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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 * cx))
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)) + p4*exp((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 = axb / (c + xb)
y = y / exp(x) + Offset
    Jorge Rabinovich Population Growth With Exponential Decay And Offset 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 + 10x-c)
y = y / (d * exp(x))
    Dose-Response B With Exponential Decay 2D  
y = b + (a-b) / (1 + 10c-x)
y = y / (d * exp(x))
    Dose-Response C With Exponential Decay 2D  
y = b + (a-b) / (1 + 10d*(x-c))
y = y / (f * exp(x))
    Dose-Response D With Exponential Decay 2D  
y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
y = y / exp(x)
    Jorge Rabinovich Population Growth With Exponential Decay 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 + (B4*D2)) * 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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 = axb / (c + xb)
y = y * exp(x) + Offset
    Jorge Rabinovich Population Growth With Exponential Growth And Offset 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 + 10x-c)
y = y * (d * exp(x))
    Dose-Response B With Exponential Growth 2D  
y = b + (a-b) / (1 + 10c-x)
y = y * (d * exp(x))
    Dose-Response C With Exponential Growth 2D  
y = b + (a-b) / (1 + 10d*(x-c))
y = y * (f * exp(x))
    Dose-Response D With Exponential Growth 2D  
y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
y = y * exp(x)
    Jorge Rabinovich Population Growth With Exponential Growth 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 + (B4*D2)) * 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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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 + 10x-c)
y = x / y
    Inverse Dose-Response B 2D  
y = b + (a-b) / (1 + 10c-x)
y = x / y
    Inverse Dose-Response C 2D  
y = b + (a-b) / (1 + 10d*(x-c))
y = x / y
    Inverse Dose-Response D 2D  
y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
y = x / y
    Inverse Jorge Rabinovich Population Growth 2D  
Y = (P1*CC) / (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 + (B4*D2)) * 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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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 = axb / (c + xb)
y = x / y + Offset
    Inverse Jorge Rabinovich Population Growth With Offset 2D  
Y = (P1*CC) / (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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 = axb / (c + xb)
y = y / x + Offset
    Jorge Rabinovich Population Growth With Linear Decay And Offset 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 + 10x-c)
y = y / (d * x)
    Dose-Response B With Linear Decay 2D  
y = b + (a-b) / (1 + 10c-x)
y = y / (d * x)
    Dose-Response C With Linear Decay 2D  
y = b + (a-b) / (1 + 10d*(x-c))
y = y / (f * x)
    Dose-Response D With Linear Decay 2D  
y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
y = y / x
    Jorge Rabinovich Population Growth With Linear Decay 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 + (B4*D2)) * 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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 = axb / (c + xb)
y = y * x + Offset
    Jorge Rabinovich Population Growth With Linear Growth And Offset 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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)) + p4*exp((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 + 10x-c)
y = y * (d * x)
    Dose-Response B With Linear Growth 2D  
y = b + (a-b) / (1 + 10c-x)
y = y * (d * x)
    Dose-Response C With Linear Growth 2D  
y = b + (a-b) / (1 + 10d*(x-c))
y = y * (f * x)
    Dose-Response D With Linear Growth 2D  
y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
y = y * x
    Jorge Rabinovich Population Growth With Linear Growth 2D  
Y = (P1*CC) / (P1 + (CC-P1)*exp(-R*X))
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 + (B4*D2)) * 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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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 + 10x-c)
y = 1.0 / y
    Reciprocal Dose-Response B 2D  
y = b + (a-b) / (1 + 10c-x)
y = 1.0 / y
    Reciprocal Dose-Response C 2D  
y = b + (a-b) / (1 + 10d*(x-c))
y = 1.0 / y
    Reciprocal Dose-Response D 2D  
y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
y = 1.0 / y
    Reciprocal Jorge Rabinovich Population Growth 2D  
Y = (P1*CC) / (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 + (B4*D2)) * 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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
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 = axb / (c + xb)
y = 1.0 / y + Offset
    Reciprocal Jorge Rabinovich Population Growth With Offset 2D  
Y = (P1*CC) / (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 * xb
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) = Linf * (1.0 - exp(-K * (t-tzero)))
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 * cx))
    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 + 10x-c)
    Dose-Response B 2D   y = b + (a-b) / (1 + 10c-x)
    Dose-Response C 2D   y = b + (a-b) / (1 + 10d*(x-c))
    Dose-Response D 2D   y = b + (a-b) / (1 + 10d*(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 = axb / (c + xb)
    Jorge Rabinovich Population Growth 2D   Y = (P1*CC) / (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 + (B4*D2)) * 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 * xb
    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) = Linf * (1.0 - exp(-K * (t-tzero)))
     

     
    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 * cx)) + 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 = axb / (c + xb) + Offset
    Jorge Rabinovich Population Growth With Offset 2D   Y = (P1*CC) / (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 * xb + 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) = Linf * (1.0 - exp(-K * (t-tzero))) + 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 * xb
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 = (c*d/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(a*x/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 / xa)
y = y / (b * exp(x)) + Offset   [web citation]
    Frechet CDF Based B With Exponential Decay And Offset 2D  
y = b * exp(-1.0 / xa)
y = y / exp(x) + Offset   [web citation]
    Frechet PDF Based A With Exponential Decay And Offset 2D  
y = exp(- 1.0 / xa) / 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 / xa) / 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 * (ax-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 * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / (d * exp(x)) + Offset   [web citation]
    Inverse_gaussian PDF Based B With Exponential Decay And Offset 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / exp(x) + Offset   [web citation]
    Levy PDF Based Scaled With Exponential Decay And Offset 2D  
y = Scale * b0.5 * 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 = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
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/(2.0*a2))
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 = (c*d/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(a*x/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 / xa)
y = y / (b * exp(x))   [web citation]
    Frechet CDF Based B With Exponential Decay 2D  
y = b * exp(-1.0 / xa)
y = y / exp(x)   [web citation]
    Frechet PDF Based A With Exponential Decay 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = y / (b * exp(x))   [web citation]
    Frechet PDF Based B With Exponential Decay 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a)))
y = y / exp(x)   [web citation]
    Gompertz CDF Based With Exponential Decay 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / (d * exp(x))   [web citation]
    Inverse_gaussian PDF Based B With Exponential Decay 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / exp(x)   [web citation]
    Levy PDF Based Scaled With Exponential Decay 2D  
y = Scale * b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = y / exp(x)   [web citation]
    Levy PDF Based With Exponential Decay 2D  
y = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
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/(2.0*a2))
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 = (c*d/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(a*x/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 / xa)
y = y * (b * exp(x)) + Offset   [web citation]
    Frechet CDF Based B With Exponential Growth And Offset 2D  
y = b * exp(-1.0 / xa)
y = y * exp(x) + Offset   [web citation]
    Frechet PDF Based A With Exponential Growth And Offset 2D  
y = exp(- 1.0 / xa) / 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 / xa) / 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 * (ax-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 * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * (d * exp(x)) + Offset   [web citation]
    Inverse_gaussian PDF Based B With Exponential Growth And Offset 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * exp(x) + Offset   [web citation]
    Levy PDF Based Scaled With Exponential Growth And Offset 2D  
y = Scale * b0.5 * 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 = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
y = y * (b * exp(x)) + Offset   [web citation]
    Rayleigh CDF Based B With Exponential Growth And Offset 2D  
y = b * exp(-x2/(2.0*a2))
y = y * exp(x) + Offset   [web citation]
    Rayleigh PDF Based Scaled With Exponential Growth And Offset 2D  
y = Scale * (x/a2) * exp(-x2/(2.0*a2))
y = y * exp(x) + Offset   [web citation]
    Rayleigh PDF Based With Exponential Growth And Offset 2D  
y = (x/a2) * exp(-x2/(2.0*a2))
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 = (c*d/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(a*x/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 / xa)
y = y * (b * exp(x))   [web citation]
    Frechet CDF Based B With Exponential Growth 2D  
y = b * exp(-1.0 / xa)
y = y * exp(x)   [web citation]
    Frechet PDF Based A With Exponential Growth 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = y * (b * exp(x))   [web citation]
    Frechet PDF Based B With Exponential Growth 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a)))
y = y * exp(x)   [web citation]
    Gompertz CDF Based With Exponential Growth 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * (d * exp(x))   [web citation]
    Inverse_gaussian PDF Based B With Exponential Growth 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * exp(x)   [web citation]
    Levy PDF Based Scaled With Exponential Growth 2D  
y = Scale * b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = y * exp(x)   [web citation]
    Levy PDF Based With Exponential Growth 2D  
y = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
y = y * (b * exp(x))   [web citation]
    Rayleigh CDF Based B With Exponential Growth 2D  
y = b * exp(-x2/(2.0*a2))
y = y * exp(x)   [web citation]
    Rayleigh PDF Based Scaled With Exponential Growth 2D  
y = Scale * (x/a2) * exp(-x2/(2.0*a2))
y = y * exp(x)   [web citation]
    Rayleigh PDF Based With Exponential Growth 2D  
y = (x/a2) * exp(-x2/(2.0*a2))
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 = (c*d/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(a*x/b2) * exp(-0.5 * (x2 + a2)/b2)
y = x / y   [web citation]
    Inverse Frechet CDF Based A 2D  
y = exp(-1.0 / xa)
y = x / y   [web citation]
    Inverse Frechet CDF Based B 2D  
y = b * exp(-1.0 / xa)
y = x / y   [web citation]
    Inverse Frechet PDF Based A 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = x / y   [web citation]
    Inverse Frechet PDF Based B 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a))
y = x / y   [web citation]
    Inverse Gompertz CDF Based Scaled 2D  
y = Scale * (1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = x / y   [web citation]
    Inverse Inverse_gaussian PDF Based B 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = x / y   [web citation]
    Inverse Levy PDF Based 2D  
y = b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = x / y   [web citation]
    Inverse Levy PDF Based Scaled 2D  
y = Scale * b0.5 * 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) / (b*x)
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 * ab / 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 = (c*d/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(a*x/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 / xa)
y = x / y + Offset   [web citation]
    Inverse Frechet CDF Based B With Offset 2D  
y = b * exp(-1.0 / xa)
y = x / y + Offset   [web citation]
    Inverse Frechet PDF Based A With Offset 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = x / y + Offset   [web citation]
    Inverse Frechet PDF Based B With Offset 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a)))
y = x / y + Offset   [web citation]
    Inverse Gompertz CDF Based With Offset 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = x / y + Offset   [web citation]
    Inverse Inverse_gaussian PDF Based B With Offset 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = x / y + Offset   [web citation]
    Inverse Levy PDF Based Scaled With Offset 2D  
y = Scale * b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = x / y + Offset   [web citation]
    Inverse Levy PDF Based With Offset 2D  
y = b0.5 * 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) / (b*x)
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 * ab / 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 = (c*d/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(a*x/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 / xa)
y = y / (b * x) + Offset   [web citation]
    Frechet CDF Based B With Linear Decay And Offset 2D  
y = b * exp(-1.0 / xa)
y = y / x + Offset   [web citation]
    Frechet PDF Based A With Linear Decay And Offset 2D  
y = exp(- 1.0 / xa) / 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 / xa) / 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 * (ax-1.0) / ln(a)))
y = y / x + Offset   [web citation]
    Gompertz CDF Based With Linear Decay And Offset 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / (d * x) + Offset   [web citation]
    Inverse_gaussian PDF Based B With Linear Decay And Offset 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / x + Offset   [web citation]
    Levy PDF Based Scaled With Linear Decay And Offset 2D  
y = Scale * b0.5 * 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 = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
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/(2.0*a2))
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 = (c*d/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(a*x/b2) * exp(-0.5 * (x2 + a2)/b2)
y = y / x   [web citation]
    Frechet CDF Based A With Linear Decay 2D  
y = exp(-1.0 / xa)
y = y / (b * x)   [web citation]
    Frechet CDF Based B With Linear Decay 2D  
y = b * exp(-1.0 / xa)
y = y / x   [web citation]
    Frechet PDF Based A With Linear Decay 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = y / (b * x)   [web citation]
    Frechet PDF Based B With Linear Decay 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a)))
y = y / x   [web citation]
    Gompertz CDF Based With Linear Decay 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / (d * x)   [web citation]
    Inverse_gaussian PDF Based B With Linear Decay 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y / x   [web citation]
    Levy PDF Based Scaled With Linear Decay 2D  
y = Scale * b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = y / x   [web citation]
    Levy PDF Based With Linear Decay 2D  
y = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
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/(2.0*a2))
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 = (c*d/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(a*x/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 / xa)
y = y * (b * x) + Offset   [web citation]
    Frechet CDF Based B With Linear Growth And Offset 2D  
y = b * exp(-1.0 / xa)
y = y * x + Offset   [web citation]
    Frechet PDF Based A With Linear Growth And Offset 2D  
y = exp(- 1.0 / xa) / 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 / xa) / 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 * (ax-1.0) / ln(a)))
y = y * x + Offset   [web citation]
    Gompertz CDF Based With Linear Growth And Offset 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * (d * x) + Offset   [web citation]
    Inverse_gaussian PDF Based B With Linear Growth And Offset 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * x + Offset   [web citation]
    Levy PDF Based Scaled With Linear Growth And Offset 2D  
y = Scale * b0.5 * 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 = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
y = y * (b * x) + Offset   [web citation]
    Rayleigh CDF Based B With Linear Growth And Offset 2D  
y = b * exp(-x2/(2.0*a2))
y = y * x + Offset   [web citation]
    Rayleigh PDF Based Scaled With Linear Growth And Offset 2D  
y = Scale * (x/a2) * exp(-x2/(2.0*a2))
y = y * x + Offset   [web citation]
    Rayleigh PDF Based With Linear Growth And Offset 2D  
y = (x/a2) * exp(-x2/(2.0*a2))
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 = (c*d/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(a*x/b2) * exp(-0.5 * (x2 + a2)/b2)
y = y * x   [web citation]
    Frechet CDF Based A With Linear Growth 2D  
y = exp(-1.0 / xa)
y = y * (b * x)   [web citation]
    Frechet CDF Based B With Linear Growth 2D  
y = b * exp(-1.0 / xa)
y = y * x   [web citation]
    Frechet PDF Based A With Linear Growth 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = y * (b * x)   [web citation]
    Frechet PDF Based B With Linear Growth 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a)))
y = y * x   [web citation]
    Gompertz CDF Based With Linear Growth 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * (d * x)   [web citation]
    Inverse_gaussian PDF Based B With Linear Growth 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = y * x   [web citation]
    Levy PDF Based Scaled With Linear Growth 2D  
y = Scale * b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = y * x   [web citation]
    Levy PDF Based With Linear Growth 2D  
y = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
y = y * (b * x)   [web citation]
    Rayleigh CDF Based B With Linear Growth 2D  
y = b * exp(-x2/(2.0*a2))
y = y * x   [web citation]
    Rayleigh PDF Based Scaled With Linear Growth 2D  
y = Scale * (x/a2) * exp(-x2/(2.0*a2))
y = y * x   [web citation]
    Rayleigh PDF Based With Linear Growth 2D  
y = (x/a2) * exp(-x2/(2.0*a2))
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 = (c*d/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(a*x/b2) * exp(-0.5 * (x2 + a2)/b2)
y = 1.0 / y   [web citation]
    Reciprocal Frechet CDF Based A 2D  
y = exp(-1.0 / xa)
y = 1.0 / y   [web citation]
    Reciprocal Frechet CDF Based B 2D  
y = b * exp(-1.0 / xa)
y = 1.0 / y   [web citation]
    Reciprocal Frechet PDF Based A 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = 1.0 / y   [web citation]
    Reciprocal Frechet PDF Based B 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a))
y = 1.0 / y   [web citation]
    Reciprocal Gompertz CDF Based Scaled 2D  
y = Scale * (1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = 1.0 / y   [web citation]
    Reciprocal Inverse_gaussian PDF Based B 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = 1.0 / y   [web citation]
    Reciprocal Levy PDF Based 2D  
y = b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)
y = 1.0 / y   [web citation]
    Reciprocal Levy PDF Based Scaled 2D  
y = Scale * b0.5 * 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) / (b*x)
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 * ab / 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 = (c*d/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(a*x/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 / xa)
y = 1.0 / y + Offset   [web citation]
    Reciprocal Frechet CDF Based B With Offset 2D  
y = b * exp(-1.0 / xa)
y = 1.0 / y + Offset   [web citation]
    Reciprocal Frechet PDF Based A With Offset 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = 1.0 / y + Offset   [web citation]
    Reciprocal Frechet PDF Based B With Offset 2D  
y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a)))
y = 1.0 / y + Offset   [web citation]
    Reciprocal Gompertz CDF Based With Offset 2D  
y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = 1.0 / y + Offset   [web citation]
    Reciprocal Inverse_gaussian PDF Based B With Offset 2D  
y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))
y = 1.0 / y + Offset   [web citation]
    Reciprocal Levy PDF Based Scaled With Offset 2D  
y = Scale * b0.5 * 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 = b0.5 * 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) / (b*x)
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 * ab / 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 = (c*d/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(a*x/b2) * exp(-0.5 * (x2 + a2)/b2)   [web citation]
    Frechet CDF Based A 2D   y = exp(-1.0 / xa)   [web citation]
    Frechet CDF Based B 2D   y = b * exp(-1.0 / xa)   [web citation]
    Frechet PDF Based A 2D   y = exp(- 1.0 / xa) / x( a + 1.0)   [web citation]
    Frechet PDF Based B 2D   y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a))   [web citation]
    Gompertz CDF Based Scaled 2D   y = Scale * (1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))   [web citation]
    Inverse_gaussian PDF Based B 2D   y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x))   [web citation]
    Levy PDF Based 2D   y = b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3)   [web citation]
    Levy PDF Based Scaled 2D   y = Scale * b0.5 * 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) / (b*x)   [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 * ab / 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 = (c*d/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(a*x/b2) * exp(-0.5 * (x2 + a2)/b2) + Offset   [web citation]
    Frechet CDF Based A With Offset 2D   y = exp(-1.0 / xa) + Offset   [web citation]
    Frechet CDF Based B With Offset 2D   y = b * exp(-1.0 / xa) + Offset   [web citation]
    Frechet PDF Based A With Offset 2D   y = exp(- 1.0 / xa) / x( a + 1.0) + Offset   [web citation]
    Frechet PDF Based B With Offset 2D   y = b * exp(- 1.0 / xa) / 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 * (ax-1.0) / ln(a))) + Offset   [web citation]
    Gompertz CDF Based With Offset 2D   y = 1.0 - exp(-b * (ax-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/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x)) + Offset   [web citation]
    Inverse_gaussian PDF Based B With Offset 2D   y = sqrt(b/(c*x3))*exp(-b*(x-a)2 / (2.0*a2*x)) + Offset   [web citation]
    Levy PDF Based Scaled With Offset 2D   y = Scale * b0.5 * exp(-b/(2.0*(x-a)))/sqrt((x-a)3) + Offset   [web citation]
    Levy PDF Based With Offset 2D   y = b0.5 * 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) / (b*x) + 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 * ab / 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 / xa)
y = y + (b * x) + c   [web citation]
    Frechet CDF Based B Plus Line 2D  
y = b * exp(-1.0 / xa)
y = y + (c * x) + d   [web citation]
    Frechet PDF Based A Plus Line 2D  
y = exp(- 1.0 / xa) / x( a + 1.0)
y = y + (b * x) + c   [web citation]
    Frechet PDF Based B Plus Line 2D  
y = b * exp(- 1.0 / xa) / x( a + 1.0)
y = y + (c * x) + d   [web citation]
    Gompertz CDF Based Plus Line 2D  
y = 1.0 - exp(-b * (ax-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 = b0.5 * 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) / (b*x)
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 * ab / 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/(2.0*a2))
y = y + (b * x) + c   [web citation]
    Rayleigh CDF Based B Plus Line 2D  
y = b * exp(-x2/(2.0*a2))
y = y + (c * x) + d   [web citation]
    Rayleigh PDF Based Plus Line 2D  
y = (x/a2) * exp(-x2/(2.0*a2))
y = y + (b * x) + c   [web citation]
    Rayleigh PDF Based Scaled Plus Line 2D  
y = Scale * (x/a2) * exp(-x2/(2.0*a2))
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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2)
y = y / (n * exp(x)) + Offset
    Graeme Paterson Electric Motor With Exponential Decay And Offset 2D  
y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y / (h * exp(x)) + Offset
    Klimpel Kinetics Flotation A With Exponential Decay And Offset 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y / (f * exp(x)) + Offset   [web citation]
    Maxwell - Wiechert 3 With Exponential Decay And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y / (h * exp(x)) + Offset   [web citation]
    Maxwell - Wiechert 4 With Exponential Decay And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 + A2*x2 + A3/x2 + A4/x4)0.5
n = n / (f * exp(x))
    Dispersion Optical With Exponential Decay 2D  
n2(x) = A1 + A2*x2 + A3/x2 + A4/x4
n2(x) = n2(x) / (f * exp(x))
    Electron Beam Lithography Point Spread With Exponential Decay 2D  
y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y / (h * exp(x))
    Klimpel Kinetics Flotation A With Exponential Decay 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y / (f * exp(x))   [web citation]
    Maxwell - Wiechert 3 With Exponential Decay 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y / (h * exp(x))   [web citation]
    Maxwell - Wiechert 4 With Exponential Decay 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2)
y = y * (n * exp(x)) + Offset
    Graeme Paterson Electric Motor With Exponential Growth And Offset 2D  
y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y * (h * exp(x)) + Offset
    Klimpel Kinetics Flotation A With Exponential Growth And Offset 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
y = y * exp(x) + Offset
    Maxwell - Wiechert 1 With Exponential Growth And Offset 2D  
y = a1*exp(-X/Tau1)
y = y * exp(x) + Offset   [web citation]
    Maxwell - Wiechert 2 With Exponential Growth And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y * (f * exp(x)) + Offset   [web citation]
    Maxwell - Wiechert 3 With Exponential Growth And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y * (h * exp(x)) + Offset   [web citation]
    Maxwell - Wiechert 4 With Exponential Growth And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 + A2*x2 + A3/x2 + A4/x4)0.5
n = n * (f * exp(x))
    Dispersion Optical With Exponential Growth 2D  
n2(x) = A1 + A2*x2 + A3/x2 + A4/x4
n2(x) = n2(x) * (f * exp(x))
    Electron Beam Lithography Point Spread With Exponential Growth 2D  
y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y * (h * exp(x))
    Klimpel Kinetics Flotation A With Exponential Growth 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
y = y * exp(x)
    Maxwell - Wiechert 1 With Exponential Growth 2D  
y = a1*exp(-X/Tau1)
y = y * exp(x)   [web citation]
    Maxwell - Wiechert 2 With Exponential Growth 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y * (f * exp(x))   [web citation]
    Maxwell - Wiechert 3 With Exponential Growth 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y * (h * exp(x))   [web citation]
    Maxwell - Wiechert 4 With Exponential Growth 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = x / y
    Inverse Klimpel Kinetics Flotation A 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
y = x / y
    Inverse Maxwell - Wiechert 1 2D  
y = a1*exp(-X/Tau1)
y = x / y   [web citation]
    Inverse Maxwell - Wiechert 2 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = x / y   [web citation]
    Inverse Maxwell - Wiechert 3 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = x / y   [web citation]
    Inverse Maxwell - Wiechert 4 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2)
y = x / y + Offset
    Inverse Graeme Paterson Electric Motor With Offset 2D  
y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = x / y + Offset
    Inverse Klimpel Kinetics Flotation A With Offset 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = x / y + Offset   [web citation]
    Inverse Maxwell - Wiechert 3 With Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = x / y + Offset   [web citation]
    Inverse Maxwell - Wiechert 4 With Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2)
y = y / (n * x) + Offset
    Graeme Paterson Electric Motor With Linear Decay And Offset 2D  
y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y / (h * x) + Offset
    Klimpel Kinetics Flotation A With Linear Decay And Offset 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y / (f * x) + Offset   [web citation]
    Maxwell - Wiechert 3 With Linear Decay And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y / (h * x) + Offset   [web citation]
    Maxwell - Wiechert 4 With Linear Decay And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 + A2*x2 + A3/x2 + A4/x4)0.5
n = n / (f * x)
    Dispersion Optical With Linear Decay 2D  
n2(x) = A1 + A2*x2 + A3/x2 + A4/x4
n2(x) = n2(x) / (f * x)
    Electron Beam Lithography Point Spread With Linear Decay 2D  
y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y / (h * x)
    Klimpel Kinetics Flotation A With Linear Decay 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y / (f * x)   [web citation]
    Maxwell - Wiechert 3 With Linear Decay 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y / (h * x)   [web citation]
    Maxwell - Wiechert 4 With Linear Decay 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2)
y = y * (n * x) + Offset
    Graeme Paterson Electric Motor With Linear Growth And Offset 2D  
y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y * (h * x) + Offset
    Klimpel Kinetics Flotation A With Linear Growth And Offset 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
y = y * x + Offset
    Maxwell - Wiechert 1 With Linear Growth And Offset 2D  
y = a1*exp(-X/Tau1)
y = y * x + Offset   [web citation]
    Maxwell - Wiechert 2 With Linear Growth And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y * (f * x) + Offset   [web citation]
    Maxwell - Wiechert 3 With Linear Growth And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y * (h * x) + Offset   [web citation]
    Maxwell - Wiechert 4 With Linear Growth And Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 + A2*x2 + A3/x2 + A4/x4)0.5
n = n * (f * x)
    Dispersion Optical With Linear Growth 2D  
n2(x) = A1 + A2*x2 + A3/x2 + A4/x4
n2(x) = n2(x) * (f * x)
    Electron Beam Lithography Point Spread With Linear Growth 2D  
y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = y * (h * x)
    Klimpel Kinetics Flotation A With Linear Growth 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
y = y * x
    Maxwell - Wiechert 1 With Linear Growth 2D  
y = a1*exp(-X/Tau1)
y = y * x   [web citation]
    Maxwell - Wiechert 2 With Linear Growth 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = y * (f * x)   [web citation]
    Maxwell - Wiechert 3 With Linear Growth 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = y * (h * x)   [web citation]
    Maxwell - Wiechert 4 With Linear Growth 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = 1.0 / y
    Reciprocal Klimpel Kinetics Flotation A 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = 1.0 / y   [web citation]
    Reciprocal Maxwell - Wiechert 3 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = 1.0 / y   [web citation]
    Reciprocal Maxwell - Wiechert 4 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2)
y = 1.0 / y + Offset
    Reciprocal Graeme Paterson Electric Motor With Offset 2D  
y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
y = 1.0 / y + Offset
    Reciprocal Klimpel Kinetics Flotation A With Offset 2D  
y = a * (1 - (1 - exp(-b*x)) / (b*x))
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 = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)
y = 1.0 / y + Offset   [web citation]
    Reciprocal Maxwell - Wiechert 3 With Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)
y = 1.0 / y + Offset   [web citation]
    Reciprocal Maxwell - Wiechert 4 With Offset 2D  
y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(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 = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t)
    Klimpel Kinetics Flotation A 2D   y = a * (1 - (1 - exp(-b*x)) / (b*x))
    Maxwell - Wiechert 1 2D   y = a1*exp(-X/Tau1)   [web citation]
    Maxwell - Wiechert 2 2D   y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2)   [web citation]
    Maxwell - Wiechert 3 2D   y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3)   [web citation]
    Maxwell - Wiechert 4 2D   y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-X/Tau4)   [web citation]
    Modified Arps Well Production 2D   y = (qi_x/((1.0-b_x)*Di_x)) * (1.0-((1.0+b_x*Di_x*x)**(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 = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + j*exp(-(x-k)2 / l2) + Offset
    Graeme Paterson Electric Motor With Offset 2D   y = A*exp(-b*t)*cos(omega*t + phi) + A2*exp(-b2*t) + Offset
    Klimpel Kinetics Flotation A With Offset 2D   y = a * (1 - (1 - exp(-b*x)) / (b*x)) + Offset
    Maxwell - Wiechert 1 With Offset 2D   y = a1*exp(-X/Tau1) + Offset   [web citation]
    Maxwell - Wiechert 2 With Offset 2D   y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + Offset   [web citation]
    Maxwell - Wiechert 3 With Offset 2D   y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + Offset   [web citation]
    Maxwell - Wiechert 4 With Offset 2D   y = a1*exp(-X/Tau1) + a2*exp(-X/Tau2) + a3*exp(-X/Tau3) + a4*exp(-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_x*Di_x*x)**(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(-b*x)) / (b*x))
y = y + (c * x) + d
    Maxwell - Wiechert 1 Plus Line 2D  
y = a1*exp(-X/Tau1)
y = y + (c * x) + d   [web citation]
     




     


2D Exponential

    Asymptotic Exponential A Transform With Exponential Decay And Offset 2D  
y = 1.0 - abx + c
y = y / (d * exp(x)) + Offset
    Asymptotic Exponential A With Exponential Decay And Offset 2D  
y = 1.0 - ax
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 = xa * 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 = ax
y = y / (b * exp(x)) + Offset
    Standard Vapor Pressure With Exponential Decay And Offset 2D  
y = exp(a + (b/x) + c*ln(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 - abx + c
y = y / (d * exp(x))
    Asymptotic Exponential A With Exponential Decay 2D  
y = 1.0 - ax
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 * (xd))
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 = xa * 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 = ax
y = y / (b * exp(x))
    Standard Vapor Pressure With Exponential Decay 2D  
y = exp(a + (b/x) + c*ln(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 - abx + c
y = y * (d * exp(x)) + Offset
    Asymptotic Exponential A With Exponential Growth And Offset 2D  
y = 1.0 - ax
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 = xa * 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 = ax
y = y * (b * exp(x)) + Offset
    Standard Vapor Pressure With Exponential Growth And Offset 2D  
y = exp(a + (b/x) + c*ln(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 - abx + c
y = y * (d * exp(x))
    Asymptotic Exponential A With Exponential Growth 2D  
y = 1.0 - ax
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 * (xd))
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 = xa * 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 = ax
y = y * (b * exp(x))
    Standard Vapor Pressure With Exponential Growth 2D  
y = exp(a + (b/x) + c*ln(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 - ax
y = x / y
    Inverse Asymptotic Exponential A Transform 2D  
y = 1.0 - abx + 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 * (xd))
y = x / y
    Inverse Hoerl 2D  
y = xa * 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 - abx + c
y = x / y + Offset
    Inverse Asymptotic Exponential A With Offset 2D  
y = 1.0 - ax
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 = xa * 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 - abx + c
y = y / (d * x) + Offset
    Asymptotic Exponential A With Linear Decay And Offset 2D  
y = 1.0 - ax
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 = xa * 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 = ax
y = y / (b * x) + Offset
    Standard Vapor Pressure With Linear Decay And Offset 2D  
y = exp(a + (b/x) + c*ln(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 - abx + c
y = y / (d * x)
    Asymptotic Exponential A With Linear Decay 2D  
y = 1.0 - ax
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 * (xd))
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 = xa * 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 = ax
y = y / (b * x)
    Standard Vapor Pressure With Linear Decay 2D  
y = exp(a + (b/x) + c*ln(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 - abx + c
y = y * (d * x) + Offset
    Asymptotic Exponential A With Linear Growth And Offset 2D  
y = 1.0 - ax
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 = xa * 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 = ax
y = y * (b * x) + Offset
    Standard Vapor Pressure With Linear Growth And Offset 2D  
y = exp(a + (b/x) + c*ln(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 - abx + c
y = y * (d * x)
    Asymptotic Exponential A With Linear Growth 2D  
y = 1.0 - ax
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 * (xd))
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 = xa * 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 = ax
y = y * (b * x)
    Standard Vapor Pressure With Linear Growth 2D  
y = exp(a + (b/x) + c*ln(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 - ax
y = 1.0 / y
    Reciprocal Asymptotic Exponential A Transform 2D  
y = 1.0 - abx + 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 * (xd))
y = 1.0 / y
    Reciprocal Hoerl 2D  
y = xa * 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 = ax
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 - abx + c
y = 1.0 / y + Offset
    Reciprocal Asymptotic Exponential A With Offset 2D  
y = 1.0 - ax
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 = xa * 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 = ax
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 - ax
    Asymptotic Exponential A Transform 2D   y = 1.0 - abx + 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 * (xd))
    Hoerl 2D   y = xa * 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 = ax
    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 - abx + c + Offset
    Asymptotic Exponential A With Offset 2D   y = 1.0 - ax + 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 = xa * 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 = ax + 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 - ax
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 = xa * 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 = ax
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 + a1*sin(c1*x)+b1*cos(c1*x)
y = y / (f * exp(x))   [web citation]
    1 Term Standard With Exponential Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x)
y = y / (d * exp(x))   [web citation]
    2 Term Standard With Exponential Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x)
y = y / (g * exp(x))   [web citation]
    3 Term Standard With Exponential Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x)
y = y / (i * exp(x))   [web citation]
    4 Term Standard With Exponential Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x) + a4*sin(4x)+b4*cos(4x)
y = y / (k * exp(x))   [web citation]
     

     
    1 Term (Scaled X) With Exponential Growth 2D  
y = a0 + a1*sin(c1*x)+b1*cos(c1*x)
y = y * (f * exp(x))   [web citation]
    1 Term Standard With Exponential Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x)
y = y * (d * exp(x))   [web citation]
    2 Term Standard With Exponential Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x)
y = y * (g * exp(x))   [web citation]
    3 Term Standard With Exponential Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x)
y = y * (i * exp(x))   [web citation]
    4 Term Standard With Exponential Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x) + a4*sin(4x)+b4*cos(4x)
y = y * (k * exp(x))   [web citation]
     

     
    Inverse 1 Term (Scaled X) 2D  
y = a0 + a1*sin(c1*x)+b1*cos(c1*x)
y = x / y   [web citation]
    Inverse 1 Term Standard 2D  
y = a0 + a1*sin(x)+b1*cos(x)
y = x / y   [web citation]
    Inverse 2 Term Standard 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x)
y = x / y   [web citation]
    Inverse 3 Term Standard 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x)
y = x / y   [web citation]
    Inverse 4 Term Standard 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x) + a4*sin(4x)+b4*cos(4x)
y = x / y   [web citation]
     

     
    1 Term (Scaled X) With Linear Decay 2D  
y = a0 + a1*sin(c1*x)+b1*cos(c1*x)
y = y / (f * x)   [web citation]
    1 Term Standard With Linear Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x)
y = y / (d * x)   [web citation]
    2 Term Standard With Linear Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x)
y = y / (g * x)   [web citation]
    3 Term Standard With Linear Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x)
y = y / (i * x)   [web citation]
    4 Term Standard With Linear Decay 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x) + a4*sin(4x)+b4*cos(4x)
y = y / (k * x)   [web citation]
     

     
    1 Term (Scaled X) With Linear Growth 2D  
y = a0 + a1*sin(c1*x)+b1*cos(c1*x)
y = y * (f * x)   [web citation]
    1 Term Standard With Linear Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x)
y = y * (d * x)   [web citation]
    2 Term Standard With Linear Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x)
y = y * (g * x)   [web citation]
    3 Term Standard With Linear Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x)
y = y * (i * x)   [web citation]
    4 Term Standard With Linear Growth 2D  
y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x) + a4*sin(4x)+b4*cos(4x)
y = y * (k * x)   [web citation]
     

     
    1 Term (Scaled X) 2D   y = a0 + a1*sin(c1*x)+b1*cos(c1*x)   [web citation]
    1 Term Standard 2D   y = a0 + a1*sin(x)+b1*cos(x)   [web citation]
    2 Term Standard 2D   y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x)   [web citation]
    3 Term Standard 2D   y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x)   [web citation]
    4 Term Standard 2D   y = a0 + a1*sin(x)+b1*cos(x) + a2*sin(2x)+b2*cos(2x) + a3*sin(3x)+b3*cos(3x) + a4*sin(4x)+b4*cos(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 + b*log10(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 + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
y = y / (g * exp(x))
    Cubic Logarithmic Transform With Exponential Decay 2D  
y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3
y = y / (h * exp(x))
    Cubic Logarithmic With Exponential Decay 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3
y = y / (f * exp(x))
    Linear Logarithmic Scaled With Exponential Decay 2D  
y = a + b*ln(cx)
y = y / (d * exp(x))
    Linear Logarithmic Shifted With Exponential Decay 2D  
y = a + b*ln(c+x)
y = y / (d * exp(x))
    Linear Logarithmic Transform With Exponential Decay 2D  
y = a + b*ln(cx+d)
y = y / (f * exp(x))
    Linear Logarithmic With Exponential Decay 2D  
y = a + b*ln(x)
y = y / (c * exp(x))
    Quadratic Logarithmic Scaled With Exponential Decay 2D  
y = a + b*ln(dx) + c*ln(dx)2
y = y / (f * exp(x))
    Quadratic Logarithmic Transform With Exponential Decay 2D  
y = a + b*ln(dx+f) + c*ln(dx+f)2
y = y / (g * exp(x))
    Quadratic Logarithmic With Exponential Decay 2D  
y = a + b*ln(x) + c*ln(x)2
y = y / (d * exp(x))
    Quartic Logarithmic Scaled With Exponential Decay 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
y = y / (h * exp(x))
    Quartic Logarithmic Transform With Exponential Decay 2D  
y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
y = y / (i * exp(x))
    Quartic Logarithmic With Exponential Decay 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
y = y / (g * exp(x))
    Quintic Logarithmic Scaled With Exponential Decay 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
y = y / (i * exp(x))
    Quintic Logarithmic Transform With Exponential Decay 2D  
y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5
y = y / (j * exp(x))
    Quintic Logarithmic With Exponential Decay 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(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 + b*log10(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 + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
y = y * (g * exp(x))
    Cubic Logarithmic Transform With Exponential Growth 2D  
y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3
y = y * (h * exp(x))
    Cubic Logarithmic With Exponential Growth 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3
y = y * (f * exp(x))
    Linear Logarithmic Scaled With Exponential Growth 2D  
y = a + b*ln(cx)
y = y * (d * exp(x))
    Linear Logarithmic Shifted With Exponential Growth 2D  
y = a + b*ln(c+x)
y = y * (d * exp(x))
    Linear Logarithmic Transform With Exponential Growth 2D  
y = a + b*ln(cx+d)
y = y * (f * exp(x))
    Linear Logarithmic With Exponential Growth 2D  
y = a + b*ln(x)
y = y * (c * exp(x))
    Quadratic Logarithmic Scaled With Exponential Growth 2D  
y = a + b*ln(dx) + c*ln(dx)2
y = y * (f * exp(x))
    Quadratic Logarithmic Transform With Exponential Growth 2D  
y = a + b*ln(dx+f) + c*ln(dx+f)2
y = y * (g * exp(x))
    Quadratic Logarithmic With Exponential Growth 2D  
y = a + b*ln(x) + c*ln(x)2
y = y * (d * exp(x))
    Quartic Logarithmic Scaled With Exponential Growth 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
y = y * (h * exp(x))
    Quartic Logarithmic Transform With Exponential Growth 2D  
y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
y = y * (i * exp(x))
    Quartic Logarithmic With Exponential Growth 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
y = y * (g * exp(x))
    Quintic Logarithmic Scaled With Exponential Growth 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
y = y * (i * exp(x))
    Quintic Logarithmic Transform With Exponential Growth 2D  
y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5
y = y * (j * exp(x))
    Quintic Logarithmic With Exponential Growth 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(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 + b*ln(x) + c*ln(x)2 + d*ln(x)3
y = x / y
    Inverse Cubic Logarithmic Scaled 2D  
y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
y = x / y
    Inverse Cubic Logarithmic Transform 2D  
y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+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 + b*ln(x) + c*ln(x)2
y = x / y
    Inverse Quadratic Logarithmic Scaled 2D  
y = a + b*ln(dx) + c*ln(dx)2
y = x / y
    Inverse Quadratic Logarithmic Transform 2D  
y = a + b*ln(dx+f) + c*ln(dx+f)2
y = x / y
    Inverse Quartic Logarithmic 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
y = x / y
    Inverse Quartic Logarithmic Scaled 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
y = x / y
    Inverse Quartic Logarithmic Transform 2D  
y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
y = x / y
    Inverse Quintic Logarithmic 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5
y = x / y
    Inverse Quintic Logarithmic Scaled 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
y = x / y
    Inverse Quintic Logarithmic Transform 2D  
y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+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 + b*log10(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 + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
y = y / (g * x)
    Cubic Logarithmic Transform With Linear Decay 2D  
y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3
y = y / (h * x)
    Cubic Logarithmic With Linear Decay 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3
y = y / (f * x)
    Linear Logarithmic Scaled With Linear Decay 2D  
y = a + b*ln(cx)
y = y / (d * x)
    Linear Logarithmic Shifted With Linear Decay 2D  
y = a + b*ln(c+x)
y = y / (d * x)
    Linear Logarithmic Transform With Linear Decay 2D  
y = a + b*ln(cx+d)
y = y / (f * x)
    Linear Logarithmic With Linear Decay 2D  
y = a + b*ln(x)
y = y / (c * x)
    Quadratic Logarithmic Scaled With Linear Decay 2D  
y = a + b*ln(dx) + c*ln(dx)2
y = y / (f * x)
    Quadratic Logarithmic Transform With Linear Decay 2D  
y = a + b*ln(dx+f) + c*ln(dx+f)2
y = y / (g * x)
    Quadratic Logarithmic With Linear Decay 2D  
y = a + b*ln(x) + c*ln(x)2
y = y / (d * x)
    Quartic Logarithmic Scaled With Linear Decay 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
y = y / (h * x)
    Quartic Logarithmic Transform With Linear Decay 2D  
y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
y = y / (i * x)
    Quartic Logarithmic With Linear Decay 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
y = y / (g * x)
    Quintic Logarithmic Scaled With Linear Decay 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
y = y / (i * x)
    Quintic Logarithmic Transform With Linear Decay 2D  
y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5
y = y / (j * x)
    Quintic Logarithmic With Linear Decay 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(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 + b*log10(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 + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
y = y * (g * x)
    Cubic Logarithmic Transform With Linear Growth 2D  
y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3
y = y * (h * x)
    Cubic Logarithmic With Linear Growth 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3
y = y * (f * x)
    Linear Logarithmic Scaled With Linear Growth 2D  
y = a + b*ln(cx)
y = y * (d * x)
    Linear Logarithmic Shifted With Linear Growth 2D  
y = a + b*ln(c+x)
y = y * (d * x)
    Linear Logarithmic Transform With Linear Growth 2D  
y = a + b*ln(cx+d)
y = y * (f * x)
    Linear Logarithmic With Linear Growth 2D  
y = a + b*ln(x)
y = y * (c * x)
    Quadratic Logarithmic Scaled With Linear Growth 2D  
y = a + b*ln(dx) + c*ln(dx)2
y = y * (f * x)
    Quadratic Logarithmic Transform With Linear Growth 2D  
y = a + b*ln(dx+f) + c*ln(dx+f)2
y = y * (g * x)
    Quadratic Logarithmic With Linear Growth 2D  
y = a + b*ln(x) + c*ln(x)2
y = y * (d * x)
    Quartic Logarithmic Scaled With Linear Growth 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
y = y * (h * x)
    Quartic Logarithmic Transform With Linear Growth 2D  
y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
y = y * (i * x)
    Quartic Logarithmic With Linear Growth 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
y = y * (g * x)
    Quintic Logarithmic Scaled With Linear Growth 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
y = y * (i * x)
    Quintic Logarithmic Transform With Linear Growth 2D  
y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5
y = y * (j * x)
    Quintic Logarithmic With Linear Growth 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(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 + b*ln(x) + c*ln(x)2 + d*ln(x)3
y = 1.0 / y
    Reciprocal Cubic Logarithmic Scaled 2D  
y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
y = 1.0 / y
    Reciprocal Cubic Logarithmic Transform 2D  
y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+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 + b*ln(x) + c*ln(x)2
y = 1.0 / y
    Reciprocal Quadratic Logarithmic Scaled 2D  
y = a + b*ln(dx) + c*ln(dx)2
y = 1.0 / y
    Reciprocal Quadratic Logarithmic Transform 2D  
y = a + b*ln(dx+f) + c*ln(dx+f)2
y = 1.0 / y
    Reciprocal Quartic Logarithmic 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
y = 1.0 / y
    Reciprocal Quartic Logarithmic Scaled 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
y = 1.0 / y
    Reciprocal Quartic Logarithmic Transform 2D  
y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
y = 1.0 / y
    Reciprocal Quintic Logarithmic 2D  
y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5
y = 1.0 / y
    Reciprocal Quintic Logarithmic Scaled 2D  
y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
y = 1.0 / y
    Reciprocal Quintic Logarithmic Transform 2D  
y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+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 + b*ln(x) + c*ln(x)2 + d*ln(x)3
    Cubic Logarithmic Scaled 2D   y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
    Cubic Logarithmic Transform 2D   y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+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 + b*ln(x) + c*ln(x)2
    Quadratic Logarithmic Scaled 2D   y = a + b*ln(dx) + c*ln(dx)2
    Quadratic Logarithmic Transform 2D   y = a + b*ln(dx+f) + c*ln(dx+f)2
    Quartic Logarithmic 2D   y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
    Quartic Logarithmic Scaled 2D   y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
    Quartic Logarithmic Transform 2D   y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
    Quintic Logarithmic 2D   y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5
    Quintic Logarithmic Scaled 2D   y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
    Quintic Logarithmic Transform 2D   y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(b*x+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 / xa)
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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(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 = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(-2*m*(x-u)) - 2*exp(-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(b*x+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 / xa)
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) + 0.5*G*(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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = y / (j * exp(x))   [web citation]
    Transition State Rate Constant Law With Exponential Decay 2D  
y = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(b*x+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 / xa)
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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(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 = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(-2*m*(x-u)) - 2*exp(-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(b*x+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 / xa)
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) + 0.5*G*(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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = y * (j * exp(x))   [web citation]
    Transition State Rate Constant Law With Exponential Growth 2D  
y = axb * 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((x*c-d)3 / (2b-(x*c-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(-2*m*(x-u)) - 2*exp(-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 / xa)
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) + 0.5*G*(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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = x / y   [web citation]
    Inverse Transition State Rate Constant Law 2D  
y = axb * 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((x*c-d)3 / (2b-(x*c-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 / xa)
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = x / y + Offset   [web citation]
    Inverse Transition State Rate Constant Law With Offset 2D  
y = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(b*x+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 / xa)
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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(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 = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(-2*m*(x-u)) - 2*exp(-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(b*x+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 / xa)
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) + 0.5*G*(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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = y / (j * x)   [web citation]
    Transition State Rate Constant Law With Linear Decay 2D  
y = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(b*x+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 / xa)
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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(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 = axb * 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((x*c-d)3 / (2b-(x*c-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 = axb * 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 + cx0.5)
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(-2*m*(x-u)) - 2*exp(-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(b*x+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 / xa)
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) + 0.5*G*(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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = y * (j * x)   [web citation]
    Transition State Rate Constant Law With Linear Growth 2D  
y = axb * 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((x*c-d)3 / (2b-(x*c-d)))0.5
y = 1.0 / y   [web citation]
    Reciprocal Combined Power And Exponential 2D  
y = axb * 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 + cx0.5)
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(-2*m*(x-u)) - 2*exp(-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 / xa)
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) + 0.5*G*(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 / xb
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-B*X**C)*(1-(0.5+(arctan((X-D)/E))/pi))+(F-G*X**H)*(0.5+(arctan((X-D)/E))/pi)
y = 1.0 / y   [web citation]
    Reciprocal Transition State Rate Constant Law 2D  
y = axb * 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