Offset 2D		y = a * exp(-exp(b - cx)) y = 1.0 / y + Offset
Reciprocal Gompertz B With Offset 2D		y = a * exp(-exp((x-b)/c)) y = 1.0 / y + Offset
Reciprocal Gompertz C With Offset 2D		y = a * exp(b * exp(c * x)) y = 1.0 / y + Offset
Reciprocal Hill With Offset 2D		y = ax^b / (c^b + x^b) y = 1.0 / y + Offset
Reciprocal JJacquelin Generalised Logistic With Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) y = 1.0 / y + Offset [web citation]
Reciprocal Logistic A With Offset 2D		y = a / (1.0 + b*exp(-cx)) y = 1.0 / y + Offset
Reciprocal Logistic B With Offset 2D		y = a / (1.0 + (x/b)^c) y = 1.0 / y + Offset
Reciprocal Lomolino With Offset 2D		y = a / (1.0 + b^ln(c/x)) y = 1.0 / y + Offset
Reciprocal Magnetic Saturation With Offset 2D		y = ax * (1.0 + b*exp(cx)) y = 1.0 / y + Offset
Reciprocal Morgan-Mercer-Flodin (MMF) With Offset 2D		y = (a * b + c * x^d) / (b + x^d) y = 1.0 / y + Offset
Reciprocal Peters-Baskin Step-Stool: y (1) With Offset 2D		y = ln(c + exp(bdx)) / d y = 1.0 / y + Offset [web citation]
Reciprocal Peters-Baskin Step-Stool: yI (2) With Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 yI = 1.0 / yI + Offset [web citation]
Reciprocal Peters-Baskin Step-Stool: yII (3) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1*x + K/d1 yII = 1.0 / yII + Offset [web citation]
Reciprocal Peters-Baskin Step-Stool: yIII (6) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 yIII = 1.0 / yIII + Offset [web citation]
Reciprocal Peters-Baskin Step-Stool: yIV (9) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = 1.0 / yIV + Offset [web citation]
Reciprocal Richards With Offset 2D		y = 1.0 / (a + b * e^(c*x))^d y = 1.0 / y + Offset
Reciprocal Sigmoid A Modified With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c y = 1.0 / y + Offset
Reciprocal Sigmoid A With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = 1.0 / y + Offset
Reciprocal Sigmoid B Modified With Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d y = 1.0 / y + Offset
Reciprocal Sigmoid B With Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = 1.0 / y + Offset
Reciprocal Weibull CDF Scaled With Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) y = 1.0 / y + Offset
Reciprocal Weibull CDF With Offset 2D		y = 1.0 - exp(-(x/b)^a) y = 1.0 / y + Offset
Reciprocal Weibull PDF With Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = 1.0 / y + Offset



BET Sigmoidal A 2D		y = x / (a + bx - (a+b)x²)
BET Sigmoidal B 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²)
Boltzmann Sigmoid A 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b
Boltzmann Sigmoid B 2D		y = (a - b) / (1.0 + exp((x-c)/(dx))) + b
Chapman 2D		y = a * (1.0 - exp(-bx))^c
Don Levin Sigmoid 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3))
Five-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)^b)^f
Four-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)^b)
Generalised Logistic 2D		y = A + C / (1 + T * exp(-B * (x - M)))^1/T [web citation]
Gompertz A 2D		y = a * exp(-exp(b - cx))
Gompertz B 2D		y = a * exp(-exp((x-b)/c))
Gompertz C 2D		y = a * exp(b * exp(c * x))
Hill 2D		y = ax^b / (c^b + x^b)
JJacquelin Generalised Logistic 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) [web citation]
Janoschek Growth 2D		w = a - (1.0 - exp(-b * t^c)) [web citation]
Janoschek Growth Modified 2D		w = a - (a - w0) * (1.0 - exp(-b * t^c)) [web citation]
Logistic A 2D		y = a / (1.0 + b*exp(-cx))
Logistic B 2D		y = a / (1.0 + (x/b)^c)
Lomolino 2D		y = a / (1.0 + b^ln(c/x))
Magnetic Saturation 2D		y = ax * (1.0 + b*exp(cx))
Morgan-Mercer-Flodin (MMF) 2D		y = (a * b + c * x^d) / (b + x^d)
Peters-Baskin Step-Stool: y (1) 2D		y = ln(c + exp(bdx)) / d [web citation]
Peters-Baskin Step-Stool: yI (2) 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 [web citation]
Peters-Baskin Step-Stool: yII (3) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1*x + K/d1 [web citation]
Peters-Baskin Step-Stool: yIII (6) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 [web citation]
Peters-Baskin Step-Stool: yIV (9) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 [web citation]
Peters-Baskin Step-Stool: yV (10) 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII,0) ) / d2 yIV = scale (yIII - yIII,0 )+ q [web citation]
Richards 2D		y = 1.0 / (a + b * e^(c*x))^d
Sigmoid A 2D		y = 1.0 / (1.0 + exp(-a(x-b)))
Sigmoid A Modified 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c
Sigmoid B 2D		y = a / (1.0 + exp(-(x-b)/c))
Sigmoid B Modified 2D		y = a / (1.0 + exp(-(x-b)/c))^d
Weibull 2D		y = a - b*exp(-cx^d)
Weibull CDF 2D		y = 1.0 - exp(-(x/b)^a)
Weibull CDF Scaled 2D		y = Scale * (1.0 - exp(-(x/b)^a))
Weibull PDF 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a)



BET Sigmoidal A With Offset 2D		y = x / (a + bx - (a+b)x²) + Offset
BET Sigmoidal B With Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) + Offset
Chapman With Offset 2D		y = a * (1.0 - exp(-bx))^c + Offset
Don Levin Sigmoid With Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) + Offset
Gompertz A With Offset 2D		y = a * exp(-exp(b - cx)) + Offset
Gompertz B With Offset 2D		y = a * exp(-exp((x-b)/c)) + Offset
Gompertz C With Offset 2D		y = a * exp(b * exp(c * x)) + Offset
Hill With Offset 2D		y = ax^b / (c^b + x^b) + Offset
JJacquelin Generalised Logistic With Offset 2D		y = L / (1.0 + (b * exp(-kt)) + (c exp(h*t))) + Offset [web citation]
Logistic A With Offset 2D		y = a / (1.0 + b*exp(-cx)) + Offset
Logistic B With Offset 2D		y = a / (1.0 + (x/b)^c) + Offset
Lomolino With Offset 2D		y = a / (1.0 + b^ln(c/x)) + Offset
Magnetic Saturation With Offset 2D		y = ax * (1.0 + b*exp(cx)) + Offset
Morgan-Mercer-Flodin (MMF) With Offset 2D		y = (a * b + c * x^d) / (b + x^d) + Offset
Peters-Baskin Step-Stool: y (1) With Offset 2D		y = ln(c + exp(bdx)) / d + Offset [web citation]
Peters-Baskin Step-Stool: yI (2) With Offset 2D		yI = ln(exp(b2c1d1) + exp(b2d1x)) / d1 + Offset [web citation]
Peters-Baskin Step-Stool: yII (3) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1*x + K/d1 + Offset [web citation]
Peters-Baskin Step-Stool: yIII (6) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c1 + L/d1)) + exp(d2yII) ) / d2 + Offset [web citation]
Peters-Baskin Step-Stool: yIV (9) With Offset 2D		K = ln( exp(b2c1d1) + exp(b2d1x) ) yII = b1x + K/d1 L = ln( exp(b2c1d1) + exp(b2c2d1) ) yIII = yII - ln( exp(d2(b1c2 + L/d1)) + exp(d2yII) ) / d2 yII,0 = ln(exp(b2c1d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2(b1c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + Offset [web citation]
Richards With Offset 2D		y = 1.0 / (a + b * e^(c*x))^d + Offset
Sigmoid A Modified With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))^c + Offset
Sigmoid A With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) + Offset
Sigmoid B Modified With Offset 2D		y = a / (1.0 + exp(-(x-b)/c))^d + Offset
Sigmoid B With Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) + Offset
Weibull CDF Scaled With Offset 2D		y = Scale * (1.0 - exp(-(x/b)^a)) + Offset
Weibull CDF With Offset 2D		y = 1.0 - exp(-(x/b)^a) + Offset
Weibull PDF With Offset 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) + Offset



BET Sigmoidal A Plus Line 2D		y = x / (a + bx - (a+b)x²) y = y + (c * x) + d
BET Sigmoidal B Plus Line 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x²) y = y + (c * x) + d
Sigmoid A Plus Line 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y + (c * x) + d
Weibull CDF Plus Line 2D		y = 1.0 - exp(-(x/b)^a) y = y + (c * x) + d
Weibull PDF Plus Line 2D		y = (a/b) * (x/b)^(a-1.0) * exp(-(x/b)^a) y = y + (c * x) + d

2D Simple

Simple Equation 02 With Exponential Decay And Offset 2D		y = a/pow(x,-2.0) y = y / exp(x) + Offset
Simple Equation 03 With Exponential Decay And Offset 2D		y = a*pow(ln(x),b) y = y / exp(x) + Offset
Simple Equation 04 With Exponential Decay And Offset 2D		y = a*pow(x,3.0) y = y / exp(x) + Offset
Simple Equation 05 With Exponential Decay And Offset 2D		y = a*pow(x,4.0) y = y / exp(x) + Offset
Simple Equation 06 With Exponential Decay And Offset 2D		y = x/(a+bpow(x,2.0)) y = y / (c exp(x)) + Offset
Simple Equation 07 With Exponential Decay And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y / exp(x) + Offset
Simple Equation 08 With Exponential Decay And Offset 2D		y = apow(b,1.0/x)pow(x,c) y = y / exp(x) + Offset
Simple Equation 09 With Exponential Decay And Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = y / exp(x) + Offset
Simple Equation 10 With Exponential Decay And Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / exp(x) + Offset
Simple Equation 13 With Exponential Decay And Offset 2D		y = apow(x/b,c)exp(x/b) y = y / exp(x) + Offset
Simple Equation 14 With Exponential Decay And Offset 2D		y = apow(x,b+cx) y = y / exp(x) + Offset
Simple Equation 15 With Exponential Decay And Offset 2D		y = a*pow(x,b+c/x) y = y / exp(x) + Offset
Simple Equation 16 With Exponential Decay And Offset 2D		y = apow(x,b+cln(x)) y = y / exp(x) + Offset
Simple Equation 17 With Exponential Decay And Offset 2D		y = apow(x,bx+c*pow(x,2.0)) y = y / exp(x) + Offset
Simple Equation 18 With Exponential Decay And Offset 2D		y = aexp(bx+c*pow(x,0.5)) y = y / exp(x) + Offset
Simple Equation 19 With Exponential Decay And Offset 2D		y = aexp(b/x+cx) y = y / exp(x) + Offset
Simple Equation 20 With Exponential Decay And Offset 2D		y = (a+x)/(b+cx) y = y / (d exp(x)) + Offset
Simple Equation 21 With Exponential Decay And Offset 2D		y = (a+x)/(b+cpow(x,2.0)) y = y / (d exp(x)) + Offset
Simple Equation 22 With Exponential Decay And Offset 2D		y = a(exp(bx)-exp(c*x)) y = y / exp(x) + Offset
Simple Equation 23 With Exponential Decay And Offset 2D		y = aexp(bexp(c*x)) y = y / exp(x) + Offset
Simple Equation 24 With Exponential Decay And Offset 2D		y = a/(1.0 + b * exp(c*x)) y = y / exp(x) + Offset
Simple Equation 25 With Exponential Decay And Offset 2D		y = a/(b+pow(x,c)) y = y / exp(x) + Offset
Simple Equation 26 With Exponential Decay And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / exp(x) + Offset
Simple Equation 27 With Exponential Decay And Offset 2D		y = pow(a+bx,c) y = y / (d exp(x)) + Offset
Simple Equation 28 With Exponential Decay And Offset 2D		y = exp(a+b/x+cln(x)) y = y / (d exp(x)) + Offset
Simple Equation 29 With Exponential Decay And Offset 2D		y = aexp(bpow(x,c)) y = y / exp(x) + Offset
Simple Equation 30 With Exponential Decay And Offset 2D		y = apow(x,bpow(x,c)) y = y / exp(x) + Offset
Simple Equation 31 With Exponential Decay And Offset 2D		y = a*ln(x+b) y = y / exp(x) + Offset
Simple Equation 32 With Exponential Decay And Offset 2D		y = a/x+bpow(x,c) y = y / (d exp(x)) + Offset
Simple Equation 33 With Exponential Decay And Offset 2D		y = a/x+bexp(c/x) y = y / (d exp(x)) + Offset
Simple Equation 34 With Exponential Decay And Offset 2D		y = a/x+bexp(cx) y = y / (d * exp(x)) + Offset
Simple Equation 35 With Exponential Decay And Offset 2D		y = aexp(bx)/x y = y / exp(x) + Offset
Simple Equation 36 With Exponential Decay And Offset 2D		y = a*exp(b/x)/x y = y / exp(x) + Offset
Simple Equation 37 With Exponential Decay And Offset 2D		y = apow(x,b)ln(x) y = y / exp(x) + Offset
Simple Equation 38 With Exponential Decay And Offset 2D		y = a*pow(x,b)/ln(x) y = y / exp(x) + Offset
Simple Equation 39 With Exponential Decay And Offset 2D		y = apow(x,b)ln(x+c) y = y / exp(x) + Offset
Simple Equation 40 With Exponential Decay And Offset 2D		y = a*pow(ln(x+b),c) y = y / exp(x) + Offset
Simple Equation 41 With Exponential Decay And Offset 2D		y = apow(x,b/x)+cx y = y / exp(x) + Offset
Simple Equation 42 With Exponential Decay And Offset 2D		y = apow(x,b/x)+cln(x) y = y / (d * exp(x)) + Offset
Simple Reciprocal With Exponential Decay And Offset 2D		y = a / x y = y / exp(x) + Offset



Simple Equation 02 With Exponential Decay 2D		y = a/pow(x,-2.0) y = y / exp(x)
Simple Equation 03 With Exponential Decay 2D		y = a*pow(ln(x),b) y = y / exp(x)
Simple Equation 04 With Exponential Decay 2D		y = a*pow(x,3.0) y = y / exp(x)
Simple Equation 05 With Exponential Decay 2D		y = a*pow(x,4.0) y = y / exp(x)
Simple Equation 06 With Exponential Decay 2D		y = x/(a+bpow(x,2.0)) y = y / (c exp(x))
Simple Equation 07 With Exponential Decay 2D		y = a * pow(b,x) * pow(x,c) y = y / exp(x)
Simple Equation 08 With Exponential Decay 2D		y = apow(b,1.0/x)pow(x,c) y = y / exp(x)
Simple Equation 09 With Exponential Decay 2D		y = a*exp(pow(x-b,2.0)/c) y = y / exp(x)
Simple Equation 10 With Exponential Decay 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / exp(x)
Simple Equation 13 With Exponential Decay 2D		y = apow(x/b,c)exp(x/b) y = y / exp(x)
Simple Equation 14 With Exponential Decay 2D		y = apow(x,b+cx) y = y / exp(x)
Simple Equation 15 With Exponential Decay 2D		y = a*pow(x,b+c/x) y = y / exp(x)
Simple Equation 16 With Exponential Decay 2D		y = apow(x,b+cln(x)) y = y / exp(x)
Simple Equation 17 With Exponential Decay 2D		y = apow(x,bx+c*pow(x,2.0)) y = y / exp(x)
Simple Equation 18 With Exponential Decay 2D		y = aexp(bx+c*pow(x,0.5)) y = y / exp(x)
Simple Equation 19 With Exponential Decay 2D		y = aexp(b/x+cx) y = y / exp(x)
Simple Equation 20 With Exponential Decay 2D		y = (a+x)/(b+cx) y = y / (d exp(x))
Simple Equation 21 With Exponential Decay 2D		y = (a+x)/(b+cpow(x,2.0)) y = y / (d exp(x))
Simple Equation 22 With Exponential Decay 2D		y = a(exp(bx)-exp(c*x)) y = y / exp(x)
Simple Equation 23 With Exponential Decay 2D		y = aexp(bexp(c*x)) y = y / exp(x)
Simple Equation 24 With Exponential Decay 2D		y = a/(1.0 + b * exp(c*x)) y = y / exp(x)
Simple Equation 25 With Exponential Decay 2D		y = a/(b+pow(x,c)) y = y / exp(x)
Simple Equation 26 With Exponential Decay 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / exp(x)
Simple Equation 27 With Exponential Decay 2D		y = pow(a+bx,c) y = y / (d exp(x))
Simple Equation 28 With Exponential Decay 2D		y = exp(a+b/x+cln(x)) y = y / (d exp(x))
Simple Equation 29 With Exponential Decay 2D		y = aexp(bpow(x,c)) y = y / exp(x)
Simple Equation 30 With Exponential Decay 2D		y = apow(x,bpow(x,c)) y = y / exp(x)
Simple Equation 31 With Exponential Decay 2D		y = a*ln(x+b) y = y / exp(x)
Simple Equation 32 With Exponential Decay 2D		y = a/x+bpow(x,c) y = y / (d exp(x))
Simple Equation 33 With Exponential Decay 2D		y = a/x+bexp(c/x) y = y / (d exp(x))
Simple Equation 34 With Exponential Decay 2D		y = a/x+bexp(cx) y = y / (d * exp(x))
Simple Equation 35 With Exponential Decay 2D		y = aexp(bx)/x y = y / exp(x)
Simple Equation 36 With Exponential Decay 2D		y = a*exp(b/x)/x y = y / exp(x)
Simple Equation 37 With Exponential Decay 2D		y = apow(x,b)ln(x) y = y / exp(x)
Simple Equation 38 With Exponential Decay 2D		y = a*pow(x,b)/ln(x) y = y / exp(x)
Simple Equation 39 With Exponential Decay 2D		y = apow(x,b)ln(x+c) y = y / exp(x)
Simple Equation 40 With Exponential Decay 2D		y = a*pow(ln(x+b),c) y = y / exp(x)
Simple Equation 41 With Exponential Decay 2D		y = apow(x,b/x)+cx y = y / exp(x)
Simple Equation 42 With Exponential Decay 2D		y = apow(x,b/x)+cln(x) y = y / (d * exp(x))
Simple Reciprocal With Exponential Decay 2D		y = a / x y = y / exp(x)



Simple Equation 02 With Exponential Growth And Offset 2D		y = a/pow(x,-2.0) y = y * exp(x) + Offset
Simple Equation 03 With Exponential Growth And Offset 2D		y = apow(ln(x),b) y = y exp(x) + Offset
Simple Equation 04 With Exponential Growth And Offset 2D		y = apow(x,3.0) y = y exp(x) + Offset
Simple Equation 05 With Exponential Growth And Offset 2D		y = apow(x,4.0) y = y exp(x) + Offset
Simple Equation 06 With Exponential Growth And Offset 2D		y = x/(a+bpow(x,2.0)) y = y (c * exp(x)) + Offset
Simple Equation 07 With Exponential Growth And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y * exp(x) + Offset
Simple Equation 08 With Exponential Growth And Offset 2D		y = apow(b,1.0/x)pow(x,c) y = y * exp(x) + Offset
Simple Equation 09 With Exponential Growth And Offset 2D		y = aexp(pow(x-b,2.0)/c) y = y exp(x) + Offset
Simple Equation 10 With Exponential Growth And Offset 2D		y = aexp(pow(ln(x)-b,2.0)/c) y = y exp(x) + Offset
Simple Equation 13 With Exponential Growth And Offset 2D		y = apow(x/b,c)exp(x/b) y = y * exp(x) + Offset
Simple Equation 14 With Exponential Growth And Offset 2D		y = apow(x,b+cx) y = y * exp(x) + Offset
Simple Equation 15 With Exponential Growth And Offset 2D		y = apow(x,b+c/x) y = y exp(x) + Offset
Simple Equation 16 With Exponential Growth And Offset 2D		y = apow(x,b+cln(x)) y = y * exp(x) + Offset
Simple Equation 17 With Exponential Growth And Offset 2D		y = apow(x,bx+cpow(x,2.0)) y = y exp(x) + Offset
Simple Equation 18 With Exponential Growth And Offset 2D		y = aexp(bx+cpow(x,0.5)) y = y exp(x) + Offset
Simple Equation 19 With Exponential Growth And Offset 2D		y = aexp(b/x+cx) y = y * exp(x) + Offset
Simple Equation 20 With Exponential Growth And Offset 2D		y = (a+x)/(b+cx) y = y (d * exp(x)) + Offset
Simple Equation 21 With Exponential Growth And Offset 2D		y = (a+x)/(b+cpow(x,2.0)) y = y (d * exp(x)) + Offset
Simple Equation 22 With Exponential Growth And Offset 2D		y = a(exp(bx)-exp(cx)) y = y exp(x) + Offset
Simple Equation 23 With Exponential Growth And Offset 2D		y = aexp(bexp(cx)) y = y exp(x) + Offset
Simple Equation 24 With Exponential Growth And Offset 2D		y = a/(1.0 + b * exp(cx)) y = y exp(x) + Offset
Simple Equation 25 With Exponential Growth And Offset 2D		y = a/(b+pow(x,c)) y = y * exp(x) + Offset
Simple Equation 26 With Exponential Growth And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * exp(x) + Offset
Simple Equation 27 With Exponential Growth And Offset 2D		y = pow(a+bx,c) y = y (d * exp(x)) + Offset
Simple Equation 28 With Exponential Growth And Offset 2D		y = exp(a+b/x+cln(x)) y = y (d * exp(x)) + Offset
Simple Equation 29 With Exponential Growth And Offset 2D		y = aexp(bpow(x,c)) y = y * exp(x) + Offset
Simple Equation 30 With Exponential Growth And Offset 2D		y = apow(x,bpow(x,c)) y = y * exp(x) + Offset
Simple Equation 31 With Exponential Growth And Offset 2D		y = aln(x+b) y = y exp(x) + Offset
Simple Equation 32 With Exponential Growth And Offset 2D		y = a/x+bpow(x,c) y = y (d * exp(x)) + Offset
Simple Equation 33 With Exponential Growth And Offset 2D		y = a/x+bexp(c/x) y = y (d * exp(x)) + Offset
Simple Equation 34 With Exponential Growth And Offset 2D		y = a/x+bexp(cx) y = y * (d * exp(x)) + Offset
Simple Equation 35 With Exponential Growth And Offset 2D		y = aexp(bx)/x y = y * exp(x) + Offset
Simple Equation 36 With Exponential Growth And Offset 2D		y = aexp(b/x)/x y = y exp(x) + Offset
Simple Equation 37 With Exponential Growth And Offset 2D		y = apow(x,b)ln(x) y = y * exp(x) + Offset
Simple Equation 38 With Exponential Growth And Offset 2D		y = apow(x,b)/ln(x) y = y exp(x) + Offset
Simple Equation 39 With Exponential Growth And Offset 2D		y = apow(x,b)ln(x+c) y = y * exp(x) + Offset
Simple Equation 40 With Exponential Growth And Offset 2D		y = apow(ln(x+b),c) y = y exp(x) + Offset
Simple Equation 41 With Exponential Growth And Offset 2D		y = apow(x,b/x)+cx y = y * exp(x) + Offset
Simple Equation 42 With Exponential Growth And Offset 2D		y = apow(x,b/x)+cln(x) y = y * (d * exp(x)) + Offset
Simple Reciprocal With Exponential Growth And Offset 2D		y = a / x y = y * exp(x) + Offset



Simple Equation 02 With Exponential Growth 2D		y = a/pow(x,-2.0) y = y * exp(x)
Simple Equation 03 With Exponential Growth 2D		y = apow(ln(x),b) y = y exp(x)
Simple Equation 04 With Exponential Growth 2D		y = apow(x,3.0) y = y exp(x)
Simple Equation 05 With Exponential Growth 2D		y = apow(x,4.0) y = y exp(x)
Simple Equation 06 With Exponential Growth 2D		y = x/(a+bpow(x,2.0)) y = y (c * exp(x))
Simple Equation 07 With Exponential Growth 2D		y = a * pow(b,x) * pow(x,c) y = y * exp(x)
Simple Equation 08 With Exponential Growth 2D		y = apow(b,1.0/x)pow(x,c) y = y * exp(x)
Simple Equation 09 With Exponential Growth 2D		y = aexp(pow(x-b,2.0)/c) y = y exp(x)
Simple Equation 10 With Exponential Growth 2D		y = aexp(pow(ln(x)-b,2.0)/c) y = y exp(x)
Simple Equation 13 With Exponential Growth 2D		y = apow(x/b,c)exp(x/b) y = y * exp(x)
Simple Equation 14 With Exponential Growth 2D		y = apow(x,b+cx) y = y * exp(x)
Simple Equation 15 With Exponential Growth 2D		y = apow(x,b+c/x) y = y exp(x)
Simple Equation 16 With Exponential Growth 2D		y = apow(x,b+cln(x)) y = y * exp(x)
Simple Equation 17 With Exponential Growth 2D		y = apow(x,bx+cpow(x,2.0)) y = y exp(x)
Simple Equation 18 With Exponential Growth 2D		y = aexp(bx+cpow(x,0.5)) y = y exp(x)
Simple Equation 19 With Exponential Growth 2D		y = aexp(b/x+cx) y = y * exp(x)
Simple Equation 20 With Exponential Growth 2D		y = (a+x)/(b+cx) y = y (d * exp(x))
Simple Equation 21 With Exponential Growth 2D		y = (a+x)/(b+cpow(x,2.0)) y = y (d * exp(x))
Simple Equation 22 With Exponential Growth 2D		y = a(exp(bx)-exp(cx)) y = y exp(x)
Simple Equation 23 With Exponential Growth 2D		y = aexp(bexp(cx)) y = y exp(x)
Simple Equation 24 With Exponential Growth 2D		y = a/(1.0 + b * exp(cx)) y = y exp(x)
Simple Equation 25 With Exponential Growth 2D		y = a/(b+pow(x,c)) y = y * exp(x)
Simple Equation 26 With Exponential Growth 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * exp(x)
Simple Equation 27 With Exponential Growth 2D		y = pow(a+bx,c) y = y (d * exp(x))
Simple Equation 28 With Exponential Growth 2D		y = exp(a+b/x+cln(x)) y = y (d * exp(x))
Simple Equation 29 With Exponential Growth 2D		y = aexp(bpow(x,c)) y = y * exp(x)
Simple Equation 30 With Exponential Growth 2D		y = apow(x,bpow(x,c)) y = y * exp(x)
Simple Equation 31 With Exponential Growth 2D		y = aln(x+b) y = y exp(x)
Simple Equation 32 With Exponential Growth 2D		y = a/x+bpow(x,c) y = y (d * exp(x))
Simple Equation 33 With Exponential Growth 2D		y = a/x+bexp(c/x) y = y (d * exp(x))
Simple Equation 34 With Exponential Growth 2D		y = a/x+bexp(cx) y = y * (d * exp(x))
Simple Equation 35 With Exponential Growth 2D		y = aexp(bx)/x y = y * exp(x)
Simple Equation 36 With Exponential Growth 2D		y = aexp(b/x)/x y = y exp(x)
Simple Equation 37 With Exponential Growth 2D		y = apow(x,b)ln(x) y = y * exp(x)
Simple Equation 38 With Exponential Growth 2D		y = apow(x,b)/ln(x) y = y exp(x)
Simple Equation 39 With Exponential Growth 2D		y = apow(x,b)ln(x+c) y = y * exp(x)
Simple Equation 40 With Exponential Growth 2D		y = apow(ln(x+b),c) y = y exp(x)
Simple Equation 41 With Exponential Growth 2D		y = apow(x,b/x)+cx y = y * exp(x)
Simple Equation 42 With Exponential Growth 2D		y = apow(x,b/x)+cln(x) y = y * (d * exp(x))
Simple Reciprocal With Exponential Growth 2D		y = a / x y = y * exp(x)



Inverse Simple Equation 03 2D		y = a*pow(ln(x),b) y = x / y
Inverse Simple Equation 07 2D		y = a * pow(b,x) * pow(x,c) y = x / y
Inverse Simple Equation 08 2D		y = apow(b,1.0/x)pow(x,c) y = x / y
Inverse Simple Equation 09 2D		y = a*exp(pow(x-b,2.0)/c) y = x / y
Inverse Simple Equation 10 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = x / y
Inverse Simple Equation 13 2D		y = apow(x/b,c)exp(x/b) y = x / y
Inverse Simple Equation 15 2D		y = a*pow(x,b+c/x) y = x / y
Inverse Simple Equation 16 2D		y = apow(x,b+cln(x)) y = x / y
Inverse Simple Equation 17 2D		y = apow(x,bx+c*pow(x,2.0)) y = x / y
Inverse Simple Equation 18 2D		y = aexp(bx+c*pow(x,0.5)) y = x / y
Inverse Simple Equation 19 2D		y = aexp(b/x+cx) y = x / y
Inverse Simple Equation 20 2D		y = (a+x)/(b+c*x) y = x / y
Inverse Simple Equation 21 2D		y = (a+x)/(b+c*pow(x,2.0)) y = x / y
Inverse Simple Equation 22 2D		y = a(exp(bx)-exp(c*x)) y = x / y
Inverse Simple Equation 23 2D		y = aexp(bexp(c*x)) y = x / y
Inverse Simple Equation 24 2D		y = a/(1.0 + b * exp(c*x)) y = x / y
Inverse Simple Equation 25 2D		y = a/(b+pow(x,c)) y = x / y
Inverse Simple Equation 26 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = x / y
Inverse Simple Equation 27 2D		y = pow(a+b*x,c) y = x / y
Inverse Simple Equation 28 2D		y = exp(a+b/x+c*ln(x)) y = x / y
Inverse Simple Equation 29 2D		y = aexp(bpow(x,c)) y = x / y
Inverse Simple Equation 30 2D		y = apow(x,bpow(x,c)) y = x / y
Inverse Simple Equation 31 2D		y = a*ln(x+b) y = x / y
Inverse Simple Equation 32 2D		y = a/x+b*pow(x,c) y = x / y
Inverse Simple Equation 33 2D		y = a/x+b*exp(c/x) y = x / y
Inverse Simple Equation 34 2D		y = a/x+bexp(cx) y = x / y
Inverse Simple Equation 35 2D		y = aexp(bx)/x y = x / y
Inverse Simple Equation 38 2D		y = a*pow(x,b)/ln(x) y = x / y
Inverse Simple Equation 39 2D		y = apow(x,b)ln(x+c) y = x / y
Inverse Simple Equation 40 2D		y = a*pow(ln(x+b),c) y = x / y
Inverse Simple Equation 41 2D		y = apow(x,b/x)+cx y = x / y
Inverse Simple Equation 42 2D		y = apow(x,b/x)+cln(x) y = x / y



Inverse Simple Equation 03 With Offset 2D		y = a*pow(ln(x),b) y = x / y + Offset
Inverse Simple Equation 07 With Offset 2D		y = a * pow(b,x) * pow(x,c) y = x / y + Offset
Inverse Simple Equation 08 With Offset 2D		y = apow(b,1.0/x)pow(x,c) y = x / y + Offset
Inverse Simple Equation 09 With Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = x / y + Offset
Inverse Simple Equation 10 With Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = x / y + Offset
Inverse Simple Equation 13 With Offset 2D		y = apow(x/b,c)exp(x/b) y = x / y + Offset
Inverse Simple Equation 15 With Offset 2D		y = a*pow(x,b+c/x) y = x / y + Offset
Inverse Simple Equation 16 With Offset 2D		y = apow(x,b+cln(x)) y = x / y + Offset
Inverse Simple Equation 17 With Offset 2D		y = apow(x,bx+c*pow(x,2.0)) y = x / y + Offset
Inverse Simple Equation 18 With Offset 2D		y = aexp(bx+c*pow(x,0.5)) y = x / y + Offset
Inverse Simple Equation 19 With Offset 2D		y = aexp(b/x+cx) y = x / y + Offset
Inverse Simple Equation 20 With Offset 2D		y = (a+x)/(b+c*x) y = x / y + Offset
Inverse Simple Equation 21 With Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = x / y + Offset
Inverse Simple Equation 22 With Offset 2D		y = a(exp(bx)-exp(c*x)) y = x / y + Offset
Inverse Simple Equation 23 With Offset 2D		y = aexp(bexp(c*x)) y = x / y + Offset
Inverse Simple Equation 24 With Offset 2D		y = a/(1.0 + b * exp(c*x)) y = x / y + Offset
Inverse Simple Equation 25 With Offset 2D		y = a/(b+pow(x,c)) y = x / y + Offset
Inverse Simple Equation 26 With Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = x / y + Offset
Inverse Simple Equation 27 With Offset 2D		y = pow(a+b*x,c) y = x / y + Offset
Inverse Simple Equation 28 With Offset 2D		y = exp(a+b/x+c*ln(x)) y = x / y + Offset
Inverse Simple Equation 29 With Offset 2D		y = aexp(bpow(x,c)) y = x / y + Offset
Inverse Simple Equation 30 With Offset 2D		y = apow(x,bpow(x,c)) y = x / y + Offset
Inverse Simple Equation 31 With Offset 2D		y = a*ln(x+b) y = x / y + Offset
Inverse Simple Equation 32 With Offset 2D		y = a/x+b*pow(x,c) y = x / y + Offset
Inverse Simple Equation 33 With Offset 2D		y = a/x+b*exp(c/x) y = x / y + Offset
Inverse Simple Equation 34 With Offset 2D		y = a/x+bexp(cx) y = x / y + Offset
Inverse Simple Equation 35 With Offset 2D		y = aexp(bx)/x y = x / y + Offset
Inverse Simple Equation 38 With Offset 2D		y = a*pow(x,b)/ln(x) y = x / y + Offset
Inverse Simple Equation 39 With Offset 2D		y = apow(x,b)ln(x+c) y = x / y + Offset
Inverse Simple Equation 40 With Offset 2D		y = a*pow(ln(x+b),c) y = x / y + Offset
Inverse Simple Equation 41 With Offset 2D		y = apow(x,b/x)+cx y = x / y + Offset
Inverse Simple Equation 42 With Offset 2D		y = apow(x,b/x)+cln(x) y = x / y + Offset



Simple Equation 02 With Linear Decay And Offset 2D		y = a/pow(x,-2.0) y = y / x + Offset
Simple Equation 03 With Linear Decay And Offset 2D		y = a*pow(ln(x),b) y = y / x + Offset
Simple Equation 04 With Linear Decay And Offset 2D		y = a*pow(x,3.0) y = y / x + Offset
Simple Equation 05 With Linear Decay And Offset 2D		y = a*pow(x,4.0) y = y / x + Offset
Simple Equation 06 With Linear Decay And Offset 2D		y = x/(a+bpow(x,2.0)) y = y / (c x) + Offset
Simple Equation 07 With Linear Decay And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y / x + Offset
Simple Equation 08 With Linear Decay And Offset 2D		y = apow(b,1.0/x)pow(x,c) y = y / x + Offset
Simple Equation 09 With Linear Decay And Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = y / x + Offset
Simple Equation 10 With Linear Decay And Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / x + Offset
Simple Equation 13 With Linear Decay And Offset 2D		y = apow(x/b,c)exp(x/b) y = y / x + Offset
Simple Equation 14 With Linear Decay And Offset 2D		y = apow(x,b+cx) y = y / x + Offset
Simple Equation 15 With Linear Decay And Offset 2D		y = a*pow(x,b+c/x) y = y / x + Offset
Simple Equation 16 With Linear Decay And Offset 2D		y = apow(x,b+cln(x)) y = y / x + Offset
Simple Equation 17 With Linear Decay And Offset 2D		y = apow(x,bx+c*pow(x,2.0)) y = y / x + Offset
Simple Equation 18 With Linear Decay And Offset 2D		y = aexp(bx+c*pow(x,0.5)) y = y / x + Offset
Simple Equation 19 With Linear Decay And Offset 2D		y = aexp(b/x+cx) y = y / x + Offset
Simple Equation 20 With Linear Decay And Offset 2D		y = (a+x)/(b+cx) y = y / (d x) + Offset
Simple Equation 21 With Linear Decay And Offset 2D		y = (a+x)/(b+cpow(x,2.0)) y = y / (d x) + Offset
Simple Equation 22 With Linear Decay And Offset 2D		y = a(exp(bx)-exp(c*x)) y = y / x + Offset
Simple Equation 23 With Linear Decay And Offset 2D		y = aexp(bexp(c*x)) y = y / x + Offset
Simple Equation 24 With Linear Decay And Offset 2D		y = a/(1.0 + b * exp(c*x)) y = y / x + Offset
Simple Equation 25 With Linear Decay And Offset 2D		y = a/(b+pow(x,c)) y = y / x + Offset
Simple Equation 26 With Linear Decay And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / x + Offset
Simple Equation 27 With Linear Decay And Offset 2D		y = pow(a+bx,c) y = y / (d x) + Offset
Simple Equation 28 With Linear Decay And Offset 2D		y = exp(a+b/x+cln(x)) y = y / (d x) + Offset
Simple Equation 29 With Linear Decay And Offset 2D		y = aexp(bpow(x,c)) y = y / x + Offset
Simple Equation 30 With Linear Decay And Offset 2D		y = apow(x,bpow(x,c)) y = y / x + Offset
Simple Equation 31 With Linear Decay And Offset 2D		y = a*ln(x+b) y = y / x + Offset
Simple Equation 32 With Linear Decay And Offset 2D		y = a/x+bpow(x,c) y = y / (d x) + Offset
Simple Equation 33 With Linear Decay And Offset 2D		y = a/x+bexp(c/x) y = y / (d x) + Offset
Simple Equation 34 With Linear Decay And Offset 2D		y = a/x+bexp(cx) y = y / (d * x) + Offset
Simple Equation 35 With Linear Decay And Offset 2D		y = aexp(bx)/x y = y / x + Offset
Simple Equation 36 With Linear Decay And Offset 2D		y = a*exp(b/x)/x y = y / x + Offset
Simple Equation 37 With Linear Decay And Offset 2D		y = apow(x,b)ln(x) y = y / x + Offset
Simple Equation 38 With Linear Decay And Offset 2D		y = a*pow(x,b)/ln(x) y = y / x + Offset
Simple Equation 39 With Linear Decay And Offset 2D		y = apow(x,b)ln(x+c) y = y / x + Offset
Simple Equation 40 With Linear Decay And Offset 2D		y = a*pow(ln(x+b),c) y = y / x + Offset
Simple Equation 41 With Linear Decay And Offset 2D		y = apow(x,b/x)+cx y = y / x + Offset
Simple Equation 42 With Linear Decay And Offset 2D		y = apow(x,b/x)+cln(x) y = y / (d * x) + Offset
Simple Reciprocal With Linear Decay And Offset 2D		y = a / x y = y / x + Offset



Simple Equation 02 With Linear Decay 2D		y = a/pow(x,-2.0) y = y / x
Simple Equation 03 With Linear Decay 2D		y = a*pow(ln(x),b) y = y / x
Simple Equation 04 With Linear Decay 2D		y = a*pow(x,3.0) y = y / x
Simple Equation 05 With Linear Decay 2D		y = a*pow(x,4.0) y = y / x
Simple Equation 06 With Linear Decay 2D		y = x/(a+bpow(x,2.0)) y = y / (c x)
Simple Equation 07 With Linear Decay 2D		y = a * pow(b,x) * pow(x,c) y = y / x
Simple Equation 08 With Linear Decay 2D		y = apow(b,1.0/x)pow(x,c) y = y / x
Simple Equation 09 With Linear Decay 2D		y = a*exp(pow(x-b,2.0)/c) y = y / x
Simple Equation 10 With Linear Decay 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / x
Simple Equation 13 With Linear Decay 2D		y = apow(x/b,c)exp(x/b) y = y / x
Simple Equation 14 With Linear Decay 2D		y = apow(x,b+cx) y = y / x
Simple Equation 15 With Linear Decay 2D		y = a*pow(x,b+c/x) y = y / x
Simple Equation 16 With Linear Decay 2D		y = apow(x,b+cln(x)) y = y / x
Simple Equation 17 With Linear Decay 2D		y = apow(x,bx+c*pow(x,2.0)) y = y / x
Simple Equation 18 With Linear Decay 2D		y = aexp(bx+c*pow(x,0.5)) y = y / x
Simple Equation 19 With Linear Decay 2D		y = aexp(b/x+cx) y = y / x
Simple Equation 20 With Linear Decay 2D		y = (a+x)/(b+cx) y = y / (d x)
Simple Equation 21 With Linear Decay 2D		y = (a+x)/(b+cpow(x,2.0)) y = y / (d x)
Simple Equation 22 With Linear Decay 2D		y = a(exp(bx)-exp(c*x)) y = y / x
Simple Equation 23 With Linear Decay 2D		y = aexp(bexp(c*x)) y = y / x
Simple Equation 24 With Linear Decay 2D		y = a/(1.0 + b * exp(c*x)) y = y / x
Simple Equation 25 With Linear Decay 2D		y = a/(b+pow(x,c)) y = y / x
Simple Equation 26 With Linear Decay 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / x
Simple Equation 27 With Linear Decay 2D		y = pow(a+bx,c) y = y / (d x)
Simple Equation 28 With Linear Decay 2D		y = exp(a+b/x+cln(x)) y = y / (d x)
Simple Equation 29 With Linear Decay 2D		y = aexp(bpow(x,c)) y = y / x
Simple Equation 30 With Linear Decay 2D		y = apow(x,bpow(x,c)) y = y / x
Simple Equation 31 With Linear Decay 2D		y = a*ln(x+b) y = y / x
Simple Equation 32 With Linear Decay 2D		y = a/x+bpow(x,c) y = y / (d x)
Simple Equation 33 With Linear Decay 2D		y = a/x+bexp(c/x) y = y / (d x)
Simple Equation 34 With Linear Decay 2D		y = a/x+bexp(cx) y = y / (d * x)
Simple Equation 35 With Linear Decay 2D		y = aexp(bx)/x y = y / x
Simple Equation 36 With Linear Decay 2D		y = a*exp(b/x)/x y = y / x
Simple Equation 37 With Linear Decay 2D		y = apow(x,b)ln(x) y = y / x
Simple Equation 38 With Linear Decay 2D		y = a*pow(x,b)/ln(x) y = y / x
Simple Equation 39 With Linear Decay 2D		y = apow(x,b)ln(x+c) y = y / x
Simple Equation 40 With Linear Decay 2D		y = a*pow(ln(x+b),c) y = y / x
Simple Equation 41 With Linear Decay 2D		y = apow(x,b/x)+cx y = y / x
Simple Equation 42 With Linear Decay 2D		y = apow(x,b/x)+cln(x) y = y / (d * x)
Simple Reciprocal With Linear Decay 2D		y = a / x y = y / x



Simple Equation 02 With Linear Growth And Offset 2D		y = a/pow(x,-2.0) y = y * x + Offset
Simple Equation 03 With Linear Growth And Offset 2D		y = apow(ln(x),b) y = y x + Offset
Simple Equation 04 With Linear Growth And Offset 2D		y = apow(x,3.0) y = y x + Offset
Simple Equation 05 With Linear Growth And Offset 2D		y = apow(x,4.0) y = y x + Offset
Simple Equation 06 With Linear Growth And Offset 2D		y = x/(a+bpow(x,2.0)) y = y (c * x) + Offset
Simple Equation 07 With Linear Growth And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y * x + Offset
Simple Equation 08 With Linear Growth And Offset 2D		y = apow(b,1.0/x)pow(x,c) y = y * x + Offset
Simple Equation 09 With Linear Growth And Offset 2D		y = aexp(pow(x-b,2.0)/c) y = y x + Offset
Simple Equation 10 With Linear Growth And Offset 2D		y = aexp(pow(ln(x)-b,2.0)/c) y = y x + Offset
Simple Equation 13 With Linear Growth And Offset 2D		y = apow(x/b,c)exp(x/b) y = y * x + Offset
Simple Equation 14 With Linear Growth And Offset 2D		y = apow(x,b+cx) y = y * x + Offset
Simple Equation 15 With Linear Growth And Offset 2D		y = apow(x,b+c/x) y = y x + Offset
Simple Equation 16 With Linear Growth And Offset 2D		y = apow(x,b+cln(x)) y = y * x + Offset
Simple Equation 17 With Linear Growth And Offset 2D		y = apow(x,bx+cpow(x,2.0)) y = y x + Offset
Simple Equation 18 With Linear Growth And Offset 2D		y = aexp(bx+cpow(x,0.5)) y = y x + Offset
Simple Equation 19 With Linear Growth And Offset 2D		y = aexp(b/x+cx) y = y * x + Offset
Simple Equation 20 With Linear Growth And Offset 2D		y = (a+x)/(b+cx) y = y (d * x) + Offset
Simple Equation 21 With Linear Growth And Offset 2D		y = (a+x)/(b+cpow(x,2.0)) y = y (d * x) + Offset
Simple Equation 22 With Linear Growth And Offset 2D		y = a(exp(bx)-exp(cx)) y = y x + Offset
Simple Equation 23 With Linear Growth And Offset 2D		y = aexp(bexp(cx)) y = y x + Offset
Simple Equation 24 With Linear Growth And Offset 2D		y = a/(1.0 + b * exp(cx)) y = y x + Offset
Simple Equation 25 With Linear Growth And Offset 2D		y = a/(b+pow(x,c)) y = y * x + Offset
Simple Equation 26 With Linear Growth And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * x + Offset
Simple Equation 27 With Linear Growth And Offset 2D		y = pow(a+bx,c) y = y (d * x) + Offset
Simple Equation 28 With Linear Growth And Offset 2D		y = exp(a+b/x+cln(x)) y = y (d * x) + Offset
Simple Equation 29 With Linear Growth And Offset 2D		y = aexp(bpow(x,c)) y = y * x + Offset
Simple Equation 30 With Linear Growth And Offset 2D		y = apow(x,bpow(x,c)) y = y * x + Offset
Simple Equation 31 With Linear Growth And Offset 2D		y = aln(x+b) y = y x + Offset
Simple Equation 32 With Linear Growth And Offset 2D		y = a/x+bpow(x,c) y = y (d * x) + Offset
Simple Equation 33 With Linear Growth And Offset 2D		y = a/x+bexp(c/x) y = y (d * x) + Offset
Simple Equation 34 With Linear Growth And Offset 2D		y = a/x+bexp(cx) y = y * (d * x) + Offset
Simple Equation 35 With Linear Growth And Offset 2D		y = aexp(bx)/x y = y * x + Offset
Simple Equation 36 With Linear Growth And Offset 2D		y = aexp(b/x)/x y = y x + Offset
Simple Equation 37 With Linear Growth And Offset 2D		y = apow(x,b)ln(x) y = y * x + Offset
Simple Equation 38 With Linear Growth And Offset 2D		y = apow(x,b)/ln(x) y = y x + Offset
Simple Equation 39 With Linear Growth And Offset 2D		y = apow(x,b)ln(x+c) y = y * x + Offset
Simple Equation 40 With Linear Growth And Offset 2D		y = apow(ln(x+b),c) y = y x + Offset
Simple Equation 41 With Linear Growth And Offset 2D		y = apow(x,b/x)+cx y = y * x + Offset
Simple Equation 42 With Linear Growth And Offset 2D		y = apow(x,b/x)+cln(x) y = y * (d * x) + Offset
Simple Reciprocal With Linear Growth And Offset 2D		y = a / x y = y * x + Offset



Simple Equation 02 With Linear Growth 2D		y = a/pow(x,-2.0) y = y * x
Simple Equation 03 With Linear Growth 2D		y = apow(ln(x),b) y = y x
Simple Equation 04 With Linear Growth 2D		y = apow(x,3.0) y = y x
Simple Equation 05 With Linear Growth 2D		y = apow(x,4.0) y = y x
Simple Equation 06 With Linear Growth 2D		y = x/(a+bpow(x,2.0)) y = y (c * x)
Simple Equation 07 With Linear Growth 2D		y = a * pow(b,x) * pow(x,c) y = y * x
Simple Equation 08 With Linear Growth 2D		y = apow(b,1.0/x)pow(x,c) y = y * x
Simple Equation 09 With Linear Growth 2D		y = aexp(pow(x-b,2.0)/c) y = y x
Simple Equation 10 With Linear Growth 2D		y = aexp(pow(ln(x)-b,2.0)/c) y = y x
Simple Equation 13 With Linear Growth 2D		y = apow(x/b,c)exp(x/b) y = y * x
Simple Equation 14 With Linear Growth 2D		y = apow(x,b+cx) y = y * x
Simple Equation 15 With Linear Growth 2D		y = apow(x,b+c/x) y = y x
Simple Equation 16 With Linear Growth 2D		y = apow(x,b+cln(x)) y = y * x
Simple Equation 17 With Linear Growth 2D		y = apow(x,bx+cpow(x,2.0)) y = y x
Simple Equation 18 With Linear Growth 2D		y = aexp(bx+cpow(x,0.5)) y = y x
Simple Equation 19 With Linear Growth 2D		y = aexp(b/x+cx) y = y * x
Simple Equation 20 With Linear Growth 2D		y = (a+x)/(b+cx) y = y (d * x)
Simple Equation 21 With Linear Growth 2D		y = (a+x)/(b+cpow(x,2.0)) y = y (d * x)
Simple Equation 22 With Linear Growth 2D		y = a(exp(bx)-exp(cx)) y = y x
Simple Equation 23 With Linear Growth 2D		y = aexp(bexp(cx)) y = y x
Simple Equation 24 With Linear Growth 2D		y = a/(1.0 + b * exp(cx)) y = y x
Simple Equation 25 With Linear Growth 2D		y = a/(b+pow(x,c)) y = y * x
Simple Equation 26 With Linear Growth 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * x
Simple Equation 27 With Linear Growth 2D		y = pow(a+bx,c) y = y (d * x)
Simple Equation 28 With Linear Growth 2D		y = exp(a+b/x+cln(x)) y = y (d * x)
Simple Equation 29 With Linear Growth 2D		y = aexp(bpow(x,c)) y = y * x
Simple Equation 30 With Linear Growth 2D		y = apow(x,bpow(x,c)) y = y * x
Simple Equation 31 With Linear Growth 2D		y = aln(x+b) y = y x
Simple Equation 32 With Linear Growth 2D		y = a/x+bpow(x,c) y = y (d * x)
Simple Equation 33 With Linear Growth 2D		y = a/x+bexp(c/x) y = y (d * x)
Simple Equation 34 With Linear Growth 2D		y = a/x+bexp(cx) y = y * (d * x)
Simple Equation 35 With Linear Growth 2D		y = aexp(bx)/x y = y * x
Simple Equation 36 With Linear Growth 2D		y = aexp(b/x)/x y = y x
Simple Equation 37 With Linear Growth 2D		y = apow(x,b)ln(x) y = y * x
Simple Equation 38 With Linear Growth 2D		y = apow(x,b)/ln(x) y = y x
Simple Equation 39 With Linear Growth 2D		y = apow(x,b)ln(x+c) y = y * x
Simple Equation 40 With Linear Growth 2D		y = apow(ln(x+b),c) y = y x
Simple Equation 41 With Linear Growth 2D		y = apow(x,b/x)+cx y = y * x
Simple Equation 42 With Linear Growth 2D		y = apow(x,b/x)+cln(x) y = y * (d * x)
Simple Reciprocal With Linear Growth 2D		y = a / x y = y * x



Reciprocal Simple Equation 02 2D		y = a/pow(x,-2.0) y = 1.0 / y
Reciprocal Simple Equation 03 2D		y = a*pow(ln(x),b) y = 1.0 / y
Reciprocal Simple Equation 04 2D		y = a*pow(x,3.0) y = 1.0 / y
Reciprocal Simple Equation 05 2D		y = a*pow(x,4.0) y = 1.0 / y
Reciprocal Simple Equation 06 2D		y = x/(a+b*pow(x,2.0)) y = 1.0 / y
Reciprocal Simple Equation 07 2D		y = a * pow(b,x) * pow(x,c) y = 1.0 / y
Reciprocal Simple Equation 08 2D		y = apow(b,1.0/x)pow(x,c) y = 1.0 / y
Reciprocal Simple Equation 09 2D		y = a*exp(pow(x-b,2.0)/c) y = 1.0 / y
Reciprocal Simple Equation 10 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = 1.0 / y
Reciprocal Simple Equation 13 2D		y = apow(x/b,c)exp(x/b) y = 1.0 / y
Reciprocal Simple Equation 14 2D		y = apow(x,b+cx) y = 1.0 / y
Reciprocal Simple Equation 15 2D		y = a*pow(x,b+c/x) y = 1.0 / y
Reciprocal Simple Equation 16 2D		y = apow(x,b+cln(x)) y = 1.0 / y
Reciprocal Simple Equation 17 2D		y = apow(x,bx+c*pow(x,2.0)) y = 1.0 / y
Reciprocal Simple Equation 18 2D		y = aexp(bx+c*pow(x,0.5)) y = 1.0 / y
Reciprocal Simple Equation 19 2D		y = aexp(b/x+cx) y = 1.0 / y
Reciprocal Simple Equation 20 2D		y = (a+x)/(b+c*x) y = 1.0 / y
Reciprocal Simple Equation 21 2D		y = (a+x)/(b+c*pow(x,2.0)) y = 1.0 / y
Reciprocal Simple Equation 22 2D		y = a(exp(bx)-exp(c*x)) y = 1.0 / y
Reciprocal Simple Equation 23 2D		y = aexp(bexp(c*x)) y = 1.0 / y
Reciprocal Simple Equation 24 2D		y = a/(1.0 + b * exp(c*x)) y = 1.0 / y
Reciprocal Simple Equation 25 2D		y = a/(b+pow(x,c)) y = 1.0 / y
Reciprocal Simple Equation 26 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = 1.0 / y
Reciprocal Simple Equation 27 2D		y = pow(a+b*x,c) y = 1.0 / y
Reciprocal Simple Equation 28 2D		y = exp(a+b/x+c*ln(x)) y = 1.0 / y
Reciprocal Simple Equation 29 2D		y = aexp(bpow(x,c)) y = 1.0 / y
Reciprocal Simple Equation 30 2D		y = apow(x,bpow(x,c)) y = 1.0 / y
Reciprocal Simple Equation 31 2D		y = a*ln(x+b) y = 1.0 / y
Reciprocal Simple Equation 32 2D		y = a/x+b*pow(x,c) y = 1.0 / y
Reciprocal Simple Equation 33 2D		y = a/x+b*exp(c/x) y = 1.0 / y
Reciprocal Simple Equation 34 2D		y = a/x+bexp(cx) y = 1.0 / y
Reciprocal Simple Equation 35 2D		y = aexp(bx)/x y = 1.0 / y
Reciprocal Simple Equation 36 2D		y = a*exp(b/x)/x y = 1.0 / y
Reciprocal Simple Equation 37 2D		y = apow(x,b)ln(x) y = 1.0 / y
Reciprocal Simple Equation 38 2D		y = a*pow(x,b)/ln(x) y = 1.0 / y
Reciprocal Simple Equation 39 2D		y = apow(x,b)ln(x+c) y = 1.0 / y
Reciprocal Simple Equation 40 2D		y = a*pow(ln(x+b),c) y = 1.0 / y
Reciprocal Simple Equation 41 2D		y = apow(x,b/x)+cx y = 1.0 / y
Reciprocal Simple Equation 42 2D		y = apow(x,b/x)+cln(x) y = 1.0 / y



Reciprocal Simple Equation 02 With Offset 2D		y = a/pow(x,-2.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 03 With Offset 2D		y = a*pow(ln(x),b) y = 1.0 / y + Offset
Reciprocal Simple Equation 04 With Offset 2D		y = a*pow(x,3.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 05 With Offset 2D		y = a*pow(x,4.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 06 With Offset 2D		y = x/(a+b*pow(x,2.0)) y = 1.0 / y + Offset
Reciprocal Simple Equation 07 With Offset 2D		y = a * pow(b,x) * pow(x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 08 With Offset 2D		y = apow(b,1.0/x)pow(x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 09 With Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = 1.0 / y + Offset
Reciprocal Simple Equation 10 With Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = 1.0 / y + Offset
Reciprocal Simple Equation 13 With Offset 2D		y = apow(x/b,c)exp(x/b) y = 1.0 / y + Offset
Reciprocal Simple Equation 14 With Offset 2D		y = apow(x,b+cx) y = 1.0 / y + Offset
Reciprocal Simple Equation 15 With Offset 2D		y = a*pow(x,b+c/x) y = 1.0 / y + Offset
Reciprocal Simple Equation 16 With Offset 2D		y = apow(x,b+cln(x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 17 With Offset 2D		y = apow(x,bx+c*pow(x,2.0)) y = 1.0 / y + Offset
Reciprocal Simple Equation 18 With Offset 2D		y = aexp(bx+c*pow(x,0.5)) y = 1.0 / y + Offset
Reciprocal Simple Equation 19 With Offset 2D		y = aexp(b/x+cx) y = 1.0 / y + Offset
Reciprocal Simple Equation 20 With Offset 2D		y = (a+x)/(b+c*x) y = 1.0 / y + Offset
Reciprocal Simple Equation 21 With Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = 1.0 / y + Offset
Reciprocal Simple Equation 22 With Offset 2D		y = a(exp(bx)-exp(c*x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 23 With Offset 2D		y = aexp(bexp(c*x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 24 With Offset 2D		y = a/(1.0 + b * exp(c*x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 25 With Offset 2D		y = a/(b+pow(x,c)) y = 1.0 / y + Offset
Reciprocal Simple Equation 26 With Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 27 With Offset 2D		y = pow(a+b*x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 28 With Offset 2D		y = exp(a+b/x+c*ln(x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 29 With Offset 2D		y = aexp(bpow(x,c)) y = 1.0 / y + Offset
Reciprocal Simple Equation 30 With Offset 2D		y = apow(x,bpow(x,c)) y = 1.0 / y + Offset
Reciprocal Simple Equation 31 With Offset 2D		y = a*ln(x+b) y = 1.0 / y + Offset
Reciprocal Simple Equation 32 With Offset 2D		y = a/x+b*pow(x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 33 With Offset 2D		y = a/x+b*exp(c/x) y = 1.0 / y + Offset
Reciprocal Simple Equation 34 With Offset 2D		y = a/x+bexp(cx) y = 1.0 / y + Offset
Reciprocal Simple Equation 35 With Offset 2D		y = aexp(bx)/x y = 1.0 / y + Offset
Reciprocal Simple Equation 36 With Offset 2D		y = a*exp(b/x)/x y = 1.0 / y + Offset
Reciprocal Simple Equation 37 With Offset 2D		y = apow(x,b)ln(x) y = 1.0 / y + Offset
Reciprocal Simple Equation 38 With Offset 2D		y = a*pow(x,b)/ln(x) y = 1.0 / y + Offset
Reciprocal Simple Equation 39 With Offset 2D		y = apow(x,b)ln(x+c) y = 1.0 / y + Offset
Reciprocal Simple Equation 40 With Offset 2D		y = a*pow(ln(x+b),c) y = 1.0 / y + Offset
Reciprocal Simple Equation 41 With Offset 2D		y = apow(x,b/x)+cx y = 1.0 / y + Offset
Reciprocal Simple Equation 42 With Offset 2D		y = apow(x,b/x)+cln(x) y = 1.0 / y + Offset



Simple Equation 01 2D		y = a
Simple Equation 02 2D		y = a/pow(x,-2.0)
Simple Equation 03 2D		y = a*pow(ln(x),b)
Simple Equation 04 2D		y = a*pow(x,3.0)
Simple Equation 05 2D		y = a*pow(x,4.0)
Simple Equation 06 2D		y = x/(a+b*pow(x,2.0))
Simple Equation 07 2D		y = a * pow(b,x) * pow(x,c)
Simple Equation 08 2D		y = apow(b,1.0/x)pow(x,c)
Simple Equation 09 2D		y = a*exp(pow(x-b,2.0)/c)
Simple Equation 10 2D		y = a*exp(pow(ln(x)-b,2.0)/c)
Simple Equation 13 2D		y = apow(x/b,c)exp(x/b)
Simple Equation 14 2D		y = apow(x,b+cx)
Simple Equation 15 2D		y = a*pow(x,b+c/x)
Simple Equation 16 2D		y = apow(x,b+cln(x))
Simple Equation 17 2D		y = apow(x,bx+c*pow(x,2.0))
Simple Equation 18 2D		y = aexp(bx+c*pow(x,0.5))
Simple Equation 19 2D		y = aexp(b/x+cx)
Simple Equation 20 2D		y = (a+x)/(b+c*x)
Simple Equation 21 2D		y = (a+x)/(b+c*pow(x,2.0))
Simple Equation 22 2D		y = a(exp(bx)-exp(c*x))
Simple Equation 23 2D		y = aexp(bexp(c*x))
Simple Equation 24 2D		y = a/(1.0 + b * exp(c*x))
Simple Equation 25 2D		y = a/(b+pow(x,c))
Simple Equation 26 2D		y = a/pow(1.0 + b * pow(x,c),2.0)
Simple Equation 27 2D		y = pow(a+b*x,c)
Simple Equation 28 2D		y = exp(a+b/x+c*ln(x))
Simple Equation 29 2D		y = aexp(bpow(x,c))
Simple Equation 30 2D		y = apow(x,bpow(x,c))
Simple Equation 31 2D		y = a*ln(x+b)
Simple Equation 32 2D		y = a/x+b*pow(x,c)
Simple Equation 33 2D		y = a/x+b*exp(c/x)
Simple Equation 34 2D		y = a/x+bexp(cx)
Simple Equation 35 2D		y = aexp(bx)/x
Simple Equation 36 2D		y = a*exp(b/x)/x
Simple Equation 37 2D		y = apow(x,b)ln(x)
Simple Equation 38 2D		y = a*pow(x,b)/ln(x)
Simple Equation 39 2D		y = apow(x,b)ln(x+c)
Simple Equation 40 2D		y = a*pow(ln(x+b),c)
Simple Equation 41 2D		y = apow(x,b/x)+cx
Simple Equation 42 2D		y = apow(x,b/x)+cln(x)
Simple Reciprocal 2D		y = a / x



Simple Equation 02 With Offset 2D		y = a/pow(x,-2.0) + Offset
Simple Equation 03 With Offset 2D		y = a*pow(ln(x),b) + Offset
Simple Equation 04 With Offset 2D		y = a*pow(x,3.0) + Offset
Simple Equation 05 With Offset 2D		y = a*pow(x,4.0) + Offset
Simple Equation 06 With Offset 2D		y = x/(a+b*pow(x,2.0)) + Offset
Simple Equation 07 With Offset 2D		y = a * pow(b,x) * pow(x,c) + Offset
Simple Equation 08 With Offset 2D		y = apow(b,1.0/x)pow(x,c) + Offset
Simple Equation 09 With Offset 2D		y = a*exp(pow(x-b,2.0)/c) + Offset
Simple Equation 10 With Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) + Offset
Simple Equation 13 With Offset 2D		y = apow(x/b,c)exp(x/b) + Offset
Simple Equation 14 With Offset 2D		y = apow(x,b+cx) + Offset
Simple Equation 15 With Offset 2D		y = a*pow(x,b+c/x) + Offset
Simple Equation 16 With Offset 2D		y = apow(x,b+cln(x)) + Offset
Simple Equation 17 With Offset 2D		y = apow(x,bx+c*pow(x,2.0)) + Offset
Simple Equation 18 With Offset 2D		y = aexp(bx+c*pow(x,0.5)) + Offset
Simple Equation 19 With Offset 2D		y = aexp(b/x+cx) + Offset
Simple Equation 20 With Offset 2D		y = (a+x)/(b+c*x) + Offset
Simple Equation 21 With Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) + Offset
Simple Equation 22 With Offset 2D		y = a(exp(bx)-exp(c*x)) + Offset
Simple Equation 23 With Offset 2D		y = aexp(bexp(c*x)) + Offset
Simple Equation 24 With Offset 2D		y = a/(1.0 + b * exp(c*x)) + Offset
Simple Equation 25 With Offset 2D		y = a/(b+pow(x,c)) + Offset
Simple Equation 26 With Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) + Offset
Simple Equation 27 With Offset 2D		y = pow(a+b*x,c) + Offset
Simple Equation 28 With Offset 2D		y = exp(a+b/x+c*ln(x)) + Offset
Simple Equation 29 With Offset 2D		y = aexp(bpow(x,c)) + Offset
Simple Equation 30 With Offset 2D		y = apow(x,bpow(x,c)) + Offset
Simple Equation 31 With Offset 2D		y = a*ln(x+b) + Offset
Simple Equation 32 With Offset 2D		y = a/x+b*pow(x,c) + Offset
Simple Equation 33 With Offset 2D		y = a/x+b*exp(c/x) + Offset
Simple Equation 34 With Offset 2D		y = a/x+bexp(cx) + Offset
Simple Equation 35 With Offset 2D		y = aexp(bx)/x + Offset
Simple Equation 36 With Offset 2D		y = a*exp(b/x)/x + Offset
Simple Equation 37 With Offset 2D		y = apow(x,b)ln(x) + Offset
Simple Equation 38 With Offset 2D		y = a*pow(x,b)/ln(x) + Offset
Simple Equation 39 With Offset 2D		y = apow(x,b)ln(x+c) + Offset
Simple Equation 40 With Offset 2D		y = a*pow(ln(x+b),c) + Offset
Simple Equation 41 With Offset 2D		y = apow(x,b/x)+cx + Offset
Simple Equation 42 With Offset 2D		y = apow(x,b/x)+cln(x) + Offset
Simple Reciprocal With Offset 2D		y = a / x + Offset



Simple Equation 02 Plus Line 2D		y = a/pow(x,-2.0) y = y + (b * x) + c
Simple Equation 03 Plus Line 2D		y = apow(ln(x),b) y = y + (c x) + d
Simple Equation 04 Plus Line 2D		y = apow(x,3.0) y = y + (b x) + c
Simple Equation 05 Plus Line 2D		y = apow(x,4.0) y = y + (b x) + c
Simple Equation 06 Plus Line 2D		y = x/(a+bpow(x,2.0)) y = y + (c x) + d
Simple Equation 31 Plus Line 2D		y = aln(x+b) y = y + (c x) + d
Simple Equation 35 Plus Line 2D		y = aexp(bx)/x y = y + (c * x) + d
Simple Equation 36 Plus Line 2D		y = aexp(b/x)/x y = y + (c x) + d
Simple Equation 37 Plus Line 2D		y = apow(x,b)ln(x) y = y + (c * x) + d
Simple Equation 38 Plus Line 2D		y = apow(x,b)/ln(x) y = y + (c x) + d
Simple Reciprocal Plus Line 2D		y = a / x y = y + (b * x) + c

2D Trigonometric

Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / exp(x) + Offset
Cardinal Sine (sinc) Squared [radians] With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / exp(x) + Offset
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / exp(x) + Offset
Cardinal Sine (sinc) [radians] With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / exp(x) + Offset
Hyperbolic Cosine [radians] (Nyquist Limited) With Exponential Decay And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / exp(x) + Offset
Hyperbolic Cosine [radians] With Exponential Decay And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / exp(x) + Offset
Sine Squared [radians] (Nyquist Limited) With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / exp(x) + Offset
Sine Squared [radians] With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / exp(x) + Offset
Sine [radians] (Nyquist Limited) With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y / exp(x) + Offset
Sine [radians] With Exponential Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y / exp(x) + Offset
Tangent [radians] (Nyquist Limited) With Exponential Decay And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y / exp(x) + Offset
Tangent [radians] With Exponential Decay And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y / exp(x) + Offset



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / exp(x)
Cardinal Sine (sinc) Squared [radians] With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / exp(x)
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / exp(x)
Cardinal Sine (sinc) [radians] With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / exp(x)
Great Circle [Degrees] With Exponential Decay 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131 latitude = latitude / (c * exp(x))
Great Circle [radians] With Exponential Decay 2D		latitude = arctan(Acos(B + longitude)) latitude = latitude / (c exp(x))
Hyperbolic Cosine [radians] (Nyquist Limited) With Exponential Decay 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / exp(x)
Hyperbolic Cosine [radians] With Exponential Decay 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / exp(x)
Sine Squared [radians] (Nyquist Limited) With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / exp(x)
Sine Squared [radians] With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / exp(x)
Sine [radians] (Nyquist Limited) With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width) y = y / exp(x)
Sine [radians] With Exponential Decay 2D		y = amplitude * sin(pi * (x - center) / width) y = y / exp(x)
Tangent [radians] (Nyquist Limited) With Exponential Decay 2D		y = amplitude * tan(pi * (x - center) / width) y = y / exp(x)
Tangent [radians] With Exponential Decay 2D		y = amplitude * tan(pi * (x - center) / width) y = y / exp(x)



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * exp(x) + Offset
Cardinal Sine (sinc) Squared [radians] With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * exp(x) + Offset
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * exp(x) + Offset
Cardinal Sine (sinc) [radians] With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * exp(x) + Offset
Hyperbolic Cosine [radians] (Nyquist Limited) With Exponential Growth And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * exp(x) + Offset
Hyperbolic Cosine [radians] With Exponential Growth And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * exp(x) + Offset
Sine Squared [radians] (Nyquist Limited) With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * exp(x) + Offset
Sine Squared [radians] With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * exp(x) + Offset
Sine [radians] (Nyquist Limited) With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y * exp(x) + Offset
Sine [radians] With Exponential Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y * exp(x) + Offset
Tangent [radians] (Nyquist Limited) With Exponential Growth And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y * exp(x) + Offset
Tangent [radians] With Exponential Growth And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y * exp(x) + Offset



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * exp(x)
Cardinal Sine (sinc) Squared [radians] With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * exp(x)
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * exp(x)
Cardinal Sine (sinc) [radians] With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * exp(x)
Great Circle [Degrees] With Exponential Growth 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131 latitude = latitude * (c * exp(x))
Great Circle [radians] With Exponential Growth 2D		latitude = arctan(Acos(B + longitude)) latitude = latitude (c * exp(x))
Hyperbolic Cosine [radians] (Nyquist Limited) With Exponential Growth 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * exp(x)
Hyperbolic Cosine [radians] With Exponential Growth 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * exp(x)
Sine Squared [radians] (Nyquist Limited) With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * exp(x)
Sine Squared [radians] With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * exp(x)
Sine [radians] (Nyquist Limited) With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width) y = y * exp(x)
Sine [radians] With Exponential Growth 2D		y = amplitude * sin(pi * (x - center) / width) y = y * exp(x)
Tangent [radians] (Nyquist Limited) With Exponential Growth 2D		y = amplitude * tan(pi * (x - center) / width) y = y * exp(x)
Tangent [radians] With Exponential Growth 2D		y = amplitude * tan(pi * (x - center) / width) y = y * exp(x)



Inverse Cardinal Sine (sinc) Squared [radians] 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = x / y
Inverse Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = x / y
Inverse Cardinal Sine (sinc) [radians] 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = x / y
Inverse Cardinal Sine (sinc) [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = x / y
Inverse Great Circle [Degrees] 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131 latitude = x / latitude
Inverse Great Circle [radians] 2D		latitude = arctan(A*cos(B + longitude)) latitude = x / latitude
Inverse Hyperbolic Cosine [radians] 2D		y = amplitude * cosh(pi * (x - center) / width) y = x / y
Inverse Hyperbolic Cosine [radians] (Nyquist Limited) 2D		y = amplitude * cosh(pi * (x - center) / width) y = x / y
Inverse Sine Squared [radians] 2D		y = amplitude * sin(pi * (x - center) / width)² y = x / y
Inverse Sine Squared [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)² y = x / y
Inverse Sine [radians] 2D		y = amplitude * sin(pi * (x - center) / width) y = x / y
Inverse Sine [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width) y = x / y
Inverse Tangent [radians] 2D		y = amplitude * tan(pi * (x - center) / width) y = x / y
Inverse Tangent [radians] (Nyquist Limited) 2D		y = amplitude * tan(pi * (x - center) / width) y = x / y



Inverse Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = x / y + Offset
Inverse Cardinal Sine (sinc) Squared [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = x / y + Offset
Inverse Cardinal Sine (sinc) [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = x / y + Offset
Inverse Cardinal Sine (sinc) [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = x / y + Offset
Inverse Hyperbolic Cosine [radians] (Nyquist Limited) With Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = x / y + Offset
Inverse Hyperbolic Cosine [radians] With Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = x / y + Offset
Inverse Sine Squared [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = x / y + Offset
Inverse Sine Squared [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = x / y + Offset
Inverse Sine [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = x / y + Offset
Inverse Sine [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = x / y + Offset
Inverse Tangent [radians] (Nyquist Limited) With Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = x / y + Offset
Inverse Tangent [radians] With Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = x / y + Offset



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / x + Offset
Cardinal Sine (sinc) Squared [radians] With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / x + Offset
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / x + Offset
Cardinal Sine (sinc) [radians] With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / x + Offset
Hyperbolic Cosine [radians] (Nyquist Limited) With Linear Decay And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / x + Offset
Hyperbolic Cosine [radians] With Linear Decay And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / x + Offset
Sine Squared [radians] (Nyquist Limited) With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / x + Offset
Sine Squared [radians] With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / x + Offset
Sine [radians] (Nyquist Limited) With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y / x + Offset
Sine [radians] With Linear Decay And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y / x + Offset
Tangent [radians] (Nyquist Limited) With Linear Decay And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y / x + Offset
Tangent [radians] With Linear Decay And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y / x + Offset



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / x
Cardinal Sine (sinc) Squared [radians] With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y / x
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / x
Cardinal Sine (sinc) [radians] With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y / x
Great Circle [Degrees] With Linear Decay 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131 latitude = latitude / (c * x)
Great Circle [radians] With Linear Decay 2D		latitude = arctan(Acos(B + longitude)) latitude = latitude / (c x)
Hyperbolic Cosine [radians] (Nyquist Limited) With Linear Decay 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / x
Hyperbolic Cosine [radians] With Linear Decay 2D		y = amplitude * cosh(pi * (x - center) / width) y = y / x
Sine Squared [radians] (Nyquist Limited) With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / x
Sine Squared [radians] With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width)² y = y / x
Sine [radians] (Nyquist Limited) With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width) y = y / x
Sine [radians] With Linear Decay 2D		y = amplitude * sin(pi * (x - center) / width) y = y / x
Tangent [radians] (Nyquist Limited) With Linear Decay 2D		y = amplitude * tan(pi * (x - center) / width) y = y / x
Tangent [radians] With Linear Decay 2D		y = amplitude * tan(pi * (x - center) / width) y = y / x



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * x + Offset
Cardinal Sine (sinc) Squared [radians] With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * x + Offset
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * x + Offset
Cardinal Sine (sinc) [radians] With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * x + Offset
Hyperbolic Cosine [radians] (Nyquist Limited) With Linear Growth And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * x + Offset
Hyperbolic Cosine [radians] With Linear Growth And Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * x + Offset
Sine Squared [radians] (Nyquist Limited) With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * x + Offset
Sine Squared [radians] With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * x + Offset
Sine [radians] (Nyquist Limited) With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y * x + Offset
Sine [radians] With Linear Growth And Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = y * x + Offset
Tangent [radians] (Nyquist Limited) With Linear Growth And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y * x + Offset
Tangent [radians] With Linear Growth And Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = y * x + Offset



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * x
Cardinal Sine (sinc) Squared [radians] With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y * x
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * x
Cardinal Sine (sinc) [radians] With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y * x
Great Circle [Degrees] With Linear Growth 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131 latitude = latitude * (c * x)
Great Circle [radians] With Linear Growth 2D		latitude = arctan(Acos(B + longitude)) latitude = latitude (c * x)
Hyperbolic Cosine [radians] (Nyquist Limited) With Linear Growth 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * x
Hyperbolic Cosine [radians] With Linear Growth 2D		y = amplitude * cosh(pi * (x - center) / width) y = y * x
Sine Squared [radians] (Nyquist Limited) With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * x
Sine Squared [radians] With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width)² y = y * x
Sine [radians] (Nyquist Limited) With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width) y = y * x
Sine [radians] With Linear Growth 2D		y = amplitude * sin(pi * (x - center) / width) y = y * x
Tangent [radians] (Nyquist Limited) With Linear Growth 2D		y = amplitude * tan(pi * (x - center) / width) y = y * x
Tangent [radians] With Linear Growth 2D		y = amplitude * tan(pi * (x - center) / width) y = y * x



Reciprocal Cardinal Sine (sinc) Squared [radians] 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = 1.0 / y
Reciprocal Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = 1.0 / y
Reciprocal Cardinal Sine (sinc) [radians] 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = 1.0 / y
Reciprocal Cardinal Sine (sinc) [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = 1.0 / y
Reciprocal Great Circle [Degrees] 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131 latitude = 1.0 / latitude
Reciprocal Great Circle [radians] 2D		latitude = arctan(A*cos(B + longitude)) latitude = 1.0 / latitude
Reciprocal Hyperbolic Cosine [radians] 2D		y = amplitude * cosh(pi * (x - center) / width) y = 1.0 / y
Reciprocal Hyperbolic Cosine [radians] (Nyquist Limited) 2D		y = amplitude * cosh(pi * (x - center) / width) y = 1.0 / y
Reciprocal Sine Squared [radians] 2D		y = amplitude * sin(pi * (x - center) / width)² y = 1.0 / y
Reciprocal Sine Squared [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)² y = 1.0 / y
Reciprocal Sine [radians] 2D		y = amplitude * sin(pi * (x - center) / width) y = 1.0 / y
Reciprocal Sine [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width) y = 1.0 / y
Reciprocal Tangent [radians] 2D		y = amplitude * tan(pi * (x - center) / width) y = 1.0 / y
Reciprocal Tangent [radians] (Nyquist Limited) 2D		y = amplitude * tan(pi * (x - center) / width) y = 1.0 / y



Reciprocal Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Cardinal Sine (sinc) Squared [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Cardinal Sine (sinc) [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Cardinal Sine (sinc) [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine [radians] (Nyquist Limited) With Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine [radians] With Offset 2D		y = amplitude * cosh(pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Sine Squared [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = 1.0 / y + Offset
Reciprocal Sine Squared [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² y = 1.0 / y + Offset
Reciprocal Sine [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Sine [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Tangent [radians] (Nyquist Limited) With Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = 1.0 / y + Offset
Reciprocal Tangent [radians] With Offset 2D		y = amplitude * tan(pi * (x - center) / width) y = 1.0 / y + Offset



Cardinal Sine (sinc) Squared [radians] 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width)
Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width)
Cardinal Sine (sinc) [radians] 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width)
Cardinal Sine (sinc) [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width)
Great Circle [Degrees] 2D		latitude = arctan(Acos((B + longitude) / 57.2957795131)) 57.2957795131
Great Circle [radians] 2D		latitude = arctan(A*cos(B + longitude))
Hyperbolic Cosine [radians] 2D		y = amplitude * cosh(pi * (x - center) / width)
Hyperbolic Cosine [radians] (Nyquist Limited) 2D		y = amplitude * cosh(pi * (x - center) / width)
Sine Squared [radians] 2D		y = amplitude * sin(pi * (x - center) / width)²
Sine Squared [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)²
Sine [radians] 2D		y = amplitude * sin(pi * (x - center) / width)
Sine [radians] (Nyquist Limited) 2D		y = amplitude * sin(pi * (x - center) / width)
Tangent [radians] 2D		y = amplitude * tan(pi * (x - center) / width)
Tangent [radians] (Nyquist Limited) 2D		y = amplitude * tan(pi * (x - center) / width)



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) + Offset
Cardinal Sine (sinc) Squared [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) + Offset
Cardinal Sine (sinc) [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) + Offset
Cardinal Sine (sinc) [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) + Offset
Hyperbolic Cosine [radians] (Nyquist Limited) With Offset 2D		y = amplitude * cosh(pi * (x - center) / width) + Offset
Hyperbolic Cosine [radians] With Offset 2D		y = amplitude * cosh(pi * (x - center) / width) + Offset
Sine Squared [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² + Offset
Sine Squared [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width)² + Offset
Sine [radians] (Nyquist Limited) With Offset 2D		y = amplitude * sin(pi * (x - center) / width) + Offset
Sine [radians] With Offset 2D		y = amplitude * sin(pi * (x - center) / width) + Offset
Tangent [radians] (Nyquist Limited) With Offset 2D		y = amplitude * tan(pi * (x - center) / width) + Offset
Tangent [radians] With Offset 2D		y = amplitude * tan(pi * (x - center) / width) + Offset



Cardinal Sine (sinc) Squared [radians] (Nyquist Limited) Plus Line 2D		y = amplitude * sin(pi * (x - center) / width)² / (pi * (x - center) / width) y = y + (d * x) + f
Cardinal Sine (sinc) [radians] (Nyquist Limited) Plus Line 2D		y = amplitude * sin(pi * (x - center) / width) / (pi * (x - center) / width) y = y + (d * x) + f
Hyperbolic Cosine [radians] (Nyquist Limited) Plus Line 2D		y = amplitude * cosh(pi * (x - center) / width) y = y + (d * x) + f
Sine Squared [radians] (Nyquist Limited) Plus Line 2D		y = amplitude * sin(pi * (x - center) / width)² y = y + (d * x) + f
Sine [radians] (Nyquist Limited) Plus Line 2D		y = amplitude * sin(pi * (x - center) / width) y = y + (d * x) + f
Tangent [radians] (Nyquist Limited) Plus Line 2D		y = amplitude * tan(pi * (x - center) / width) y = y + (d * x) + f

2D YieldDensity

Bleasdale With Exponential Decay And Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y / (d * exp(x)) + Offset
Extended Holliday With Exponential Decay And Offset 2D		y = a / (a + bx + cx²) y = y / (d * exp(x)) + Offset
Harris With Exponential Decay And Offset 2D		y = 1.0 / (a + bx^c) y = y / (d * exp(x)) + Offset
Holliday With Exponential Decay And Offset 2D		y = 1.0 / (a + bx + cx²) y = y / (d * exp(x)) + Offset
Inverse Bleasdale With Exponential Decay And Offset 2D		y = x / (a + bx)^(-1.0/c) y = y / (d * exp(x)) + Offset
InverseHarris With Exponential Decay And Offset 2D		y = x / (a + bx^c) y = y / (d * exp(x)) + Offset
Nelder With Exponential Decay And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y / (f * exp(x)) + Offset



Bleasdale With Exponential Decay 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y / (d * exp(x))
Extended Holliday With Exponential Decay 2D		y = a / (a + bx + cx²) y = y / (d * exp(x))
Harris With Exponential Decay 2D		y = 1.0 / (a + bx^c) y = y / (d * exp(x))
Holliday With Exponential Decay 2D		y = 1.0 / (a + bx + cx²) y = y / (d * exp(x))
Inverse Bleasdale With Exponential Decay 2D		y = x / (a + bx)^(-1.0/c) y = y / (d * exp(x))
InverseHarris With Exponential Decay 2D		y = x / (a + bx^c) y = y / (d * exp(x))
Nelder With Exponential Decay 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y / (f * exp(x))



Bleasdale With Exponential Growth And Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y * (d * exp(x)) + Offset
Extended Holliday With Exponential Growth And Offset 2D		y = a / (a + bx + cx²) y = y * (d * exp(x)) + Offset
Harris With Exponential Growth And Offset 2D		y = 1.0 / (a + bx^c) y = y * (d * exp(x)) + Offset
Holliday With Exponential Growth And Offset 2D		y = 1.0 / (a + bx + cx²) y = y * (d * exp(x)) + Offset
Inverse Bleasdale With Exponential Growth And Offset 2D		y = x / (a + bx)^(-1.0/c) y = y * (d * exp(x)) + Offset
InverseHarris With Exponential Growth And Offset 2D		y = x / (a + bx^c) y = y * (d * exp(x)) + Offset
Nelder With Exponential Growth And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y * (f * exp(x)) + Offset



Bleasdale With Exponential Growth 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y * (d * exp(x))
Extended Holliday With Exponential Growth 2D		y = a / (a + bx + cx²) y = y * (d * exp(x))
Harris With Exponential Growth 2D		y = 1.0 / (a + bx^c) y = y * (d * exp(x))
Holliday With Exponential Growth 2D		y = 1.0 / (a + bx + cx²) y = y * (d * exp(x))
Inverse Bleasdale With Exponential Growth 2D		y = x / (a + bx)^(-1.0/c) y = y * (d * exp(x))
InverseHarris With Exponential Growth 2D		y = x / (a + bx^c) y = y * (d * exp(x))
Nelder With Exponential Growth 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y * (f * exp(x))



Inverse Bleasdale 2D		y = 1.0 / (a + bx)^(-1.0/c) y = x / y
Inverse Extended Holliday 2D		y = a / (a + bx + cx²) y = x / y
Inverse Harris 2D		y = 1.0 / (a + bx^c) y = x / y
Inverse Holliday 2D		y = 1.0 / (a + bx + cx²) y = x / y
Inverse Nelder 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = x / y



Inverse Bleasdale With Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) y = x / y + Offset
Inverse Extended Holliday With Offset 2D		y = a / (a + bx + cx²) y = x / y + Offset
Inverse Harris With Offset 2D		y = 1.0 / (a + bx^c) y = x / y + Offset
Inverse Holliday With Offset 2D		y = 1.0 / (a + bx + cx²) y = x / y + Offset
Inverse Nelder With Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = x / y + Offset



Bleasdale With Linear Decay And Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y / (d * x) + Offset
Extended Holliday With Linear Decay And Offset 2D		y = a / (a + bx + cx²) y = y / (d * x) + Offset
Harris With Linear Decay And Offset 2D		y = 1.0 / (a + bx^c) y = y / (d * x) + Offset
Holliday With Linear Decay And Offset 2D		y = 1.0 / (a + bx + cx²) y = y / (d * x) + Offset
Inverse Bleasdale With Linear Decay And Offset 2D		y = x / (a + bx)^(-1.0/c) y = y / (d * x) + Offset
InverseHarris With Linear Decay And Offset 2D		y = x / (a + bx^c) y = y / (d * x) + Offset
Nelder With Linear Decay And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y / (f * x) + Offset



Bleasdale With Linear Decay 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y / (d * x)
Extended Holliday With Linear Decay 2D		y = a / (a + bx + cx²) y = y / (d * x)
Harris With Linear Decay 2D		y = 1.0 / (a + bx^c) y = y / (d * x)
Holliday With Linear Decay 2D		y = 1.0 / (a + bx + cx²) y = y / (d * x)
Inverse Bleasdale With Linear Decay 2D		y = x / (a + bx)^(-1.0/c) y = y / (d * x)
InverseHarris With Linear Decay 2D		y = x / (a + bx^c) y = y / (d * x)
Nelder With Linear Decay 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y / (f * x)



Bleasdale With Linear Growth And Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y * (d * x) + Offset
Extended Holliday With Linear Growth And Offset 2D		y = a / (a + bx + cx²) y = y * (d * x) + Offset
Harris With Linear Growth And Offset 2D		y = 1.0 / (a + bx^c) y = y * (d * x) + Offset
Holliday With Linear Growth And Offset 2D		y = 1.0 / (a + bx + cx²) y = y * (d * x) + Offset
Inverse Bleasdale With Linear Growth And Offset 2D		y = x / (a + bx)^(-1.0/c) y = y * (d * x) + Offset
InverseHarris With Linear Growth And Offset 2D		y = x / (a + bx^c) y = y * (d * x) + Offset
Nelder With Linear Growth And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y * (f * x) + Offset



Bleasdale With Linear Growth 2D		y = 1.0 / (a + bx)^(-1.0/c) y = y * (d * x)
Extended Holliday With Linear Growth 2D		y = a / (a + bx + cx²) y = y * (d * x)
Harris With Linear Growth 2D		y = 1.0 / (a + bx^c) y = y * (d * x)
Holliday With Linear Growth 2D		y = 1.0 / (a + bx + cx²) y = y * (d * x)
Inverse Bleasdale With Linear Growth 2D		y = x / (a + bx)^(-1.0/c) y = y * (d * x)
InverseHarris With Linear Growth 2D		y = x / (a + bx^c) y = y * (d * x)
Nelder With Linear Growth 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = y * (f * x)



Reciprocal Bleasdale 2D		y = 1.0 / (a + bx)^(-1.0/c) y = 1.0 / y
Reciprocal Extended Holliday 2D		y = a / (a + bx + cx²) y = 1.0 / y
Reciprocal Harris 2D		y = 1.0 / (a + bx^c) y = 1.0 / y
Reciprocal Holliday 2D		y = 1.0 / (a + bx + cx²) y = 1.0 / y
Reciprocal Inverse Bleasdale 2D		y = x / (a + bx)^(-1.0/c) y = 1.0 / y
Reciprocal InverseHarris 2D		y = x / (a + bx^c) y = 1.0 / y
Reciprocal Nelder 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = 1.0 / y



Reciprocal Bleasdale With Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) y = 1.0 / y + Offset
Reciprocal Extended Holliday With Offset 2D		y = a / (a + bx + cx²) y = 1.0 / y + Offset
Reciprocal Harris With Offset 2D		y = 1.0 / (a + bx^c) y = 1.0 / y + Offset
Reciprocal Holliday With Offset 2D		y = 1.0 / (a + bx + cx²) y = 1.0 / y + Offset
Reciprocal Inverse Bleasdale With Offset 2D		y = x / (a + bx)^(-1.0/c) y = 1.0 / y + Offset
Reciprocal InverseHarris With Offset 2D		y = x / (a + bx^c) y = 1.0 / y + Offset
Reciprocal Nelder With Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² y = 1.0 / y + Offset



Bleasdale 2D		y = 1.0 / (a + bx)^(-1.0/c)
Extended Holliday 2D		y = a / (a + bx + cx²)
Harris 2D		y = 1.0 / (a + bx^c)
Holliday 2D		y = 1.0 / (a + bx + cx²)
Inverse Bleasdale 2D		y = x / (a + bx)^(-1.0/c)
InverseHarris 2D		y = x / (a + bx^c)
Nelder 2D		y = (a + x) / (b + c(a + x) + d(a + x)²



Bleasdale With Offset 2D		y = 1.0 / (a + bx)^(-1.0/c) + Offset
Extended Holliday With Offset 2D		y = a / (a + bx + cx²) + Offset
Harris With Offset 2D		y = 1.0 / (a + bx^c) + Offset
Holliday With Offset 2D		y = 1.0 / (a + bx + cx²) + Offset
Inverse Bleasdale With Offset 2D		y = x / (a + bx)^(-1.0/c) + Offset
InverseHarris With Offset 2D		y = x / (a + bx^c) + Offset
Nelder With Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)² + Offset

Curve fitting and surface fitting web application source code
Django (this site) Django (Python 2) Flask CherryPy Bottle

Curve fitting and surface fitting GUI application source code
tkinter pyQt5 pyGtk wxPython

Miscellaneous application source code
Animated Confidence Intervals
Initial Fitting Parameters
Multiple Statistical Distributions Fitter

Core fitting library source code
pyeq2 (Python 2) pyeq3

Link to additional information and history