ZunZunSite3 List Of All 2D Equations |
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] | |
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] | |
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] | |
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 | |