| ZunZun.com List Of All 3D Equations | |
| Chen-Clayton 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) | |
| High-Low Affinity Isotope Displacement (y = [Hot]) 3D | z = aby / (1+b(x+y)) | |
| Logistic Growth 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) 3D | z = ay / (b + x + y) + cy / (d + x + y) | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) 3D | z = ay / (b + x + y) | |
| Modified Chung-Pfost 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) [web citation] | |
| Modified Halsey 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) [web citation] | |
| Modified Henderson 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) [web citation] | |
| Strohman-Yoerger 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) [web citation] | |
| Chen-Clayton With Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) + Offset [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) + Offset | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Offset 3D | z = aby / (1+b(x+y)) + Offset | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) + Offset | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Offset 3D | z = ay / (b + x + y) + Offset | |
| Modified Chung-Pfost With Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) + Offset [web citation] | |
| Modified Halsey With Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) + Offset [web citation] | |
| Modified Henderson With Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) + Offset [web citation] | |
| Strohman-Yoerger With Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) + Offset [web citation] | |
| Chen-Clayton With Exponential Decay 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) / (g * exp(xy)) [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Exponential Decay 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z / exp(xy) | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Exponential Decay 3D | z = aby / (1+b(x+y)) z = z / exp(xy) | |
| Logistic Growth With Exponential Decay 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g z = z / (i * exp(xy)) | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Exponential Decay 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z / (g * exp(xy)) | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Exponential Decay 3D | z = ay / (b + x + y) z = z / exp(xy) | |
| Modified Chung-Pfost With Exponential Decay 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) / (f * exp(xy)) [web citation] | |
| Modified Halsey With Exponential Decay 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) / (f * exp(xy)) [web citation] | |
| Modified Henderson With Exponential Decay 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) / (f * exp(xy)) [web citation] | |
| Strohman-Yoerger With Exponential Decay 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) / (g * exp(xy)) [web citation] | |
| Chen-Clayton With Exponential Decay And Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) / (h * exp(xy)) + Offset [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Exponential Decay And Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z / exp(xy) + Offset | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Exponential Decay And Offset 3D | z = aby / (1+b(x+y)) z = z / exp(xy) + Offset | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Exponential Decay And Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z / (h * exp(xy)) + Offset | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Exponential Decay And Offset 3D | z = ay / (b + x + y) z = z / exp(xy) + Offset | |
| Modified Chung-Pfost With Exponential Decay And Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) / (g * exp(xy)) + Offset [web citation] | |
| Modified Halsey With Exponential Decay And Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) / (g * exp(xy)) + Offset [web citation] | |
| Modified Henderson With Exponential Decay And Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) / (g * exp(xy)) + Offset [web citation] | |
| Strohman-Yoerger With Exponential Decay And Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) / (h * exp(xy)) + Offset [web citation] | |
| Chen-Clayton With Exponential Growth 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) * (g * exp(xy)) [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Exponential Growth 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z * exp(xy) | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Exponential Growth 3D | z = aby / (1+b(x+y)) z = z * exp(xy) | |
| Logistic Growth With Exponential Growth 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g z = z * (i * exp(xy)) | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Exponential Growth 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z * (g * exp(xy)) | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Exponential Growth 3D | z = ay / (b + x + y) z = z * exp(xy) | |
| Modified Chung-Pfost With Exponential Growth 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) * (f * exp(xy)) [web citation] | |
| Modified Halsey With Exponential Growth 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) * (f * exp(xy)) [web citation] | |
| Modified Henderson With Exponential Growth 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) * (f * exp(xy)) [web citation] | |
| Strohman-Yoerger With Exponential Growth 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) * (g * exp(xy)) [web citation] | |
| Chen-Clayton With Exponential Growth And Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) * (h * exp(xy)) + Offset [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Exponential Growth And Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z * exp(xy) + Offset | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Exponential Growth And Offset 3D | z = aby / (1+b(x+y)) z = z * exp(xy) + Offset | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Exponential Growth And Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z * (h * exp(xy)) + Offset | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Exponential Growth And Offset 3D | z = ay / (b + x + y) z = z * exp(xy) + Offset | |
| Modified Chung-Pfost With Exponential Growth And Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) * (g * exp(xy)) + Offset [web citation] | |
| Modified Halsey With Exponential Growth And Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) * (g * exp(xy)) + Offset [web citation] | |
| Modified Henderson With Exponential Growth And Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) * (g * exp(xy)) + Offset [web citation] | |
| Strohman-Yoerger With Exponential Growth And Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) * (h * exp(xy)) + Offset [web citation] | |
| Inverse Chen-Clayton 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = xy / r.h.(Tk,M) [web citation] | |
| Inverse High-Low Affinity Double Isotope Displacement (y = [Hot]) 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = xy / z | |
| Inverse High-Low Affinity Isotope Displacement (y = [Hot]) 3D | z = aby / (1+b(x+y)) z = xy / z | |
| Inverse Logistic Growth 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g z = xy / z | |
| Inverse Michaelis-Menten Double Isotope Displacement (y = [Hot]) 3D | z = ay / (b + x + y) + cy / (d + x + y) z = xy / z | |
| Inverse Michaelis-Menten Isotope Displacement (y = [Hot]) 3D | z = ay / (b + x + y) z = xy / z | |
| Inverse Modified Chung-Pfost 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = xy / r.h.(T,M) [web citation] | |
| Inverse Modified Halsey 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = xy / r.h.(T,M) [web citation] | |
| Inverse Modified Henderson 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = xy / r.h.(T,M) [web citation] | |
| Inverse Strohman-Yoerger 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = xy / r.h.(Ps,M) [web citation] | |
| Inverse Chen-Clayton With Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = xy / (r.h.(Tk,M) + Offset [web citation] | |
| Inverse High-Low Affinity Double Isotope Displacement (y = [Hot]) With Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = xy / (z + Offset | |
| Inverse High-Low Affinity Isotope Displacement (y = [Hot]) With Offset 3D | z = aby / (1+b(x+y)) z = xy / (z + Offset | |
| Inverse Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) z = xy / (z + Offset | |
| Inverse Michaelis-Menten Isotope Displacement (y = [Hot]) With Offset 3D | z = ay / (b + x + y) z = xy / (z + Offset | |
| Inverse Modified Chung-Pfost With Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = xy / (r.h.(T,M) + Offset [web citation] | |
| Inverse Modified Halsey With Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = xy / (r.h.(T,M) + Offset [web citation] | |
| Inverse Modified Henderson With Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = xy / (r.h.(T,M) + Offset [web citation] | |
| Inverse Strohman-Yoerger With Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = xy / (r.h.(Ps,M) + Offset [web citation] | |
| Chen-Clayton With Linear Decay 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) / (g * xy) [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Linear Decay 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z / xy | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Linear Decay 3D | z = aby / (1+b(x+y)) z = z / xy | |
| Logistic Growth With Linear Decay 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g z = z / (i * xy) | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Linear Decay 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z / (g * xy) | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Linear Decay 3D | z = ay / (b + x + y) z = z / xy | |
| Modified Chung-Pfost With Linear Decay 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) / (f * xy) [web citation] | |
| Modified Halsey With Linear Decay 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) / (f * xy) [web citation] | |
| Modified Henderson With Linear Decay 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) / (f * xy) [web citation] | |
| Strohman-Yoerger With Linear Decay 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) / (g * xy) [web citation] | |
| Chen-Clayton With Linear Decay And Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) / (h * xy) + Offset [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Linear Decay And Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z / xy + Offset | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Linear Decay And Offset 3D | z = aby / (1+b(x+y)) z = z / xy + Offset | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Linear Decay And Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z / (h * xy) + Offset | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Linear Decay And Offset 3D | z = ay / (b + x + y) z = z / xy + Offset | |
| Modified Chung-Pfost With Linear Decay And Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) / (g * xy) + Offset [web citation] | |
| Modified Halsey With Linear Decay And Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) / (g * xy) + Offset [web citation] | |
| Modified Henderson With Linear Decay And Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) / (g * xy) + Offset [web citation] | |
| Strohman-Yoerger With Linear Decay And Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) / (h * xy) + Offset [web citation] | |
| Chen-Clayton With Linear Growth 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) * (g * xy) + Offset [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Linear Growth 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z * xy | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Linear Growth 3D | z = aby / (1+b(x+y)) z = z * xy | |
| Logistic Growth With Linear Growth 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g z = z * (i * xy) + Offset | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Linear Growth 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z * (g * xy) + Offset | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Linear Growth 3D | z = ay / (b + x + y) z = z * xy | |
| Modified Chung-Pfost With Linear Growth 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) * (f * xy) + Offset [web citation] | |
| Modified Halsey With Linear Growth 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) * (f * xy) + Offset [web citation] | |
| Modified Henderson With Linear Growth 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) * (f * xy) + Offset [web citation] | |
| Strohman-Yoerger With Linear Growth 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) * (g * xy) + Offset [web citation] | |
| Chen-Clayton With Linear Growth And Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = r.h.(Tk,M) * (h * xy) + Offset [web citation] | |
| High-Low Affinity Double Isotope Displacement (y = [Hot]) With Linear Growth And Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = z * xy + Offset | |
| High-Low Affinity Isotope Displacement (y = [Hot]) With Linear Growth And Offset 3D | z = aby / (1+b(x+y)) z = z * xy + Offset | |
| Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Linear Growth And Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) z = z * (h * xy) + Offset | |
| Michaelis-Menten Isotope Displacement (y = [Hot]) With Linear Growth And Offset 3D | z = ay / (b + x + y) z = z * xy + Offset | |
| Modified Chung-Pfost With Linear Growth And Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = r.h.(T,M) * (g * xy) + Offset [web citation] | |
| Modified Halsey With Linear Growth And Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = r.h.(T,M) * (g * xy) + Offset [web citation] | |
| Modified Henderson With Linear Growth And Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = r.h.(T,M) * (g * xy) + Offset [web citation] | |
| Strohman-Yoerger With Linear Growth And Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = r.h.(Ps,M) * (h * xy) + Offset [web citation] | |
| Reciprocal Chen-Clayton 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = 1.0 / r.h.(Tk,M) [web citation] | |
| Reciprocal High-Low Affinity Double Isotope Displacement (y = [Hot]) 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = 1.0 / z | |
| Reciprocal High-Low Affinity Isotope Displacement (y = [Hot]) 3D | z = aby / (1+b(x+y)) z = 1.0 / z | |
| Reciprocal Logistic Growth 3D | z = a / (1 + exp(-(b + cx + dy + fxy))) + g z = 1.0 / z | |
| Reciprocal Michaelis-Menten Double Isotope Displacement (y = [Hot]) 3D | z = ay / (b + x + y) + cy / (d + x + y) z = 1.0 / z | |
| Reciprocal Michaelis-Menten Isotope Displacement (y = [Hot]) 3D | z = ay / (b + x + y) z = 1.0 / z | |
| Reciprocal Modified Chung-Pfost 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = 1.0 / r.h.(T,M) [web citation] | |
| Reciprocal Modified Halsey 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = 1.0 / r.h.(T,M) [web citation] | |
| Reciprocal Modified Henderson 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = 1.0 / r.h.(T,M) [web citation] | |
| Reciprocal Strohman-Yoerger 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = 1.0 / r.h.(Ps,M) [web citation] | |
| Reciprocal Chen-Clayton With Offset 3D | r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M)) r.h.(Tk,M) = 1.0 / r.h.(Tk,M) + Offset [web citation] | |
| Reciprocal High-Low Affinity Double Isotope Displacement (y = [Hot]) With Offset 3D | z = aby / (1+b(x+y)) + cdy / (1+d(x+y)) z = 1.0 / z + Offset | |
| Reciprocal High-Low Affinity Isotope Displacement (y = [Hot]) With Offset 3D | z = aby / (1+b(x+y)) z = 1.0 / z + Offset | |
| Reciprocal Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Offset 3D | z = ay / (b + x + y) + cy / (d + x + y) z = 1.0 / z + Offset | |
| Reciprocal Michaelis-Menten Isotope Displacement (y = [Hot]) With Offset 3D | z = ay / (b + x + y) z = 1.0 / z + Offset | |
| Reciprocal Modified Chung-Pfost With Offset 3D | r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M)) r.h.(T,M) = 1.0 / r.h.(T,M) + Offset [web citation] | |
| Reciprocal Modified Halsey With Offset 3D | r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3) r.h.(T,M) = 1.0 / r.h.(T,M) + Offset [web citation] | |
| Reciprocal Modified Henderson With Offset 3D | r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3) r.h.(T,M) = 1.0 / r.h.(T,M) + Offset [web citation] | |
| Reciprocal Strohman-Yoerger With Offset 3D | r.h.(Ps,M) = exp(C1*exp(-C2*M)*ln(Ps) - C3*exp(-C4*M)) r.h.(Ps,M) = 1.0 / r.h.(Ps,M) + Offset [web citation] | |
| Full Cubic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 | |
| Full Cubic Exponential Transform 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 | |
| Full Quadratic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) | |
| Full Quadratic Exponential Transform 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) | |
| Linear Exponential 3D | z = a + b*exp(x) + c*exp(y) | |
| Linear Exponential Transform 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) | |
| Simplified Cubic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 | |
| Simplified Cubic Exponential Transform 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 | |
| Simplified Quadratic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 | |
| Simplified Quadratic Exponential Transform 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 | |
| Full Cubic Exponential Transform With Exponential Decay 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 z = z / (s * exp(xy)) | |
| Full Cubic Exponential With Exponential Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 z = z / (n * exp(xy)) | |
| Full Quadratic Exponential Transform With Exponential Decay 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) z = z / (n * exp(xy)) | |
| Full Quadratic Exponential With Exponential Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) z = z / (i * exp(xy)) | |
| Linear Exponential Transform With Exponential Decay 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) z = z / (j * exp(xy)) | |
| Linear Exponential With Exponential Decay 3D | z = a + b*exp(x) + c*exp(y) z = z / (f * exp(xy)) | |
| Simplified Cubic Exponential Transform With Exponential Decay 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 z = z / (p * exp(xy)) | |
| Simplified Cubic Exponential With Exponential Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 z = z / (j * exp(xy)) | |
| Simplified Quadratic Exponential Transform With Exponential Decay 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 z = z / (m * exp(xy)) | |
| Simplified Quadratic Exponential With Exponential Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 z = z / (h * exp(xy)) | |
| Full Cubic Exponential Transform With Exponential Growth 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 z = z * (s * exp(xy)) | |
| Full Cubic Exponential With Exponential Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 z = z * (n * exp(xy)) | |
| Full Quadratic Exponential Transform With Exponential Growth 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) z = z * (n * exp(xy)) | |
| Full Quadratic Exponential With Exponential Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) z = z * (i * exp(xy)) | |
| Linear Exponential Transform With Exponential Growth 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) z = z * (j * exp(xy)) | |
| Linear Exponential With Exponential Growth 3D | z = a + b*exp(x) + c*exp(y) z = z * (f * exp(xy)) | |
| Simplified Cubic Exponential Transform With Exponential Growth 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 z = z * (p * exp(xy)) | |
| Simplified Cubic Exponential With Exponential Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 z = z * (j * exp(xy)) | |
| Simplified Quadratic Exponential Transform With Exponential Growth 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 z = z * (m * exp(xy)) | |
| Simplified Quadratic Exponential With Exponential Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 z = z * (h * exp(xy)) | |
| Inverse Full Cubic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 z = xy / z | |
| Inverse Full Cubic Exponential Transform 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 z = xy / z | |
| Inverse Full Quadratic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) z = xy / z | |
| Inverse Full Quadratic Exponential Transform 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) z = xy / z | |
| Inverse Linear Exponential 3D | z = a + b*exp(x) + c*exp(y) z = xy / z | |
| Inverse Linear Exponential Transform 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) z = xy / z | |
| Inverse Simplified Cubic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 z = xy / z | |
| Inverse Simplified Cubic Exponential Transform 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 z = xy / z | |
| Inverse Simplified Quadratic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 z = xy / z | |
| Inverse Simplified Quadratic Exponential Transform 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 z = xy / z | |
| Full Cubic Exponential Transform With Linear Decay 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 z = z / (s * xy) | |
| Full Cubic Exponential With Linear Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 z = z / (n * xy) | |
| Full Quadratic Exponential Transform With Linear Decay 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) z = z / (n * xy) | |
| Full Quadratic Exponential With Linear Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) z = z / (i * xy) | |
| Linear Exponential Transform With Linear Decay 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) z = z / (j * xy) | |
| Linear Exponential With Linear Decay 3D | z = a + b*exp(x) + c*exp(y) z = z / (f * xy) | |
| Simplified Cubic Exponential Transform With Linear Decay 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 z = z / (p * xy) | |
| Simplified Cubic Exponential With Linear Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 z = z / (j * xy) | |
| Simplified Quadratic Exponential Transform With Linear Decay 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 z = z / (m * xy) | |
| Simplified Quadratic Exponential With Linear Decay 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 z = z / (h * xy) | |
| Full Cubic Exponential Transform With Linear Growth 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 z = z * (s * xy) + Offset | |
| Full Cubic Exponential With Linear Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 z = z * (n * xy) + Offset | |
| Full Quadratic Exponential Transform With Linear Growth 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) z = z * (n * xy) + Offset | |
| Full Quadratic Exponential With Linear Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) z = z * (i * xy) + Offset | |
| Linear Exponential Transform With Linear Growth 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) z = z * (j * xy) + Offset | |
| Linear Exponential With Linear Growth 3D | z = a + b*exp(x) + c*exp(y) z = z * (f * xy) + Offset | |
| Simplified Cubic Exponential Transform With Linear Growth 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 z = z * (p * xy) + Offset | |
| Simplified Cubic Exponential With Linear Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 z = z * (j * xy) + Offset | |
| Simplified Quadratic Exponential Transform With Linear Growth 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 z = z * (m * xy) + Offset | |
| Simplified Quadratic Exponential With Linear Growth 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 z = z * (h * xy) + Offset | |
| Reciprocal Full Cubic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)3 + h*exp(y)3 + i*exp(x)*exp(y) + j*exp(x)2*exp(y) + k*exp(x)*exp(y)2 z = 1.0 / z | |
| Reciprocal Full Cubic Exponential Transform 3D | z = a + b*exp(m*x+n) + c*exp(o*y+p) + d*exp(m*x+n)2 + f*exp(o*y+p)2 + g*exp(m*x+n)3 + h*exp(o*y+p)3 + i*exp(m*x+n)*exp(o*y+p) + j*exp(m*x+n)2*exp(o*y+p) + k*exp(m*x+n)*exp(o*y+p)2 z = 1.0 / z | |
| Reciprocal Full Quadratic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y) z = 1.0 / z | |
| Reciprocal Full Quadratic Exponential Transform 3D | z = a + b*exp(h*x+i) + c*exp(j*y+k) + d*exp(h*x+i)2 + e*exp(j*y+k)2 + f*exp(h*x+i)*exp(j*y+k) z = 1.0 / z | |
| Reciprocal Linear Exponential 3D | z = a + b*exp(x) + c*exp(y) z = 1.0 / z | |
| Reciprocal Linear Exponential Transform 3D | z = a + b*exp(d*x+f) + c*exp(g*y+h) z = 1.0 / z | |
| Reciprocal Simplified Cubic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + e*exp(y)2 + f*exp(x)3 + g*exp(y)3 z = 1.0 / z | |
| Reciprocal Simplified Cubic Exponential Transform 3D | z = a + b*exp(i*x+j) + c*exp(k*y+m) + d*exp(i*x+j)2 + f*exp(k*y+m)2 + g*exp(i*x+j)3 + h*exp(k*y+m)3 z = 1.0 / z | |
| Reciprocal Simplified Quadratic Exponential 3D | z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 z = 1.0 / z | |
| Reciprocal Simplified Quadratic Exponential Transform 3D | z = a + b*exp(g*x+h) + c*exp(i*y+j) + d*exp(g*x+h)2 + f*exp(i*y+j)2 z = 1.0 / z | |
| Full Cubic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 | |
| Full Cubic Logarithmic Transform 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 | |
| Full Quadratic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) | |
| Full Quadratic Logarithmic Transform 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) | |
| Linear Logarithmic 3D | z = a + b*ln(x) + c*ln(y) | |
| Linear Logarithmic Transform 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) | |
| Simplified Cubic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 | |
| Simplified Cubic Logarithmic Transform 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 | |
| Simplified Quadratic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 | |
| Simplified Quadratic Logarithmic Transform 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 | |
| Full Cubic Logarithmic Transform With Exponential Decay 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 z = z / (s * exp(xy)) | |
| Full Cubic Logarithmic With Exponential Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 z = z / (n * exp(xy)) | |
| Full Quadratic Logarithmic Transform With Exponential Decay 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) z = z / (n * exp(xy)) | |
| Full Quadratic Logarithmic With Exponential Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z / (i * exp(xy)) | |
| Linear Logarithmic Transform With Exponential Decay 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) z = z / (j * exp(xy)) | |
| Linear Logarithmic With Exponential Decay 3D | z = a + b*ln(x) + c*ln(y) z = z / (f * exp(xy)) | |
| Simplified Cubic Logarithmic Transform With Exponential Decay 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 z = z / (p * exp(xy)) | |
| Simplified Cubic Logarithmic With Exponential Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 z = z / (j * exp(xy)) | |
| Simplified Quadratic Logarithmic Transform With Exponential Decay 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 z = z / (m * exp(xy)) | |
| Simplified Quadratic Logarithmic With Exponential Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 z = z / (h * exp(xy)) | |
| Full Cubic Logarithmic Transform With Exponential Growth 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 z = z * (s * exp(xy)) | |
| Full Cubic Logarithmic With Exponential Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 z = z * (n * exp(xy)) | |
| Full Quadratic Logarithmic Transform With Exponential Growth 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) z = z * (n * exp(xy)) | |
| Full Quadratic Logarithmic With Exponential Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z * (i * exp(xy)) | |
| Linear Logarithmic Transform With Exponential Growth 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) z = z * (j * exp(xy)) | |
| Linear Logarithmic With Exponential Growth 3D | z = a + b*ln(x) + c*ln(y) z = z * (f * exp(xy)) | |
| Simplified Cubic Logarithmic Transform With Exponential Growth 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 z = z * (p * exp(xy)) | |
| Simplified Cubic Logarithmic With Exponential Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 z = z * (j * exp(xy)) | |
| Simplified Quadratic Logarithmic Transform With Exponential Growth 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 z = z * (m * exp(xy)) | |
| Simplified Quadratic Logarithmic With Exponential Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 z = z * (h * exp(xy)) | |
| Inverse Full Cubic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 z = xy / z | |
| Inverse Full Cubic Logarithmic Transform 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 z = xy / z | |
| Inverse Full Quadratic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = xy / z | |
| Inverse Full Quadratic Logarithmic Transform 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) z = xy / z | |
| Inverse Linear Logarithmic 3D | z = a + b*ln(x) + c*ln(y) z = xy / z | |
| Inverse Linear Logarithmic Transform 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) z = xy / z | |
| Inverse Simplified Cubic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 z = xy / z | |
| Inverse Simplified Cubic Logarithmic Transform 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 z = xy / z | |
| Inverse Simplified Quadratic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 z = xy / z | |
| Inverse Simplified Quadratic Logarithmic Transform 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 z = xy / z | |
| Full Cubic Logarithmic Transform With Linear Decay 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 z = z / (s * xy) | |
| Full Cubic Logarithmic With Linear Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 z = z / (n * xy) | |
| Full Quadratic Logarithmic Transform With Linear Decay 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) z = z / (n * xy) | |
| Full Quadratic Logarithmic With Linear Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z / (i * xy) | |
| Linear Logarithmic Transform With Linear Decay 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) z = z / (j * xy) | |
| Linear Logarithmic With Linear Decay 3D | z = a + b*ln(x) + c*ln(y) z = z / (f * xy) | |
| Simplified Cubic Logarithmic Transform With Linear Decay 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 z = z / (p * xy) | |
| Simplified Cubic Logarithmic With Linear Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 z = z / (j * xy) | |
| Simplified Quadratic Logarithmic Transform With Linear Decay 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 z = z / (m * xy) | |
| Simplified Quadratic Logarithmic With Linear Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 z = z / (h * xy) | |
| Full Cubic Logarithmic Transform With Linear Growth 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 z = z * (s * xy) + Offset | |
| Full Cubic Logarithmic With Linear Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 z = z * (n * xy) + Offset | |
| Full Quadratic Logarithmic Transform With Linear Growth 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) z = z * (n * xy) + Offset | |
| Full Quadratic Logarithmic With Linear Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z * (i * xy) + Offset | |
| Linear Logarithmic Transform With Linear Growth 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) z = z * (j * xy) + Offset | |
| Linear Logarithmic With Linear Growth 3D | z = a + b*ln(x) + c*ln(y) z = z * (f * xy) + Offset | |
| Simplified Cubic Logarithmic Transform With Linear Growth 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 z = z * (p * xy) + Offset | |
| Simplified Cubic Logarithmic With Linear Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 z = z * (j * xy) + Offset | |
| Simplified Quadratic Logarithmic Transform With Linear Growth 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 z = z * (m * xy) + Offset | |
| Simplified Quadratic Logarithmic With Linear Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 z = z * (h * xy) + Offset | |
| Reciprocal Full Cubic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 + i*ln(x)*ln(y) + j*ln(x)2*ln(y) + k*ln(x)*ln(y)2 z = 1.0 / z | |
| Reciprocal Full Cubic Logarithmic Transform 3D | z = a + b*ln(m*x+n) + c*ln(o*y+p) + d*ln(m*x+n)2 + f*ln(o*y+p)2 + g*ln(m*x+n)3 + h*ln(o*y+p)3 + i*ln(m*x+n)*ln(o*y+p) + j*ln(m*x+n)2*ln(o*y+p) + k*ln(m*x+n)*ln(o*y+p)2 z = 1.0 / z | |
| Reciprocal Full Quadratic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = 1.0 / z | |
| Reciprocal Full Quadratic Logarithmic Transform 3D | z = a + b*ln(h*x+i) + c*ln(j*y+k) + d*ln(h*x+i)2 + f*ln(j*y+k)2 + g*ln(h*x+i)*ln(j*y+k) z = 1.0 / z | |
| Reciprocal Linear Logarithmic 3D | z = a + b*ln(x) + c*ln(y) z = 1.0 / z | |
| Reciprocal Linear Logarithmic Transform 3D | z = a + b*ln(d*x+f) + c*ln(g*y+h) z = 1.0 / z | |
| Reciprocal Simplified Cubic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)3 + h*ln(y)3 z = 1.0 / z | |
| Reciprocal Simplified Cubic Logarithmic Transform 3D | z = a + b*ln(i*x+j) + c*ln(k*y+m) + d*ln(i*x+j)2 + f*ln(k*y+m)2 + g*ln(i*x+j)3 + h*ln(k*y+m)3 z = 1.0 / z | |
| Reciprocal Simplified Quadratic Logarithmic 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 z = 1.0 / z | |
| Reciprocal Simplified Quadratic Logarithmic Transform 3D | z = a + b*ln(g*x+h) + c*ln(i*y+j) + d*ln(g*x+h)2 + f*ln(i*y+j)2 z = 1.0 / z | |
| Sag For Asphere 0 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset | |
| Sag For Asphere 0 Borisovsky 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset | |
| Sag For Asphere 0 Borisovsky With Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset + Offset | |
| Sag For Asphere 0 Borisovsky With Exponential Decay 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z / (h * exp(xy)) | |
| Sag For Asphere 0 With Exponential Decay 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z / (f * exp(xy)) | |
| Sag For Asphere 0 Borisovsky With Exponential Decay And Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z / (i * exp(xy)) + Offset | |
| Sag For Asphere 0 Borisovsky With Exponential Growth 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z * (h * exp(xy)) | |
| Sag For Asphere 0 With Exponential Growth 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z * (f * exp(xy)) | |
| Sag For Asphere 0 Borisovsky With Exponential Growth And Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z * (i * exp(xy)) + Offset | |
| Inverse Sag For Asphere 0 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = xy / z | |
| Inverse Sag For Asphere 0 Borisovsky 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = xy / z | |
| Inverse Sag For Asphere 0 Borisovsky With Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = xy / (z + Offset | |
| Sag For Asphere 0 Borisovsky With Linear Decay 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z / (h * xy) | |
| Sag For Asphere 0 With Linear Decay 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z / (f * xy) | |
| Sag For Asphere 0 Borisovsky With Linear Decay And Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z / (i * xy) + Offset | |
| Sag For Asphere 0 Borisovsky With Linear Growth 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z * (h * xy) + Offset | |
| Sag For Asphere 0 With Linear Growth 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z * (f * xy) + Offset | |
| Sag For Asphere 0 Borisovsky With Linear Growth And Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = z * (i * xy) + Offset | |
| Reciprocal Sag For Asphere 0 3D | s2 = x2 + y2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = 1.0 / z | |
| Reciprocal Sag For Asphere 0 Borisovsky 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = 1.0 / z | |
| Reciprocal Sag For Asphere 0 Borisovsky With Offset 3D | s2 = (x - a)2 + (y - b)2 z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + offset z = 1.0 / z + Offset | |
| Extreme Value A 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) | |
| Extreme Value B 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) | |
| Gaussian A 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) | |
| Gaussian B 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) | |
| Log-Normal A 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) | |
| Log-Normal B 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) | |
| Logistic A 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) | |
| Logistic B 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) | |
| Lorentzian A 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) | |
| Lorentzian B 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) | |
| Extreme Value A With Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) + Offset | |
| Extreme Value B With Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) + Offset | |
| Gaussian A With Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) + Offset | |
| Gaussian B With Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) + Offset | |
| Log-Normal A With Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) + Offset | |
| Log-Normal B With Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) + Offset | |
| Logistic A With Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) + Offset | |
| Logistic B With Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) + Offset | |
| Lorentzian A With Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) + Offset | |
| Lorentzian B With Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) + Offset | |
| Extreme Value A With Exponential Decay 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z / (i * exp(xy)) | |
| Extreme Value B With Exponential Decay 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z / exp(xy) | |
| Gaussian A With Exponential Decay 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z / exp(xy) | |
| Gaussian B With Exponential Decay 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z / (i * exp(xy)) | |
| Log-Normal A With Exponential Decay 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z / exp(xy) | |
| Log-Normal B With Exponential Decay 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z / (i * exp(xy)) | |
| Logistic A With Exponential Decay 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z / (i * exp(xy)) | |
| Logistic B With Exponential Decay 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z / exp(xy) | |
| Lorentzian A With Exponential Decay 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z / exp(xy) | |
| Lorentzian B With Exponential Decay 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z / exp(xy) | |
| Extreme Value A With Exponential Decay And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z / (j * exp(xy)) + Offset | |
| Extreme Value B With Exponential Decay And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z / exp(xy) + Offset | |
| Gaussian A With Exponential Decay And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z / exp(xy) + Offset | |
| Gaussian B With Exponential Decay And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z / (j * exp(xy)) + Offset | |
| Log-Normal A With Exponential Decay And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z / exp(xy) + Offset | |
| Log-Normal B With Exponential Decay And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z / (j * exp(xy)) + Offset | |
| Logistic A With Exponential Decay And Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z / (j * exp(xy)) + Offset | |
| Logistic B With Exponential Decay And Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z / exp(xy) + Offset | |
| Lorentzian A With Exponential Decay And Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z / exp(xy) + Offset | |
| Lorentzian B With Exponential Decay And Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z / exp(xy) + Offset | |
| Extreme Value A With Exponential Growth 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z * (i * exp(xy)) | |
| Extreme Value B With Exponential Growth 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z * exp(xy) | |
| Gaussian A With Exponential Growth 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z * exp(xy) | |
| Gaussian B With Exponential Growth 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z * (i * exp(xy)) | |
| Log-Normal A With Exponential Growth 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z * exp(xy) | |
| Log-Normal B With Exponential Growth 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z * (i * exp(xy)) | |
| Logistic A With Exponential Growth 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z * (i * exp(xy)) | |
| Logistic B With Exponential Growth 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z * exp(xy) | |
| Lorentzian A With Exponential Growth 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z * exp(xy) | |
| Lorentzian B With Exponential Growth 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z * exp(xy) | |
| Extreme Value A With Exponential Growth And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z * (j * exp(xy)) + Offset | |
| Extreme Value B With Exponential Growth And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z * exp(xy) + Offset | |
| Gaussian A With Exponential Growth And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z * exp(xy) + Offset | |
| Gaussian B With Exponential Growth And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z * (j * exp(xy)) + Offset | |
| Log-Normal A With Exponential Growth And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z * exp(xy) + Offset | |
| Log-Normal B With Exponential Growth And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z * (j * exp(xy)) + Offset | |
| Logistic A With Exponential Growth And Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z * (j * exp(xy)) + Offset | |
| Logistic B With Exponential Growth And Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z * exp(xy) + Offset | |
| Lorentzian A With Exponential Growth And Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z * exp(xy) + Offset | |
| Lorentzian B With Exponential Growth And Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z * exp(xy) + Offset | |
| Inverse Extreme Value A 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = xy / z | |
| Inverse Extreme Value B 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = xy / z | |
| Inverse Gaussian A 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = xy / z | |
| Inverse Gaussian B 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = xy / z | |
| Inverse Log-Normal A 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = xy / z | |
| Inverse Log-Normal B 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = xy / z | |
| Inverse Logistic A 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = xy / z | |
| Inverse Logistic B 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = xy / z | |
| Inverse Lorentzian A 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = xy / z | |
| Inverse Lorentzian B 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = xy / z | |
| Inverse Extreme Value A With Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = xy / (z + Offset | |
| Inverse Extreme Value B With Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = xy / (z + Offset | |
| Inverse Gaussian A With Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = xy / (z + Offset | |
| Inverse Gaussian B With Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = xy / (z + Offset | |
| Inverse Log-Normal A With Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = xy / (z + Offset | |
| Inverse Log-Normal B With Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = xy / (z + Offset | |
| Inverse Logistic A With Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = xy / (z + Offset | |
| Inverse Logistic B With Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = xy / (z + Offset | |
| Inverse Lorentzian A With Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = xy / (z + Offset | |
| Inverse Lorentzian B With Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = xy / (z + Offset | |
| Extreme Value A With Linear Decay 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z / (i * xy) | |
| Extreme Value B With Linear Decay 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z / xy | |
| Gaussian A With Linear Decay 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z / xy | |
| Gaussian B With Linear Decay 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z / (i * xy) | |
| Log-Normal A With Linear Decay 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z / xy | |
| Log-Normal B With Linear Decay 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z / (i * xy) | |
| Logistic A With Linear Decay 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z / (i * xy) | |
| Logistic B With Linear Decay 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z / xy | |
| Lorentzian A With Linear Decay 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z / xy | |
| Lorentzian B With Linear Decay 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z / xy | |
| Extreme Value A With Linear Decay And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z / (j * xy) + Offset | |
| Extreme Value B With Linear Decay And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z / xy + Offset | |
| Gaussian A With Linear Decay And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z / xy + Offset | |
| Gaussian B With Linear Decay And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z / (j * xy) + Offset | |
| Log-Normal A With Linear Decay And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z / xy + Offset | |
| Log-Normal B With Linear Decay And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z / (j * xy) + Offset | |
| Logistic A With Linear Decay And Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z / (j * xy) + Offset | |
| Logistic B With Linear Decay And Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z / xy + Offset | |
| Lorentzian A With Linear Decay And Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z / xy + Offset | |
| Lorentzian B With Linear Decay And Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z / xy + Offset | |
| Extreme Value A With Linear Growth 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z * (i * xy) + Offset | |
| Extreme Value B With Linear Growth 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z * xy | |
| Gaussian A With Linear Growth 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z * xy | |
| Gaussian B With Linear Growth 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z * (i * xy) + Offset | |
| Log-Normal A With Linear Growth 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z * xy | |
| Log-Normal B With Linear Growth 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z * (i * xy) + Offset | |
| Logistic A With Linear Growth 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z * (i * xy) + Offset | |
| Logistic B With Linear Growth 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z * xy | |
| Lorentzian A With Linear Growth 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z * xy | |
| Lorentzian B With Linear Growth 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z * xy | |
| Extreme Value A With Linear Growth And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = z * (j * xy) + Offset | |
| Extreme Value B With Linear Growth And Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = z * xy + Offset | |
| Gaussian A With Linear Growth And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = z * xy + Offset | |
| Gaussian B With Linear Growth And Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = z * (j * xy) + Offset | |
| Log-Normal A With Linear Growth And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = z * xy + Offset | |
| Log-Normal B With Linear Growth And Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = z * (j * xy) + Offset | |
| Logistic A With Linear Growth And Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = z * (j * xy) + Offset | |
| Logistic B With Linear Growth And Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = z * xy + Offset | |
| Lorentzian A With Linear Growth And Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = z * xy + Offset | |
| Lorentzian B With Linear Growth And Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = z * xy + Offset | |
| Reciprocal Extreme Value A 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = 1.0 / z | |
| Reciprocal Extreme Value B 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = 1.0 / z | |
| Reciprocal Gaussian A 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = 1.0 / z | |
| Reciprocal Gaussian B 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = 1.0 / z | |
| Reciprocal Log-Normal A 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = 1.0 / z | |
| Reciprocal Log-Normal B 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = 1.0 / z | |
| Reciprocal Logistic A 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = 1.0 / z | |
| Reciprocal Logistic B 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = 1.0 / z | |
| Reciprocal Lorentzian A 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = 1.0 / z | |
| Reciprocal Lorentzian B 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = 1.0 / z | |
| Reciprocal Extreme Value A With Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) + d * exp(-exp(-(y-f)/g)-(y-f)/g+1) z = 1.0 / z + Offset | |
| Reciprocal Extreme Value B With Offset 3D | z = a * exp(-exp(-(x-b)/c)-(x-b)/c+1) * exp(-exp(-(y-d)/f)-(y-d)/f+1) z = 1.0 / z + Offset | |
| Reciprocal Gaussian A With Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2 + ((y-d)/f)2)) z = 1.0 / z + Offset | |
| Reciprocal Gaussian B With Offset 3D | z = a * exp(-0.5 * (((x-b)/c)2)) + d * exp(-0.5 * (((y-f)/g)2)) z = 1.0 / z + Offset | |
| Reciprocal Log-Normal A With Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2 + ((ln(y)-d)/f)2)) z = 1.0 / z + Offset | |
| Reciprocal Log-Normal B With Offset 3D | z = a * exp(-0.5 * (((ln(x)-b)/c)2)) + d * exp(-0.5 * (((ln(y)-f)/g)2)) z = 1.0 / z + Offset | |
| Reciprocal Logistic A With Offset 3D | z = 4a * exp(-((x-b)/c))/((1+exp(-((x-b)/c)))2) + 4d * exp(-((y-f)/g))/((1+exp(-((y-f)/g)))2) z = 1.0 / z + Offset | |
| Reciprocal Logistic B With Offset 3D | z = 16a * exp(-((x-b)/c)-((y-d)/f)) / ((1+exp(-((x-b)/c)))2 * (1+exp(-((y-d)/f)))2) z = 1.0 / z + Offset | |
| Reciprocal Lorentzian A With Offset 3D | z = a / ((1+((x-b)/c)2)*(1+((y-d)/f)2)) z = 1.0 / z + Offset | |
| Reciprocal Lorentzian B With Offset 3D | z = a / (1+((x-b)/c)2) + d * (1+((y-f)/g)2) z = 1.0 / z + Offset | |
| User-Selectable Polyfunctional 3D | z = user-selectable function | |
| Full Cubic 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 | |
| Full Quadratic 3D | z = a + bx + cy + dx2 + fy2 + gxy | |
| Linear 3D | z = a + bx + cy | |
| Simplified Cubic 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 | |
| Simplified Quadratic 3D | z = a + bx + cy + dx2 + fy2 | |
| User-Selectable Polynomial 3D | z = user-selectable polynomial | |
| Full Cubic With Exponential Decay 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 z = z / (n * exp(xy)) | |
| Full Quadratic With Exponential Decay 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z / (i * exp(xy)) | |
| Linear With Exponential Decay 3D | z = a + bx + cy z = z / (f * exp(xy)) | |
| Simplified Cubic With Exponential Decay 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 z = z / (j * exp(xy)) | |
| Simplified Quadratic With Exponential Decay 3D | z = a + bx + cy + dx2 + fy2 z = z / (h * exp(xy)) | |
| User-Selectable Polynomial With Exponential Decay 3D | z = user-selectable polynomial z = z / (exp(xy)) | |
| Full Cubic With Exponential Growth 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 z = z * (n * exp(xy)) | |
| Full Quadratic With Exponential Growth 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z * (i * exp(xy)) | |
| Linear With Exponential Growth 3D | z = a + bx + cy z = z * (f * exp(xy)) | |
| Simplified Cubic With Exponential Growth 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 z = z * (j * exp(xy)) | |
| Simplified Quadratic With Exponential Growth 3D | z = a + bx + cy + dx2 + fy2 z = z * (h * exp(xy)) | |
| User-Selectable Polynomial With Exponential Growth 3D | z = user-selectable polynomial z = z * (exp(xy)) | |
| Inverse Full Cubic 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 z = xy / z | |
| Inverse Full Quadratic 3D | z = a + bx + cy + dx2 + fy2 + gxy z = xy / z | |
| Inverse Linear 3D | z = a + bx + cy z = xy / z | |
| Inverse Simplified Cubic 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 z = xy / z | |
| Inverse Simplified Quadratic 3D | z = a + bx + cy + dx2 + fy2 z = xy / z | |
| Inverse User-Selectable Polynomial 3D | z = user-selectable polynomial z = xy / z | |
| Full Cubic With Linear Decay 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 z = z / (n * xy) | |
| Full Quadratic With Linear Decay 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z / (i * xy) | |
| Linear With Linear Decay 3D | z = a + bx + cy z = z / (f * xy) | |
| Simplified Cubic With Linear Decay 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 z = z / (j * xy) | |
| Simplified Quadratic With Linear Decay 3D | z = a + bx + cy + dx2 + fy2 z = z / (h * xy) | |
| User-Selectable Polynomial With Linear Decay 3D | z = user-selectable polynomial z = z / (xy) | |
| Full Cubic With Linear Growth 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 z = z * (n * xy) + Offset | |
| Full Quadratic With Linear Growth 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z * (i * xy) + Offset | |
| Linear With Linear Growth 3D | z = a + bx + cy z = z * (f * xy) + Offset | |
| Simplified Cubic With Linear Growth 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 z = z * (j * xy) + Offset | |
| Simplified Quadratic With Linear Growth 3D | z = a + bx + cy + dx2 + fy2 z = z * (h * xy) + Offset | |
| User-Selectable Polynomial With Linear Growth 3D | z = user-selectable polynomial z = z * (xy) + Offset | |
| Reciprocal Full Cubic 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 + ixy + jx2y + kxy2 z = 1.0 / z | |
| Reciprocal Full Quadratic 3D | z = a + bx + cy + dx2 + fy2 + gxy z = 1.0 / z | |
| Reciprocal Linear 3D | z = a + bx + cy z = 1.0 / z | |
| Reciprocal Simplified Cubic 3D | z = a + bx + cy + dx2 + fy2 + gx3 + hy3 z = 1.0 / z | |
| Reciprocal Simplified Quadratic 3D | z = a + bx + cy + dx2 + fy2 z = 1.0 / z | |
| Power A 3D | z = a * (xb + yc) | |
| Power A Transform 3D | z = a * ((dx + f)b + (gy + h)c) | |
| Power B 3D | z = a + xb + yc | |
| Power B Transform 3D | z = a + (dx + f)b + (gy + h)c | |
| Power C 3D | z = a + xb * yc | |
| Power C Transform 3D | z = a + (dx + f)b * (gy + h)c | |
| Power D 3D | z = axb + cyd | |
| Power D Transform 3D | z = a(fx + g)b + c(hy + i)d | |
| Power E 3D | z = a * xb * yc | |
| Power E Transform 3D | z = a * (dx + f)b * (gy + h)c | |
| Power A Transform With Offset 3D | z = a * ((dx + f)b + (gy + h)c) + Offset | |
| Power A With Offset 3D | z = a * (xb + yc) + Offset | |
| Power D Transform With Offset 3D | z = a(fx + g)b + c(hy + i)d + Offset | |
| Power D With Offset 3D | z = axb + cyd + Offset | |
| Power E Transform With Offset 3D | z = a * (dx + f)b * (gy + h)c + Offset | |
| Power E With Offset 3D | z = a * xb * yc + Offset | |
| Power A Transform With Exponential Decay 3D | z = a * ((dx + f)b + (gy + h)c) z = z / exp(xy) | |
| Power A With Exponential Decay 3D | z = a * (xb + yc) z = z / exp(xy) | |
| Power B Transform With Exponential Decay 3D | z = a + (dx + f)b + (gy + h)c z = z / (j * exp(xy)) | |
| Power B With Exponential Decay 3D | z = a + xb + yc z = z / (f * exp(xy)) | |
| Power C Transform With Exponential Decay 3D | z = a + (dx + f)b * (gy + h)c z = z / (j * exp(xy)) | |
| Power C With Exponential Decay 3D | z = a + xb * yc z = z / (f * exp(xy)) | |
| Power D Transform With Exponential Decay 3D | z = a(fx + g)b + c(hy + i)d z = z / (k * exp(xy)) | |
| Power D With Exponential Decay 3D | z = axb + cyd z = z / (g * exp(xy)) | |
| Power E Transform With Exponential Decay 3D | z = a * (dx + f)b * (gy + h)c z = z / exp(xy) | |
| Power E With Exponential Decay 3D | z = a * xb * yc z = z / exp(xy) | |
| Power A Transform With Exponential Decay And Offset 3D | z = a * ((dx + f)b + (gy + h)c) z = z / exp(xy) + Offset | |
| Power A With Exponential Decay And Offset 3D | z = a * (xb + yc) z = z / exp(xy) + Offset | |
| Power D Transform With Exponential Decay And Offset 3D | z = a(fx + g)b + c(hy + i)d z = z / (m * exp(xy)) + Offset | |
| Power D With Exponential Decay And Offset 3D | z = axb + cyd z = z / (h * exp(xy)) + Offset | |
| Power E Transform With Exponential Decay And Offset 3D | z = a * (dx + f)b * (gy + h)c z = z / exp(xy) + Offset | |
| Power E With Exponential Decay And Offset 3D | z = a * xb * yc z = z / exp(xy) + Offset | |
| Power A Transform With Exponential Growth 3D | z = a * ((dx + f)b + (gy + h)c) z = z * exp(xy) | |
| Power A With Exponential Growth 3D | z = a * (xb + yc) z = z * exp(xy) | |
| Power B Transform With Exponential Growth 3D | z = a + (dx + f)b + (gy + h)c z = z * (j * exp(xy)) | |
| Power B With Exponential Growth 3D | z = a + xb + yc z = z * (f * exp(xy)) | |
| Power C Transform With Exponential Growth 3D | z = a + (dx + f)b * (gy + h)c z = z * (j * exp(xy)) | |
| Power C With Exponential Growth 3D | z = a + xb * yc z = z * (f * exp(xy)) | |
| Power D Transform With Exponential Growth 3D | z = a(fx + g)b + c(hy + i)d z = z * (k * exp(xy)) | |
| Power D With Exponential Growth 3D | z = axb + cyd z = z * (g * exp(xy)) | |
| Power E Transform With Exponential Growth 3D | z = a * (dx + f)b * (gy + h)c z = z * exp(xy) | |
| Power E With Exponential Growth 3D | z = a * xb * yc z = z * exp(xy) | |
| Power A Transform With Exponential Growth And Offset 3D | z = a * ((dx + f)b + (gy + h)c) z = z * exp(xy) + Offset | |
| Power A With Exponential Growth And Offset 3D | z = a * (xb + yc) z = z * exp(xy) + Offset | |
| Power D Transform With Exponential Growth And Offset 3D | z = a(fx + g)b + c(hy + i)d z = z * (m * exp(xy)) + Offset | |
| Power D With Exponential Growth And Offset 3D | z = axb + cyd z = z * (h * exp(xy)) + Offset | |
| Power E Transform With Exponential Growth And Offset 3D | z = a * (dx + f)b * (gy + h)c z = z * exp(xy) + Offset | |
| Power E With Exponential Growth And Offset 3D | z = a * xb * yc z = z * exp(xy) + Offset | |
| Inverse Power A 3D | z = a * (xb + yc) z = xy / z | |
| Inverse Power A Transform 3D | z = a * ((dx + f)b + (gy + h)c) z = xy / z | |
| Inverse Power B 3D | z = a + xb + yc z = xy / z | |
| Inverse Power B Transform 3D | z = a + (dx + f)b + (gy + h)c z = xy / z | |
| Inverse Power C 3D | z = a + xb * yc z = xy / z | |
| Inverse Power C Transform 3D | z = a + (dx + f)b * (gy + h)c z = xy / z | |
| Inverse Power D 3D | z = axb + cyd z = xy / z | |
| Inverse Power D Transform 3D | z = a(fx + g)b + c(hy + i)d z = xy / z | |
| Inverse Power E 3D | z = a * xb * yc z = xy / z | |
| Inverse Power E Transform 3D | z = a * (dx + f)b * (gy + h)c z = xy / z | |
| Inverse Power A Transform With Offset 3D | z = a * ((dx + f)b + (gy + h)c) z = xy / (z + Offset | |
| Inverse Power A With Offset 3D | z = a * (xb + yc) z = xy / (z + Offset | |
| Inverse Power D Transform With Offset 3D | z = a(fx + g)b + c(hy + i)d z = xy / (z + Offset | |
| Inverse Power D With Offset 3D | z = axb + cyd z = xy / (z + Offset | |
| Inverse Power E Transform With Offset 3D | z = a * (dx + f)b * (gy + h)c z = xy / (z + Offset | |
| Inverse Power E With Offset 3D | z = a * xb * yc z = xy / (z + Offset | |
| Power A Transform With Linear Decay 3D | z = a * ((dx + f)b + (gy + h)c) z = z / xy | |
| Power A With Linear Decay 3D | z = a * (xb + yc) z = z / xy | |
| Power B Transform With Linear Decay 3D | z = a + (dx + f)b + (gy + h)c z = z / (j * xy) | |
| Power B With Linear Decay 3D | z = a + xb + yc z = z / (f * xy) | |
| Power C Transform With Linear Decay 3D | z = a + (dx + f)b * (gy + h)c z = z / (j * xy) | |
| Power C With Linear Decay 3D | z = a + xb * yc z = z / (f * xy) | |
| Power D Transform With Linear Decay 3D | z = a(fx + g)b + c(hy + i)d z = z / (k * xy) | |
| Power D With Linear Decay 3D | z = axb + cyd z = z / (g * xy) | |
| Power E Transform With Linear Decay 3D | z = a * (dx + f)b * (gy + h)c z = z / xy | |
| Power E With Linear Decay 3D | z = a * xb * yc z = z / xy | |
| Power A Transform With Linear Decay And Offset 3D | z = a * ((dx + f)b + (gy + h)c) z = z / xy + Offset | |
| Power A With Linear Decay And Offset 3D | z = a * (xb + yc) z = z / xy + Offset | |
| Power D Transform With Linear Decay And Offset 3D | z = a(fx + g)b + c(hy + i)d z = z / (m * xy) + Offset | |
| Power D With Linear Decay And Offset 3D | z = axb + cyd z = z / (h * xy) + Offset | |
| Power E Transform With Linear Decay And Offset 3D | z = a * (dx + f)b * (gy + h)c z = z / xy + Offset | |
| Power E With Linear Decay And Offset 3D | z = a * xb * yc z = z / xy + Offset | |
| Power A Transform With Linear Growth 3D | z = a * ((dx + f)b + (gy + h)c) z = z * xy | |
| Power A With Linear Growth 3D | z = a * (xb + yc) z = z * xy | |
| Power B Transform With Linear Growth 3D | z = a + (dx + f)b + (gy + h)c z = z * (j * xy) + Offset | |
| Power B With Linear Growth 3D | z = a + xb + yc z = z * (f * xy) + Offset | |
| Power C Transform With Linear Growth 3D | z = a + (dx + f)b * (gy + h)c z = z * (j * xy) + Offset | |
| Power C With Linear Growth 3D | z = a + xb * yc z = z * (f * xy) + Offset | |
| Power D Transform With Linear Growth 3D | z = a(fx + g)b + c(hy + i)d z = z * (k * xy) + Offset | |
| Power D With Linear Growth 3D | z = axb + cyd z = z * (g * xy) + Offset | |
| Power E Transform With Linear Growth 3D | z = a * (dx + f)b * (gy + h)c z = z * xy | |
| Power E With Linear Growth 3D | z = a * xb * yc z = z * xy | |
| Power A Transform With Linear Growth And Offset 3D | z = a * ((dx + f)b + (gy + h)c) z = z * xy + Offset | |
| Power A With Linear Growth And Offset 3D | z = a * (xb + yc) z = z * xy + Offset | |
| Power D Transform With Linear Growth And Offset 3D | z = a(fx + g)b + c(hy + i)d z = z * (m * xy) + Offset | |
| Power D With Linear Growth And Offset 3D | z = axb + cyd z = z * (h * xy) + Offset | |
| Power E Transform With Linear Growth And Offset 3D | z = a * (dx + f)b * (gy + h)c z = z * xy + Offset | |
| Power E With Linear Growth And Offset 3D | z = a * xb * yc z = z * xy + Offset | |
| Reciprocal Power A 3D | z = a * (xb + yc) z = 1.0 / z | |
| Reciprocal Power A Transform 3D | z = a * ((dx + f)b + (gy + h)c) z = 1.0 / z | |
| Reciprocal Power B 3D | z = a + xb + yc z = 1.0 / z | |
| Reciprocal Power B Transform 3D | z = a + (dx + f)b + (gy + h)c z = 1.0 / z | |
| Reciprocal Power C 3D | z = a + xb * yc z = 1.0 / z | |
| Reciprocal Power C Transform 3D | z = a + (dx + f)b * (gy + h)c z = 1.0 / z | |
| Reciprocal Power D 3D | z = axb + cyd z = 1.0 / z | |
| Reciprocal Power D Transform 3D | z = a(fx + g)b + c(hy + i)d z = 1.0 / z | |
| Reciprocal Power E 3D | z = a * xb * yc z = 1.0 / z | |
| Reciprocal Power E Transform 3D | z = a * (dx + f)b * (gy + h)c z = 1.0 / z | |
| Reciprocal Power A Transform With Offset 3D | z = a * ((dx + f)b + (gy + h)c) z = 1.0 / z + Offset | |
| Reciprocal Power A With Offset 3D | z = a * (xb + yc) z = 1.0 / z + Offset | |
| Reciprocal Power D Transform With Offset 3D | z = a(fx + g)b + c(hy + i)d z = 1.0 / z + Offset | |
| Reciprocal Power D With Offset 3D | z = axb + cyd z = 1.0 / z + Offset | |
| Reciprocal Power E Transform With Offset 3D | z = a * (dx + f)b * (gy + h)c z = 1.0 / z + Offset | |
| Reciprocal Power E With Offset 3D | z = a * xb * yc z = 1.0 / z + Offset | |
| Rational A 3D | z = (a + bx + cy)/(1 + dx + fy) | |
| Rational B 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) | |
| Rational C 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) | |
| Rational D 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) | |
| Rational E 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) | |
| Rational F 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) | |
| Rational G 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) | |
| Rational H 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) | |
| Rational I 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) | |
| Rational J 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) | |
| Rational K 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) | |
| Rational L 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) | |
| Rational M 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) | |
| Rational N 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) | |
| Rational O 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) | |
| Rational P 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) | |
| Rational Q 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) | |
| Rational R 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) | |
| Rational S 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) | |
| Rational T 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) | |
| Rational U 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) | |
| Rational V 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) | |
| Rational W 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) | |
| Rational X 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) | |
| Rational Y 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) | |
| Rational Z 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) | |
| Rational A With Offset 3D | z = (a + bx + cy)/(1 + dx + fy) + Offset | |
| Rational B With Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) + Offset | |
| Rational C With Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) + Offset | |
| Rational D With Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) + Offset | |
| Rational E With Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) + Offset | |
| Rational F With Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) + Offset | |
| Rational G With Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) + Offset | |
| Rational H With Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) + Offset | |
| Rational I With Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) + Offset | |
| Rational J With Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) + Offset | |
| Rational K With Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) + Offset | |
| Rational L With Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) + Offset | |
| Rational M With Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) + Offset | |
| Rational N With Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) + Offset | |
| Rational O With Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) + Offset | |
| Rational P With Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) + Offset | |
| Rational Q With Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) + Offset | |
| Rational R With Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) + Offset | |
| Rational S With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) + Offset | |
| Rational T With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) + Offset | |
| Rational U With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) + Offset | |
| Rational V With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) + Offset | |
| Rational W With Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) + Offset | |
| Rational X With Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) + Offset | |
| Rational Y With Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) + Offset | |
| Rational Z With Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) + Offset | |
| Rational A With Exponential Decay 3D | z = (a + bx + cy)/(1 + dx + fy) z = z / (h * exp(xy)) | |
| Rational B With Exponential Decay 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z / (h * exp(xy)) | |
| Rational C With Exponential Decay 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z / (h * exp(xy)) | |
| Rational D With Exponential Decay 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z / (h * exp(xy)) | |
| Rational E With Exponential Decay 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z / (h * exp(xy)) | |
| Rational F With Exponential Decay 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z / (h * exp(xy)) | |
| Rational G With Exponential Decay 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z / (h * exp(xy)) | |
| Rational H With Exponential Decay 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z / (h * exp(xy)) | |
| Rational I With Exponential Decay 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z / (h * exp(xy)) | |
| Rational J With Exponential Decay 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z / (h * exp(xy)) | |
| Rational K With Exponential Decay 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z / (h * exp(xy)) | |
| Rational L With Exponential Decay 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z / (h * exp(xy)) | |
| Rational M With Exponential Decay 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z / (h * exp(xy)) | |
| Rational N With Exponential Decay 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z / (j * exp(xy)) | |
| Rational O With Exponential Decay 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z / (j * exp(xy)) | |
| Rational P With Exponential Decay 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z / (j * exp(xy)) | |
| Rational Q With Exponential Decay 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z / (j * exp(xy)) | |
| Rational R With Exponential Decay 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z / (j * exp(xy)) | |
| Rational S With Exponential Decay 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (j * exp(xy)) | |
| Rational T With Exponential Decay 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (j * exp(xy)) | |
| Rational U With Exponential Decay 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (j * exp(xy)) | |
| Rational V With Exponential Decay 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (j * exp(xy)) | |
| Rational W With Exponential Decay 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (j * exp(xy)) | |
| Rational X With Exponential Decay 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (j * exp(xy)) | |
| Rational Y With Exponential Decay 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (j * exp(xy)) | |
| Rational Z With Exponential Decay 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (j * exp(xy)) | |
| Rational A With Exponential Decay And Offset 3D | z = (a + bx + cy)/(1 + dx + fy) z = z / (i * exp(xy)) + Offset | |
| Rational B With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z / (i * exp(xy)) + Offset | |
| Rational C With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z / (i * exp(xy)) + Offset | |
| Rational D With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z / (i * exp(xy)) + Offset | |
| Rational E With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z / (i * exp(xy)) + Offset | |
| Rational F With Exponential Decay And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z / (i * exp(xy)) + Offset | |
| Rational G With Exponential Decay And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z / (i * exp(xy)) + Offset | |
| Rational H With Exponential Decay And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z / (i * exp(xy)) + Offset | |
| Rational I With Exponential Decay And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z / (i * exp(xy)) + Offset | |
| Rational J With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z / (i * exp(xy)) + Offset | |
| Rational K With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z / (i * exp(xy)) + Offset | |
| Rational L With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z / (i * exp(xy)) + Offset | |
| Rational M With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z / (i * exp(xy)) + Offset | |
| Rational N With Exponential Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z / (k * exp(xy)) + Offset | |
| Rational O With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z / (k * exp(xy)) + Offset | |
| Rational P With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z / (k * exp(xy)) + Offset | |
| Rational Q With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z / (k * exp(xy)) + Offset | |
| Rational R With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z / (k * exp(xy)) + Offset | |
| Rational S With Exponential Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (k * exp(xy)) + Offset | |
| Rational T With Exponential Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (k * exp(xy)) + Offset | |
| Rational U With Exponential Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (k * exp(xy)) + Offset | |
| Rational V With Exponential Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (k * exp(xy)) + Offset | |
| Rational W With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (k * exp(xy)) + Offset | |
| Rational X With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (k * exp(xy)) + Offset | |
| Rational Y With Exponential Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (k * exp(xy)) + Offset | |
| Rational Z With Exponential Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (k * exp(xy)) + Offset | |
| Rational A With Exponential Growth 3D | z = (a + bx + cy)/(1 + dx + fy) z = z * (h * exp(xy)) | |
| Rational B With Exponential Growth 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z * (h * exp(xy)) | |
| Rational C With Exponential Growth 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z * (h * exp(xy)) | |
| Rational D With Exponential Growth 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z * (h * exp(xy)) | |
| Rational E With Exponential Growth 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z * (h * exp(xy)) | |
| Rational F With Exponential Growth 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z * (h * exp(xy)) | |
| Rational G With Exponential Growth 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z * (h * exp(xy)) | |
| Rational H With Exponential Growth 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z * (h * exp(xy)) | |
| Rational I With Exponential Growth 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z * (h * exp(xy)) | |
| Rational J With Exponential Growth 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z * (h * exp(xy)) | |
| Rational K With Exponential Growth 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z * (h * exp(xy)) | |
| Rational L With Exponential Growth 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z * (h * exp(xy)) | |
| Rational M With Exponential Growth 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z * (h * exp(xy)) | |
| Rational N With Exponential Growth 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z * (j * exp(xy)) | |
| Rational O With Exponential Growth 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z * (j * exp(xy)) | |
| Rational P With Exponential Growth 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z * (j * exp(xy)) | |
| Rational Q With Exponential Growth 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z * (j * exp(xy)) | |
| Rational R With Exponential Growth 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z * (j * exp(xy)) | |
| Rational S With Exponential Growth 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (j * exp(xy)) | |
| Rational T With Exponential Growth 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (j * exp(xy)) | |
| Rational U With Exponential Growth 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (j * exp(xy)) | |
| Rational V With Exponential Growth 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (j * exp(xy)) | |
| Rational W With Exponential Growth 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (j * exp(xy)) | |
| Rational X With Exponential Growth 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (j * exp(xy)) | |
| Rational Y With Exponential Growth 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (j * exp(xy)) | |
| Rational Z With Exponential Growth 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (j * exp(xy)) | |
| Rational A With Exponential Growth And Offset 3D | z = (a + bx + cy)/(1 + dx + fy) z = z * (i * exp(xy)) + Offset | |
| Rational B With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z * (i * exp(xy)) + Offset | |
| Rational C With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z * (i * exp(xy)) + Offset | |
| Rational D With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z * (i * exp(xy)) + Offset | |
| Rational E With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z * (i * exp(xy)) + Offset | |
| Rational F With Exponential Growth And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z * (i * exp(xy)) + Offset | |
| Rational G With Exponential Growth And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z * (i * exp(xy)) + Offset | |
| Rational H With Exponential Growth And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z * (i * exp(xy)) + Offset | |
| Rational I With Exponential Growth And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z * (i * exp(xy)) + Offset | |
| Rational J With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z * (i * exp(xy)) + Offset | |
| Rational K With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z * (i * exp(xy)) + Offset | |
| Rational L With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z * (i * exp(xy)) + Offset | |
| Rational M With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z * (i * exp(xy)) + Offset | |
| Rational N With Exponential Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z * (k * exp(xy)) + Offset | |
| Rational O With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z * (k * exp(xy)) + Offset | |
| Rational P With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z * (k * exp(xy)) + Offset | |
| Rational Q With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z * (k * exp(xy)) + Offset | |
| Rational R With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z * (k * exp(xy)) + Offset | |
| Rational S With Exponential Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (k * exp(xy)) + Offset | |
| Rational T With Exponential Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (k * exp(xy)) + Offset | |
| Rational U With Exponential Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (k * exp(xy)) + Offset | |
| Rational V With Exponential Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (k * exp(xy)) + Offset | |
| Rational W With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (k * exp(xy)) + Offset | |
| Rational X With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (k * exp(xy)) + Offset | |
| Rational Y With Exponential Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (k * exp(xy)) + Offset | |
| Rational Z With Exponential Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (k * exp(xy)) + Offset | |
| Inverse Rational A 3D | z = (a + bx + cy)/(1 + dx + fy) z = xy / z | |
| Inverse Rational B 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = xy / z | |
| Inverse Rational C 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = xy / z | |
| Inverse Rational D 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = xy / z | |
| Inverse Rational E 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = xy / z | |
| Inverse Rational F 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = xy / z | |
| Inverse Rational G 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = xy / z | |
| Inverse Rational H 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = xy / z | |
| Inverse Rational I 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = xy / z | |
| Inverse Rational J 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = xy / z | |
| Inverse Rational K 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = xy / z | |
| Inverse Rational L 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = xy / z | |
| Inverse Rational M 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = xy / z | |
| Inverse Rational N 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = xy / z | |
| Inverse Rational O 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = xy / z | |
| Inverse Rational P 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = xy / z | |
| Inverse Rational Q 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = xy / z | |
| Inverse Rational R 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = xy / z | |
| Inverse Rational S 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = xy / z | |
| Inverse Rational T 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = xy / z | |
| Inverse Rational U 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = xy / z | |
| Inverse Rational V 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = xy / z | |
| Inverse Rational W 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = xy / z | |
| Inverse Rational X 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = xy / z | |
| Inverse Rational Y 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = xy / z | |
| Inverse Rational Z 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = xy / z | |
| Inverse Rational A With Offset 3D | z = (a + bx + cy)/(1 + dx + fy) z = xy / (z + Offset | |
| Inverse Rational B With Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = xy / (z + Offset | |
| Inverse Rational C With Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = xy / (z + Offset | |
| Inverse Rational D With Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = xy / (z + Offset | |
| Inverse Rational E With Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = xy / (z + Offset | |
| Inverse Rational F With Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = xy / (z + Offset | |
| Inverse Rational G With Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = xy / (z + Offset | |
| Inverse Rational H With Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = xy / (z + Offset | |
| Inverse Rational I With Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = xy / (z + Offset | |
| Inverse Rational J With Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = xy / (z + Offset | |
| Inverse Rational K With Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = xy / (z + Offset | |
| Inverse Rational L With Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = xy / (z + Offset | |
| Inverse Rational M With Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = xy / (z + Offset | |
| Inverse Rational N With Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = xy / (z + Offset | |
| Inverse Rational O With Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = xy / (z + Offset | |
| Inverse Rational P With Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = xy / (z + Offset | |
| Inverse Rational Q With Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = xy / (z + Offset | |
| Inverse Rational R With Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = xy / (z + Offset | |
| Inverse Rational S With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = xy / (z + Offset | |
| Inverse Rational T With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = xy / (z + Offset | |
| Inverse Rational U With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = xy / (z + Offset | |
| Inverse Rational V With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = xy / (z + Offset | |
| Inverse Rational W With Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = xy / (z + Offset | |
| Inverse Rational X With Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = xy / (z + Offset | |
| Inverse Rational Y With Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = xy / (z + Offset | |
| Inverse Rational Z With Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = xy / (z + Offset | |
| Rational A With Linear Decay 3D | z = (a + bx + cy)/(1 + dx + fy) z = z / (h * xy) | |
| Rational B With Linear Decay 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z / (h * xy) | |
| Rational C With Linear Decay 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z / (h * xy) | |
| Rational D With Linear Decay 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z / (h * xy) | |
| Rational E With Linear Decay 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z / (h * xy) | |
| Rational F With Linear Decay 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z / (h * xy) | |
| Rational G With Linear Decay 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z / (h * xy) | |
| Rational H With Linear Decay 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z / (h * xy) | |
| Rational I With Linear Decay 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z / (h * xy) | |
| Rational J With Linear Decay 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z / (h * xy) | |
| Rational K With Linear Decay 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z / (h * xy) | |
| Rational L With Linear Decay 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z / (h * xy) | |
| Rational M With Linear Decay 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z / (h * xy) | |
| Rational N With Linear Decay 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z / (j * xy) | |
| Rational O With Linear Decay 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z / (j * xy) | |
| Rational P With Linear Decay 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z / (j * xy) | |
| Rational Q With Linear Decay 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z / (j * xy) | |
| Rational R With Linear Decay 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z / (j * xy) | |
| Rational S With Linear Decay 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (j * xy) | |
| Rational T With Linear Decay 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (j * xy) | |
| Rational U With Linear Decay 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (j * xy) | |
| Rational V With Linear Decay 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (j * xy) | |
| Rational W With Linear Decay 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (j * xy) | |
| Rational X With Linear Decay 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (j * xy) | |
| Rational Y With Linear Decay 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (j * xy) | |
| Rational Z With Linear Decay 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (j * xy) | |
| Rational A With Linear Decay And Offset 3D | z = (a + bx + cy)/(1 + dx + fy) z = z / (i * xy) + Offset | |
| Rational B With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z / (i * xy) + Offset | |
| Rational C With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z / (i * xy) + Offset | |
| Rational D With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z / (i * xy) + Offset | |
| Rational E With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z / (i * xy) + Offset | |
| Rational F With Linear Decay And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z / (i * xy) + Offset | |
| Rational G With Linear Decay And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z / (i * xy) + Offset | |
| Rational H With Linear Decay And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z / (i * xy) + Offset | |
| Rational I With Linear Decay And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z / (i * xy) + Offset | |
| Rational J With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z / (i * xy) + Offset | |
| Rational K With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z / (i * xy) + Offset | |
| Rational L With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z / (i * xy) + Offset | |
| Rational M With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z / (i * xy) + Offset | |
| Rational N With Linear Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z / (k * xy) + Offset | |
| Rational O With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z / (k * xy) + Offset | |
| Rational P With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z / (k * xy) + Offset | |
| Rational Q With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z / (k * xy) + Offset | |
| Rational R With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z / (k * xy) + Offset | |
| Rational S With Linear Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (k * xy) + Offset | |
| Rational T With Linear Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (k * xy) + Offset | |
| Rational U With Linear Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (k * xy) + Offset | |
| Rational V With Linear Decay And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (k * xy) + Offset | |
| Rational W With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z / (k * xy) + Offset | |
| Rational X With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z / (k * xy) + Offset | |
| Rational Y With Linear Decay And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z / (k * xy) + Offset | |
| Rational Z With Linear Decay And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z / (k * xy) + Offset | |
| Rational A With Linear Growth 3D | z = (a + bx + cy)/(1 + dx + fy) z = z * (h * xy) + Offset | |
| Rational B With Linear Growth 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z * (h * xy) + Offset | |
| Rational C With Linear Growth 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z * (h * xy) + Offset | |
| Rational D With Linear Growth 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z * (h * xy) + Offset | |
| Rational E With Linear Growth 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z * (h * xy) + Offset | |
| Rational F With Linear Growth 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z * (h * xy) + Offset | |
| Rational G With Linear Growth 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z * (h * xy) + Offset | |
| Rational H With Linear Growth 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z * (h * xy) + Offset | |
| Rational I With Linear Growth 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z * (h * xy) + Offset | |
| Rational J With Linear Growth 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z * (h * xy) + Offset | |
| Rational K With Linear Growth 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z * (h * xy) + Offset | |
| Rational L With Linear Growth 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z * (h * xy) + Offset | |
| Rational M With Linear Growth 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z * (h * xy) + Offset | |
| Rational N With Linear Growth 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z * (j * xy) + Offset | |
| Rational O With Linear Growth 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z * (j * xy) + Offset | |
| Rational P With Linear Growth 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z * (j * xy) + Offset | |
| Rational Q With Linear Growth 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z * (j * xy) + Offset | |
| Rational R With Linear Growth 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z * (j * xy) + Offset | |
| Rational S With Linear Growth 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (j * xy) + Offset | |
| Rational T With Linear Growth 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (j * xy) + Offset | |
| Rational U With Linear Growth 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (j * xy) + Offset | |
| Rational V With Linear Growth 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (j * xy) + Offset | |
| Rational W With Linear Growth 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (j * xy) + Offset | |
| Rational X With Linear Growth 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (j * xy) + Offset | |
| Rational Y With Linear Growth 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (j * xy) + Offset | |
| Rational Z With Linear Growth 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (j * xy) + Offset | |
| Rational A With Linear Growth And Offset 3D | z = (a + bx + cy)/(1 + dx + fy) z = z * (i * xy) + Offset | |
| Rational B With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = z * (i * xy) + Offset | |
| Rational C With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = z * (i * xy) + Offset | |
| Rational D With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = z * (i * xy) + Offset | |
| Rational E With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = z * (i * xy) + Offset | |
| Rational F With Linear Growth And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = z * (i * xy) + Offset | |
| Rational G With Linear Growth And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = z * (i * xy) + Offset | |
| Rational H With Linear Growth And Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = z * (i * xy) + Offset | |
| Rational I With Linear Growth And Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = z * (i * xy) + Offset | |
| Rational J With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = z * (i * xy) + Offset | |
| Rational K With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = z * (i * xy) + Offset | |
| Rational L With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = z * (i * xy) + Offset | |
| Rational M With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = z * (i * xy) + Offset | |
| Rational N With Linear Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = z * (k * xy) + Offset | |
| Rational O With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = z * (k * xy) + Offset | |
| Rational P With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = z * (k * xy) + Offset | |
| Rational Q With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = z * (k * xy) + Offset | |
| Rational R With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = z * (k * xy) + Offset | |
| Rational S With Linear Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (k * xy) + Offset | |
| Rational T With Linear Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (k * xy) + Offset | |
| Rational U With Linear Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (k * xy) + Offset | |
| Rational V With Linear Growth And Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (k * xy) + Offset | |
| Rational W With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = z * (k * xy) + Offset | |
| Rational X With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = z * (k * xy) + Offset | |
| Rational Y With Linear Growth And Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = z * (k * xy) + Offset | |
| Rational Z With Linear Growth And Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = z * (k * xy) + Offset | |
| Reciprocal Rational A 3D | z = (a + bx + cy)/(1 + dx + fy) z = 1.0 / z | |
| Reciprocal Rational B 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = 1.0 / z | |
| Reciprocal Rational C 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = 1.0 / z | |
| Reciprocal Rational D 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = 1.0 / z | |
| Reciprocal Rational E 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = 1.0 / z | |
| Reciprocal Rational F 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = 1.0 / z | |
| Reciprocal Rational G 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = 1.0 / z | |
| Reciprocal Rational H 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = 1.0 / z | |
| Reciprocal Rational I 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = 1.0 / z | |
| Reciprocal Rational J 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = 1.0 / z | |
| Reciprocal Rational K 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = 1.0 / z | |
| Reciprocal Rational L 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = 1.0 / z | |
| Reciprocal Rational M 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = 1.0 / z | |
| Reciprocal Rational N 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = 1.0 / z | |
| Reciprocal Rational O 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = 1.0 / z | |
| Reciprocal Rational P 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = 1.0 / z | |
| Reciprocal Rational Q 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = 1.0 / z | |
| Reciprocal Rational R 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = 1.0 / z | |
| Reciprocal Rational S 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = 1.0 / z | |
| Reciprocal Rational T 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = 1.0 / z | |
| Reciprocal Rational U 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = 1.0 / z | |
| Reciprocal Rational V 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = 1.0 / z | |
| Reciprocal Rational W 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = 1.0 / z | |
| Reciprocal Rational X 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = 1.0 / z | |
| Reciprocal Rational Y 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = 1.0 / z | |
| Reciprocal Rational Z 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = 1.0 / z | |
| Reciprocal Rational A With Offset 3D | z = (a + bx + cy)/(1 + dx + fy) z = 1.0 / z + Offset | |
| Reciprocal Rational B With Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy) z = 1.0 / z + Offset | |
| Reciprocal Rational C With Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy) z = 1.0 / z + Offset | |
| Reciprocal Rational D With Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy) z = 1.0 / z + Offset | |
| Reciprocal Rational E With Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy) z = 1.0 / z + Offset | |
| Reciprocal Rational F With Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational G With Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational H With Offset 3D | z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational I With Offset 3D | z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational J With Offset 3D | z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational K With Offset 3D | z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational L With Offset 3D | z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational M With Offset 3D | z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational N With Offset 3D | z = (a + bx + cy + dxy)/(1 + fx + gy + hxy) z = 1.0 / z + Offset | |
| Reciprocal Rational O With Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)ln(y))/(1 + fx + gy + hxy) z = 1.0 / z + Offset | |
| Reciprocal Rational P With Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)ln(y))/(1 + fx + gy + hxy) z = 1.0 / z + Offset | |
| Reciprocal Rational Q With Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)exp(y))/(1 + fx + gy + hxy) z = 1.0 / z + Offset | |
| Reciprocal Rational R With Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)exp(y))/(1 + fx + gy + hxy) z = 1.0 / z + Offset | |
| Reciprocal Rational S With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational T With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational U With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational V With Offset 3D | z = (a + bx + cy + dxy)/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational W With Offset 3D | z = (a + b*ln(x) + c*ln(y) + d*ln(x)*ln(y))/(1 + f*ln(x) + g*ln(y) + h*ln(x)*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational X With Offset 3D | z = (a + b*exp(x) + c*ln(y) + d*exp(x)*ln(y))/(1 + f*exp(x) + g*ln(y) + h*exp(x)*ln(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational Y With Offset 3D | z = (a + b*ln(x) + c*exp(y) + d*ln(x)*exp(y))/(1 + f*ln(x) + g*exp(y) + h*ln(x)*exp(y)) z = 1.0 / z + Offset | |
| Reciprocal Rational Z With Offset 3D | z = (a + b*exp(x) + c*exp(y) + d*exp(x)*exp(y))/(1 + f*exp(x) + g*exp(y) + h*exp(x)*exp(y)) z = 1.0 / z + Offset | |
| Roman Surface (minus) 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) | |
| Roman Surface (minus) Offset XY 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) | |
| Roman Surface (minus) Scaled And Offset XY 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) | |
| Roman Surface (plus) 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) | |
| Roman Surface (plus) Offset XY 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) | |
| Roman Surface (plus) Scaled And Offset XY 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) | |
| Roman Surface (minus) Offset XY With Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) + Offset | |
| Roman Surface (minus) Scaled And Offset XY With Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) + Offset | |
| Roman Surface (minus) With Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) + Offset | |
| Roman Surface (plus) Offset XY With Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) + Offset | |
| Roman Surface (plus) Scaled And Offset XY With Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) + Offset | |
| Roman Surface (plus) With Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) + Offset | |
| Roman Surface (minus) Offset XY With Exponential Decay 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (f * exp(xy)) | |
| Roman Surface (minus) Scaled And Offset XY With Exponential Decay 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (h * exp(xy)) | |
| Roman Surface (minus) With Exponential Decay 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (c * exp(xy)) | |
| Roman Surface (plus) Offset XY With Exponential Decay 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (f * exp(xy)) | |
| Roman Surface (plus) Scaled And Offset XY With Exponential Decay 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (h * exp(xy)) | |
| Roman Surface (plus) With Exponential Decay 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (c * exp(xy)) | |
| Roman Surface (minus) Offset XY With Exponential Decay And Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (g * exp(xy)) + Offset | |
| Roman Surface (minus) Scaled And Offset XY With Exponential Decay And Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (i * exp(xy)) + Offset | |
| Roman Surface (minus) With Exponential Decay And Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (d * exp(xy)) + Offset | |
| Roman Surface (plus) Offset XY With Exponential Decay And Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (g * exp(xy)) + Offset | |
| Roman Surface (plus) Scaled And Offset XY With Exponential Decay And Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (i * exp(xy)) + Offset | |
| Roman Surface (plus) With Exponential Decay And Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (d * exp(xy)) + Offset | |
| Roman Surface (minus) Offset XY With Exponential Growth 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (f * exp(xy)) | |
| Roman Surface (minus) Scaled And Offset XY With Exponential Growth 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (h * exp(xy)) | |
| Roman Surface (minus) With Exponential Growth 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (c * exp(xy)) | |
| Roman Surface (plus) Offset XY With Exponential Growth 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (f * exp(xy)) | |
| Roman Surface (plus) Scaled And Offset XY With Exponential Growth 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (h * exp(xy)) | |
| Roman Surface (plus) With Exponential Growth 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (c * exp(xy)) | |
| Roman Surface (minus) Offset XY With Exponential Growth And Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (g * exp(xy)) + Offset | |
| Roman Surface (minus) Scaled And Offset XY With Exponential Growth And Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (i * exp(xy)) + Offset | |
| Roman Surface (minus) With Exponential Growth And Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (d * exp(xy)) + Offset | |
| Roman Surface (plus) Offset XY With Exponential Growth And Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (g * exp(xy)) + Offset | |
| Roman Surface (plus) Scaled And Offset XY With Exponential Growth And Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (i * exp(xy)) + Offset | |
| Roman Surface (plus) With Exponential Growth And Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (d * exp(xy)) + Offset | |
| Inverse Roman Surface (minus) 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = xy / z | |
| Inverse Roman Surface (minus) Offset XY 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = xy / z | |
| Inverse Roman Surface (minus) Scaled And Offset XY 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = xy / z | |
| Inverse Roman Surface (plus) 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = xy / z | |
| Inverse Roman Surface (plus) Offset XY 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = xy / z | |
| Inverse Roman Surface (plus) Scaled And Offset XY 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = xy / z | |
| Inverse Roman Surface (minus) Offset XY With Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = xy / (z + Offset | |
| Inverse Roman Surface (minus) Scaled And Offset XY With Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = xy / (z + Offset | |
| Inverse Roman Surface (minus) With Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = xy / (z + Offset | |
| Inverse Roman Surface (plus) Offset XY With Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = xy / (z + Offset | |
| Inverse Roman Surface (plus) Scaled And Offset XY With Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = xy / (z + Offset | |
| Inverse Roman Surface (plus) With Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = xy / (z + Offset | |
| Roman Surface (minus) Offset XY With Linear Decay 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (f * xy) | |
| Roman Surface (minus) Scaled And Offset XY With Linear Decay 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (h * xy) | |
| Roman Surface (minus) With Linear Decay 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (c * xy) | |
| Roman Surface (plus) Offset XY With Linear Decay 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (f * xy) | |
| Roman Surface (plus) Scaled And Offset XY With Linear Decay 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (h * xy) | |
| Roman Surface (plus) With Linear Decay 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (c * xy) | |
| Roman Surface (minus) Offset XY With Linear Decay And Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (g * xy) + Offset | |
| Roman Surface (minus) Scaled And Offset XY With Linear Decay And Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (i * xy) + Offset | |
| Roman Surface (minus) With Linear Decay And Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (d * xy) + Offset | |
| Roman Surface (plus) Offset XY With Linear Decay And Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z / (g * xy) + Offset | |
| Roman Surface (plus) Scaled And Offset XY With Linear Decay And Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z / (i * xy) + Offset | |
| Roman Surface (plus) With Linear Decay And Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z / (d * xy) + Offset | |
| Roman Surface (minus) Offset XY With Linear Growth 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (f * xy) + Offset | |
| Roman Surface (minus) Scaled And Offset XY With Linear Growth 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (h * xy) + Offset | |
| Roman Surface (minus) With Linear Growth 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (c * xy) + Offset | |
| Roman Surface (plus) Offset XY With Linear Growth 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (f * xy) + Offset | |
| Roman Surface (plus) Scaled And Offset XY With Linear Growth 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (h * xy) + Offset | |
| Roman Surface (plus) With Linear Growth 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (c * xy) + Offset | |
| Roman Surface (minus) Offset XY With Linear Growth And Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (g * xy) + Offset | |
| Roman Surface (minus) Scaled And Offset XY With Linear Growth And Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (i * xy) + Offset | |
| Roman Surface (minus) With Linear Growth And Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (d * xy) + Offset | |
| Roman Surface (plus) Offset XY With Linear Growth And Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = z * (g * xy) + Offset | |
| Roman Surface (plus) Scaled And Offset XY With Linear Growth And Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = z * (i * xy) + Offset | |
| Roman Surface (plus) With Linear Growth And Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = z * (d * xy) + Offset | |
| Reciprocal Roman Surface (minus) 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = 1.0 / z | |
| Reciprocal Roman Surface (minus) Offset XY 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = 1.0 / z | |
| Reciprocal Roman Surface (minus) Scaled And Offset XY 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = 1.0 / z | |
| Reciprocal Roman Surface (plus) 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = 1.0 / z | |
| Reciprocal Roman Surface (plus) Offset XY 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = 1.0 / z | |
| Reciprocal Roman Surface (plus) Scaled And Offset XY 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = 1.0 / z | |
| Reciprocal Roman Surface (minus) Offset XY With Offset 3D | z = (k((y+b)2-(x+a)2) - ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = 1.0 / z + Offset | |
| Reciprocal Roman Surface (minus) Scaled And Offset XY With Offset 3D | z = (k((cy+d)2-(ax+b)2) - ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = 1.0 / z + Offset | |
| Reciprocal Roman Surface (minus) With Offset 3D | z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = 1.0 / z + Offset | |
| Reciprocal Roman Surface (plus) Offset XY With Offset 3D | z = (k((y+b)2-(x+a)2) + ((x+a)2-(y+b)2)sqrt(k2-(x+a)2-(y+b)2)) / (2((x+a)2+(y+b)2)) z = 1.0 / z + Offset | |
| Reciprocal Roman Surface (plus) Scaled And Offset XY With Offset 3D | z = (k((cy+d)2-(ax+b)2) + ((ax+b)2-(cy+d)2)sqrt(k2-(ax+b)2-(cy+d)2)) / (2((ax+b)2+(cy+d)2)) z = 1.0 / z + Offset | |
| Reciprocal Roman Surface (plus) With Offset 3D | z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) z = 1.0 / z + Offset | |
| Andrea Prunotto Sigmoid A 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) | |
| Andrea Prunotto Sigmoid B 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) | |
| Fraser Smith Sigmoid 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) | |
| Sigmoid 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) | |
| Fraser Smith Sigmoid With Offset 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) + Offset | |
| Sigmoid With Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) + Offset | |
| Andrea Prunotto Sigmoid A With Exponential Decay 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) z = z / (i * exp(xy)) | |
| Andrea Prunotto Sigmoid B With Exponential Decay 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) z = z / (i * exp(xy)) | |
| Fraser Smith Sigmoid With Exponential Decay 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z / (g * exp(xy)) | |
| Sigmoid With Exponential Decay 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z / exp(xy) | |
| Fraser Smith Sigmoid With Exponential Decay And Offset 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z / (h * exp(xy)) + Offset | |
| Sigmoid With Exponential Decay And Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z / exp(xy) + Offset | |
| Andrea Prunotto Sigmoid A With Exponential Growth 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) z = z * (i * exp(xy)) | |
| Andrea Prunotto Sigmoid B With Exponential Growth 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) z = z * (i * exp(xy)) | |
| Fraser Smith Sigmoid With Exponential Growth 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z * (g * exp(xy)) | |
| Sigmoid With Exponential Growth 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z * exp(xy) | |
| Fraser Smith Sigmoid With Exponential Growth And Offset 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z * (h * exp(xy)) + Offset | |
| Sigmoid With Exponential Growth And Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z * exp(xy) + Offset | |
| Inverse Andrea Prunotto Sigmoid A 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) z = xy / z | |
| Inverse Andrea Prunotto Sigmoid B 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) z = xy / z | |
| Inverse Fraser Smith Sigmoid 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = xy / z | |
| Inverse Sigmoid 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = xy / z | |
| Inverse Fraser Smith Sigmoid With Offset 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = xy / (z + Offset | |
| Inverse Sigmoid With Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = xy / (z + Offset | |
| Andrea Prunotto Sigmoid A With Linear Decay 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) z = z / (i * xy) | |
| Andrea Prunotto Sigmoid B With Linear Decay 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) z = z / (i * xy) | |
| Fraser Smith Sigmoid With Linear Decay 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z / (g * xy) | |
| Sigmoid With Linear Decay 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z / xy | |
| Fraser Smith Sigmoid With Linear Decay And Offset 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z / (h * xy) + Offset | |
| Sigmoid With Linear Decay And Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z / xy + Offset | |
| Andrea Prunotto Sigmoid A With Linear Growth 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) z = z * (i * xy) + Offset | |
| Andrea Prunotto Sigmoid B With Linear Growth 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) z = z * (i * xy) + Offset | |
| Fraser Smith Sigmoid With Linear Growth 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z * (g * xy) + Offset | |
| Sigmoid With Linear Growth 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z * xy | |
| Fraser Smith Sigmoid With Linear Growth And Offset 3D | z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + e(c - dy))) z = z * (h * xy) + Offset | |
| Sigmoid With Linear Growth And Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = z * xy + Offset | |
| Reciprocal Andrea Prunotto Sigmoid A 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y)))) z = 1.0 / z | |
| Reciprocal Andrea Prunotto Sigmoid B 3D | z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y)))) z = 1.0 / z | |
| Reciprocal Sigmoid 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = 1.0 / z | |
| Reciprocal Sigmoid With Offset 3D | z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) z = 1.0 / z + Offset | |
| Taylor Series A 3D | z = a + bx + cy + dx2 + fy2 + gxy | |
| Taylor Series B 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y | |
| Taylor Series C 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) | |
| Taylor Series D 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) | |
| Taylor Series E 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x | |
| Taylor Series F 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) | |
| Taylor Series G 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x | |
| Taylor Series H 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) | |
| Taylor Series I 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y | |
| Taylor Series J 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y | |
| Taylor Series K 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) | |
| Taylor Series L 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) | |
| Taylor Series M 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) | |
| Taylor Series N 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) | |
| Taylor Series O 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) | |
| Taylor Series P 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) | |
| Taylor Series A With Exponential Decay 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z / (i * exp(xy)) | |
| Taylor Series B With Exponential Decay 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y z = z / (i * exp(xy)) | |
| Taylor Series C With Exponential Decay 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) z = z / (i * exp(xy)) | |
| Taylor Series D With Exponential Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z / (i * exp(xy)) | |
| Taylor Series E With Exponential Decay 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x z = z / (i * exp(xy)) | |
| Taylor Series F With Exponential Decay 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) z = z / (i * exp(xy)) | |
| Taylor Series G With Exponential Decay 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x z = z / (i * exp(xy)) | |
| Taylor Series H With Exponential Decay 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) z = z / (i * exp(xy)) | |
| Taylor Series I With Exponential Decay 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y z = z / (i * exp(xy)) | |
| Taylor Series J With Exponential Decay 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y z = z / (i * exp(xy)) | |
| Taylor Series K With Exponential Decay 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) z = z / (i * exp(xy)) | |
| Taylor Series L With Exponential Decay 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) z = z / (i * exp(xy)) | |
| Taylor Series M With Exponential Decay 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) z = z / (i * exp(xy)) | |
| Taylor Series N With Exponential Decay 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) z = z / (i * exp(xy)) | |
| Taylor Series O With Exponential Decay 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) z = z / (i * exp(xy)) | |
| Taylor Series P With Exponential Decay 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) z = z / (i * exp(xy)) | |
| Taylor Series A With Exponential Growth 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z * (i * exp(xy)) | |
| Taylor Series B With Exponential Growth 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y z = z * (i * exp(xy)) | |
| Taylor Series C With Exponential Growth 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) z = z * (i * exp(xy)) | |
| Taylor Series D With Exponential Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z * (i * exp(xy)) | |
| Taylor Series E With Exponential Growth 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x z = z * (i * exp(xy)) | |
| Taylor Series F With Exponential Growth 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) z = z * (i * exp(xy)) | |
| Taylor Series G With Exponential Growth 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x z = z * (i * exp(xy)) | |
| Taylor Series H With Exponential Growth 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) z = z * (i * exp(xy)) | |
| Taylor Series I With Exponential Growth 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y z = z * (i * exp(xy)) | |
| Taylor Series J With Exponential Growth 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y z = z * (i * exp(xy)) | |
| Taylor Series K With Exponential Growth 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) z = z * (i * exp(xy)) | |
| Taylor Series L With Exponential Growth 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) z = z * (i * exp(xy)) | |
| Taylor Series M With Exponential Growth 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) z = z * (i * exp(xy)) | |
| Taylor Series N With Exponential Growth 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) z = z * (i * exp(xy)) | |
| Taylor Series O With Exponential Growth 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) z = z * (i * exp(xy)) | |
| Taylor Series P With Exponential Growth 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) z = z * (i * exp(xy)) | |
| Inverse Taylor Series A 3D | z = a + bx + cy + dx2 + fy2 + gxy z = xy / z | |
| Inverse Taylor Series B 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y z = xy / z | |
| Inverse Taylor Series C 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) z = xy / z | |
| Inverse Taylor Series D 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = xy / z | |
| Inverse Taylor Series E 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x z = xy / z | |
| Inverse Taylor Series F 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) z = xy / z | |
| Inverse Taylor Series G 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x z = xy / z | |
| Inverse Taylor Series H 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) z = xy / z | |
| Inverse Taylor Series I 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y z = xy / z | |
| Inverse Taylor Series J 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y z = xy / z | |
| Inverse Taylor Series K 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) z = xy / z | |
| Inverse Taylor Series L 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) z = xy / z | |
| Inverse Taylor Series M 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) z = xy / z | |
| Inverse Taylor Series N 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) z = xy / z | |
| Inverse Taylor Series O 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) z = xy / z | |
| Inverse Taylor Series P 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) z = xy / z | |
| Taylor Series A With Linear Decay 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z / (i * xy) | |
| Taylor Series B With Linear Decay 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y z = z / (i * xy) | |
| Taylor Series C With Linear Decay 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) z = z / (i * xy) | |
| Taylor Series D With Linear Decay 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z / (i * xy) | |
| Taylor Series E With Linear Decay 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x z = z / (i * xy) | |
| Taylor Series F With Linear Decay 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) z = z / (i * xy) | |
| Taylor Series G With Linear Decay 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x z = z / (i * xy) | |
| Taylor Series H With Linear Decay 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) z = z / (i * xy) | |
| Taylor Series I With Linear Decay 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y z = z / (i * xy) | |
| Taylor Series J With Linear Decay 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y z = z / (i * xy) | |
| Taylor Series K With Linear Decay 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) z = z / (i * xy) | |
| Taylor Series L With Linear Decay 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) z = z / (i * xy) | |
| Taylor Series M With Linear Decay 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) z = z / (i * xy) | |
| Taylor Series N With Linear Decay 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) z = z / (i * xy) | |
| Taylor Series O With Linear Decay 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) z = z / (i * xy) | |
| Taylor Series P With Linear Decay 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) z = z / (i * xy) | |
| Taylor Series A With Linear Growth 3D | z = a + bx + cy + dx2 + fy2 + gxy z = z * (i * xy) + Offset | |
| Taylor Series B With Linear Growth 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y z = z * (i * xy) + Offset | |
| Taylor Series C With Linear Growth 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) z = z * (i * xy) + Offset | |
| Taylor Series D With Linear Growth 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = z * (i * xy) + Offset | |
| Taylor Series E With Linear Growth 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x z = z * (i * xy) + Offset | |
| Taylor Series F With Linear Growth 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) z = z * (i * xy) + Offset | |
| Taylor Series G With Linear Growth 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x z = z * (i * xy) + Offset | |
| Taylor Series H With Linear Growth 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) z = z * (i * xy) + Offset | |
| Taylor Series I With Linear Growth 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y z = z * (i * xy) + Offset | |
| Taylor Series J With Linear Growth 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y z = z * (i * xy) + Offset | |
| Taylor Series K With Linear Growth 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) z = z * (i * xy) + Offset | |
| Taylor Series L With Linear Growth 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) z = z * (i * xy) + Offset | |
| Taylor Series M With Linear Growth 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) z = z * (i * xy) + Offset | |
| Taylor Series N With Linear Growth 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) z = z * (i * xy) + Offset | |
| Taylor Series O With Linear Growth 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) z = z * (i * xy) + Offset | |
| Taylor Series P With Linear Growth 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) z = z * (i * xy) + Offset | |
| Reciprocal Taylor Series A 3D | z = a + bx + cy + dx2 + fy2 + gxy z = 1.0 / z | |
| Reciprocal Taylor Series B 3D | z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y z = 1.0 / z | |
| Reciprocal Taylor Series C 3D | z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y) z = 1.0 / z | |
| Reciprocal Taylor Series D 3D | z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y) z = 1.0 / z | |
| Reciprocal Taylor Series E 3D | z = a + b/x + cy + d/x2 + fy2 + gy/x z = 1.0 / z | |
| Reciprocal Taylor Series F 3D | z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x) z = 1.0 / z | |
| Reciprocal Taylor Series G 3D | z = a + b/x + c*ln(y) + d/x2 + f*ln(y)2 + g*ln(y)/x z = 1.0 / z | |
| Reciprocal Taylor Series H 3D | z = a + b/ln(x) + c*ln(y) + d/ln(x)2 + f*ln(y)2 + g*ln(y)/ln(x) z = 1.0 / z | |
| Reciprocal Taylor Series I 3D | z = a + bx + c/y + dx2 + f/y2 + gx/y z = 1.0 / z | |
| Reciprocal Taylor Series J 3D | z = a + b*ln(x) + c/y + d*ln(x)2 + f/y2 + g*ln(x)/y z = 1.0 / z | |
| Reciprocal Taylor Series K 3D | z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y) z = 1.0 / z | |
| Reciprocal Taylor Series L 3D | z = a + b*ln(x) + c/ln(y) + d*ln(x)2 + f/ln(y)2 + g*ln(x)/ln(y) z = 1.0 / z | |
| Reciprocal Taylor Series M 3D | z = a + b/x + c/y + d/x2 + f/y2 + g/(xy) z = 1.0 / z | |
| Reciprocal Taylor Series N 3D | z = a + b/ln(x) + c/y + d/ln(x)2 + f/y2 + g/(ln(x)*y) z = 1.0 / z | |
| Reciprocal Taylor Series O 3D | z = a + b/x + c/ln(y) + d/x2 + f/ln(y)2 + g/(x*ln(y)) z = 1.0 / z | |
| Reciprocal Taylor Series P 3D | z = a + b/ln(x) + c/ln(y) + d/ln(x)2 + f/ln(y)2 + g/(ln(x)*ln(y)) z = 1.0 / z | |
| Cosh A [radians] 3D | z = a * cosh(x) + b * cosh(y) | |
| Cosh A [radians] Transform 3D | z = a * cosh(bx+c) + d * cosh(fy+g) | |
| Cosh B [radians] 3D | z = a * cosh(x) * cosh(y) | |
| Cosh B [radians] Transform 3D | z = a * cosh(bx+c) * cosh(dy+f) | |
| Cosh XY [radians] 3D | z = a * cosh(xy) | |
| Cosh XY [radians] Transform 3D | z = a * cosh(b * xy + c) | |
| Reza's Custom Equation One [radians] 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n | |
| Reza's Custom Equation Two [radians] 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 | |
| Sine A [radians] 3D | z = a * sin(x) + b * sin(y) | |
| Sine A [radians] Transform 3D | z = a * sin(bx+c) + d * sin(fy+g) | |
| Sine B [radians] 3D | z = a * sin(x) * sin(y) | |
| Sine B [radians] Transform 3D | z = a * sin(bx+c) * sin(dy+f) | |
| Sine XY [radians] 3D | z = a * sin(xy) | |
| Sine XY [radians] Transform 3D | z = a * sin(b * xy + c) | |
| Tan A [radians] 3D | z = a * tan(x) + b * tan(y) | |
| Tan A [radians] Transform 3D | z = a * tan(bx + c) + d * tan(fy + g) | |
| Tan B [radians] 3D | z = a * tan(x) * tan(y) | |
| Tan B [radians] Transform 3D | z = a * tan(bx + c) * tan(dy + f) | |
| Tan XY [radians] 3D | z = a * tan(xy) | |
| Tan XY [radians] Transform 3D | z = a * tan(b * xy + c) | |
| Cosh A [radians] Transform With Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) + Offset | |
| Cosh A [radians] With Offset 3D | z = a * cosh(x) + b * cosh(y) + Offset | |
| Cosh B [radians] Transform With Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) + Offset | |
| Cosh B [radians] With Offset 3D | z = a * cosh(x) * cosh(y) + Offset | |
| Cosh XY [radians] Transform With Offset 3D | z = a * cosh(b * xy + c) + Offset | |
| Cosh XY [radians] With Offset 3D | z = a * cosh(xy) + Offset | |
| Reza's Custom Equation One [radians] With Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n + Offset | |
| Reza's Custom Equation Two [radians] With Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 + Offset | |
| Sine A [radians] Transform With Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) + Offset | |
| Sine A [radians] With Offset 3D | z = a * sin(x) + b * sin(y) + Offset | |
| Sine B [radians] Transform With Offset 3D | z = a * sin(bx+c) * sin(dy+f) + Offset | |
| Sine B [radians] With Offset 3D | z = a * sin(x) * sin(y) + Offset | |
| Sine XY [radians] Transform With Offset 3D | z = a * sin(b * xy + c) + Offset | |
| Sine XY [radians] With Offset 3D | z = a * sin(xy) + Offset | |
| Tan A [radians] Transform With Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) + Offset | |
| Tan A [radians] With Offset 3D | z = a * tan(x) + b * tan(y) + Offset | |
| Tan B [radians] Transform With Offset 3D | z = a * tan(bx + c) * tan(dy + f) + Offset | |
| Tan B [radians] With Offset 3D | z = a * tan(x) * tan(y) + Offset | |
| Tan XY [radians] With Offset 3D | z = a * tan(xy) + Offset | |
| Cosh A [radians] Transform With Exponential Decay 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z / (i * exp(xy)) | |
| Cosh A [radians] With Exponential Decay 3D | z = a * cosh(x) + b * cosh(y) z = z / (d * exp(xy)) | |
| Cosh B [radians] Transform With Exponential Decay 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z / exp(xy) | |
| Cosh B [radians] With Exponential Decay 3D | z = a * cosh(x) * cosh(y) z = z / exp(xy) | |
| Cosh XY [radians] Transform With Exponential Decay 3D | z = a * cosh(b * xy + c) z = z / exp(xy) | |
| Cosh XY [radians] With Exponential Decay 3D | z = a * cosh(xy) z = z / exp(xy) | |
| Reza's Custom Equation One [radians] With Exponential Decay 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z / (m * exp(xy)) | |
| Reza's Custom Equation Two [radians] With Exponential Decay 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z / (j * exp(xy)) | |
| Sine A [radians] Transform With Exponential Decay 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z / (i * exp(xy)) | |
| Sine A [radians] With Exponential Decay 3D | z = a * sin(x) + b * sin(y) z = z / (d * exp(xy)) | |
| Sine B [radians] Transform With Exponential Decay 3D | z = a * sin(bx+c) * sin(dy+f) z = z / exp(xy) | |
| Sine B [radians] With Exponential Decay 3D | z = a * sin(x) * sin(y) z = z / exp(xy) | |
| Sine XY [radians] Transform With Exponential Decay 3D | z = a * sin(b * xy + c) z = z / exp(xy) | |
| Sine XY [radians] With Exponential Decay 3D | z = a * sin(xy) z = z / exp(xy) | |
| Tan A [radians] Transform With Exponential Decay 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z / (i * exp(xy)) | |
| Tan A [radians] With Exponential Decay 3D | z = a * tan(x) + b * tan(y) z = z / (d * exp(xy)) | |
| Tan B [radians] Transform With Exponential Decay 3D | z = a * tan(bx + c) * tan(dy + f) z = z / exp(xy) | |
| Tan B [radians] With Exponential Decay 3D | z = a * tan(x) * tan(y) z = z / exp(xy) | |
| Tan XY [radians] Transform With Exponential Decay 3D | z = a * tan(b * xy + c) z = z / exp(xy) | |
| Tan XY [radians] With Exponential Decay 3D | z = a * tan(xy) z = z / exp(xy) | |
| Cosh A [radians] Transform With Exponential Decay And Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z / (j * exp(xy)) + Offset | |
| Cosh A [radians] With Exponential Decay And Offset 3D | z = a * cosh(x) + b * cosh(y) z = z / (f * exp(xy)) + Offset | |
| Cosh B [radians] Transform With Exponential Decay And Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z / exp(xy) + Offset | |
| Cosh B [radians] With Exponential Decay And Offset 3D | z = a * cosh(x) * cosh(y) z = z / exp(xy) + Offset | |
| Cosh XY [radians] Transform With Exponential Decay And Offset 3D | z = a * cosh(b * xy + c) z = z / exp(xy) + Offset | |
| Cosh XY [radians] With Exponential Decay And Offset 3D | z = a * cosh(xy) z = z / exp(xy) + Offset | |
| Reza's Custom Equation One [radians] With Exponential Decay And Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z / (n * exp(xy)) + Offset | |
| Reza's Custom Equation Two [radians] With Exponential Decay And Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z / (k * exp(xy)) + Offset | |
| Sine A [radians] Transform With Exponential Decay And Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z / (j * exp(xy)) + Offset | |
| Sine A [radians] With Exponential Decay And Offset 3D | z = a * sin(x) + b * sin(y) z = z / (f * exp(xy)) + Offset | |
| Sine B [radians] Transform With Exponential Decay And Offset 3D | z = a * sin(bx+c) * sin(dy+f) z = z / exp(xy) + Offset | |
| Sine B [radians] With Exponential Decay And Offset 3D | z = a * sin(x) * sin(y) z = z / exp(xy) + Offset | |
| Sine XY [radians] Transform With Exponential Decay And Offset 3D | z = a * sin(b * xy + c) z = z / exp(xy) + Offset | |
| Sine XY [radians] With Exponential Decay And Offset 3D | z = a * sin(xy) z = z / exp(xy) + Offset | |
| Tan A [radians] Transform With Exponential Decay And Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z / (j * exp(xy)) + Offset | |
| Tan A [radians] With Exponential Decay And Offset 3D | z = a * tan(x) + b * tan(y) z = z / (f * exp(xy)) + Offset | |
| Tan B [radians] Transform With Exponential Decay And Offset 3D | z = a * tan(bx + c) * tan(dy + f) z = z / exp(xy) + Offset | |
| Tan B [radians] With Exponential Decay And Offset 3D | z = a * tan(x) * tan(y) z = z / exp(xy) + Offset | |
| Tan XY [radians] With Exponential Decay And Offset 3D | z = a * tan(xy) z = z / exp(xy) + Offset | |
| Cosh A [radians] Transform With Exponential Growth 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z * (i * exp(xy)) | |
| Cosh A [radians] With Exponential Growth 3D | z = a * cosh(x) + b * cosh(y) z = z * (d * exp(xy)) | |
| Cosh B [radians] Transform With Exponential Growth 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z * exp(xy) | |
| Cosh B [radians] With Exponential Growth 3D | z = a * cosh(x) * cosh(y) z = z * exp(xy) | |
| Cosh XY [radians] Transform With Exponential Growth 3D | z = a * cosh(b * xy + c) z = z * exp(xy) | |
| Cosh XY [radians] With Exponential Growth 3D | z = a * cosh(xy) z = z * exp(xy) | |
| Reza's Custom Equation One [radians] With Exponential Growth 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z * (m * exp(xy)) | |
| Reza's Custom Equation Two [radians] With Exponential Growth 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z * (j * exp(xy)) | |
| Sine A [radians] Transform With Exponential Growth 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z * (i * exp(xy)) | |
| Sine A [radians] With Exponential Growth 3D | z = a * sin(x) + b * sin(y) z = z * (d * exp(xy)) | |
| Sine B [radians] Transform With Exponential Growth 3D | z = a * sin(bx+c) * sin(dy+f) z = z * exp(xy) | |
| Sine B [radians] With Exponential Growth 3D | z = a * sin(x) * sin(y) z = z * exp(xy) | |
| Sine XY [radians] Transform With Exponential Growth 3D | z = a * sin(b * xy + c) z = z * exp(xy) | |
| Sine XY [radians] With Exponential Growth 3D | z = a * sin(xy) z = z * exp(xy) | |
| Tan A [radians] Transform With Exponential Growth 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z * (i * exp(xy)) | |
| Tan A [radians] With Exponential Growth 3D | z = a * tan(x) + b * tan(y) z = z * (d * exp(xy)) | |
| Tan B [radians] Transform With Exponential Growth 3D | z = a * tan(bx + c) * tan(dy + f) z = z * exp(xy) | |
| Tan B [radians] With Exponential Growth 3D | z = a * tan(x) * tan(y) z = z * exp(xy) | |
| Tan XY [radians] Transform With Exponential Growth 3D | z = a * tan(b * xy + c) z = z * exp(xy) | |
| Tan XY [radians] With Exponential Growth 3D | z = a * tan(xy) z = z * exp(xy) | |
| Cosh A [radians] Transform With Exponential Growth And Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z * (j * exp(xy)) + Offset | |
| Cosh A [radians] With Exponential Growth And Offset 3D | z = a * cosh(x) + b * cosh(y) z = z * (f * exp(xy)) + Offset | |
| Cosh B [radians] Transform With Exponential Growth And Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z * exp(xy) + Offset | |
| Cosh B [radians] With Exponential Growth And Offset 3D | z = a * cosh(x) * cosh(y) z = z * exp(xy) + Offset | |
| Cosh XY [radians] Transform With Exponential Growth And Offset 3D | z = a * cosh(b * xy + c) z = z * exp(xy) + Offset | |
| Cosh XY [radians] With Exponential Growth And Offset 3D | z = a * cosh(xy) z = z * exp(xy) + Offset | |
| Reza's Custom Equation One [radians] With Exponential Growth And Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z * (n * exp(xy)) + Offset | |
| Reza's Custom Equation Two [radians] With Exponential Growth And Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z * (k * exp(xy)) + Offset | |
| Sine A [radians] Transform With Exponential Growth And Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z * (j * exp(xy)) + Offset | |
| Sine A [radians] With Exponential Growth And Offset 3D | z = a * sin(x) + b * sin(y) z = z * (f * exp(xy)) + Offset | |
| Sine B [radians] Transform With Exponential Growth And Offset 3D | z = a * sin(bx+c) * sin(dy+f) z = z * exp(xy) + Offset | |
| Sine B [radians] With Exponential Growth And Offset 3D | z = a * sin(x) * sin(y) z = z * exp(xy) + Offset | |
| Sine XY [radians] Transform With Exponential Growth And Offset 3D | z = a * sin(b * xy + c) z = z * exp(xy) + Offset | |
| Sine XY [radians] With Exponential Growth And Offset 3D | z = a * sin(xy) z = z * exp(xy) + Offset | |
| Tan A [radians] Transform With Exponential Growth And Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z * (j * exp(xy)) + Offset | |
| Tan A [radians] With Exponential Growth And Offset 3D | z = a * tan(x) + b * tan(y) z = z * (f * exp(xy)) + Offset | |
| Tan B [radians] Transform With Exponential Growth And Offset 3D | z = a * tan(bx + c) * tan(dy + f) z = z * exp(xy) + Offset | |
| Tan B [radians] With Exponential Growth And Offset 3D | z = a * tan(x) * tan(y) z = z * exp(xy) + Offset | |
| Tan XY [radians] With Exponential Growth And Offset 3D | z = a * tan(xy) z = z * exp(xy) + Offset | |
| Inverse Cosh A [radians] 3D | z = a * cosh(x) + b * cosh(y) z = xy / z | |
| Inverse Cosh A [radians] Transform 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = xy / z | |
| Inverse Cosh B [radians] 3D | z = a * cosh(x) * cosh(y) z = xy / z | |
| Inverse Cosh B [radians] Transform 3D | z = a * cosh(bx+c) * cosh(dy+f) z = xy / z | |
| Inverse Cosh XY [radians] 3D | z = a * cosh(xy) z = xy / z | |
| Inverse Cosh XY [radians] Transform 3D | z = a * cosh(b * xy + c) z = xy / z | |
| Inverse Reza's Custom Equation One [radians] 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = xy / z | |
| Inverse Reza's Custom Equation Two [radians] 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = xy / z | |
| Inverse Sine A [radians] 3D | z = a * sin(x) + b * sin(y) z = xy / z | |
| Inverse Sine A [radians] Transform 3D | z = a * sin(bx+c) + d * sin(fy+g) z = xy / z | |
| Inverse Sine B [radians] 3D | z = a * sin(x) * sin(y) z = xy / z | |
| Inverse Sine B [radians] Transform 3D | z = a * sin(bx+c) * sin(dy+f) z = xy / z | |
| Inverse Sine XY [radians] 3D | z = a * sin(xy) z = xy / z | |
| Inverse Sine XY [radians] Transform 3D | z = a * sin(b * xy + c) z = xy / z | |
| Inverse Tan A [radians] 3D | z = a * tan(x) + b * tan(y) z = xy / z | |
| Inverse Tan A [radians] Transform 3D | z = a * tan(bx + c) + d * tan(fy + g) z = xy / z | |
| Inverse Tan B [radians] 3D | z = a * tan(x) * tan(y) z = xy / z | |
| Inverse Tan B [radians] Transform 3D | z = a * tan(bx + c) * tan(dy + f) z = xy / z | |
| Inverse Tan XY [radians] 3D | z = a * tan(xy) z = xy / z | |
| Inverse Tan XY [radians] Transform 3D | z = a * tan(b * xy + c) z = xy / z | |
| Inverse Cosh A [radians] Transform With Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = xy / (z + Offset | |
| Inverse Cosh A [radians] With Offset 3D | z = a * cosh(x) + b * cosh(y) z = xy / (z + Offset | |
| Inverse Cosh B [radians] Transform With Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) z = xy / (z + Offset | |
| Inverse Cosh B [radians] With Offset 3D | z = a * cosh(x) * cosh(y) z = xy / (z + Offset | |
| Inverse Cosh XY [radians] Transform With Offset 3D | z = a * cosh(b * xy + c) z = xy / (z + Offset | |
| Inverse Cosh XY [radians] With Offset 3D | z = a * cosh(xy) z = xy / (z + Offset | |
| Inverse Reza's Custom Equation One [radians] With Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = xy / (z + Offset | |
| Inverse Reza's Custom Equation Two [radians] With Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = xy / (z + Offset | |
| Inverse Sine A [radians] Transform With Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) z = xy / (z + Offset | |
| Inverse Sine A [radians] With Offset 3D | z = a * sin(x) + b * sin(y) z = xy / (z + Offset | |
| Inverse Sine B [radians] Transform With Offset 3D | z = a * sin(bx+c) * sin(dy+f) z = xy / (z + Offset | |
| Inverse Sine B [radians] With Offset 3D | z = a * sin(x) * sin(y) z = xy / (z + Offset | |
| Inverse Sine XY [radians] Transform With Offset 3D | z = a * sin(b * xy + c) z = xy / (z + Offset | |
| Inverse Sine XY [radians] With Offset 3D | z = a * sin(xy) z = xy / (z + Offset | |
| Inverse Tan A [radians] Transform With Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) z = xy / (z + Offset | |
| Inverse Tan A [radians] With Offset 3D | z = a * tan(x) + b * tan(y) z = xy / (z + Offset | |
| Inverse Tan B [radians] Transform With Offset 3D | z = a * tan(bx + c) * tan(dy + f) z = xy / (z + Offset | |
| Inverse Tan B [radians] With Offset 3D | z = a * tan(x) * tan(y) z = xy / (z + Offset | |
| Inverse Tan XY [radians] With Offset 3D | z = a * tan(xy) z = xy / (z + Offset | |
| Cosh A [radians] Transform With Linear Decay 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z / (i * xy) | |
| Cosh A [radians] With Linear Decay 3D | z = a * cosh(x) + b * cosh(y) z = z / (d * xy) | |
| Cosh B [radians] Transform With Linear Decay 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z / xy | |
| Cosh B [radians] With Linear Decay 3D | z = a * cosh(x) * cosh(y) z = z / xy | |
| Cosh XY [radians] Transform With Linear Decay 3D | z = a * cosh(b * xy + c) z = z / xy | |
| Cosh XY [radians] With Linear Decay 3D | z = a * cosh(xy) z = z / xy | |
| Reza's Custom Equation One [radians] With Linear Decay 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z / (m * xy) | |
| Reza's Custom Equation Two [radians] With Linear Decay 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z / (j * xy) | |
| Sine A [radians] Transform With Linear Decay 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z / (i * xy) | |
| Sine A [radians] With Linear Decay 3D | z = a * sin(x) + b * sin(y) z = z / (d * xy) | |
| Sine B [radians] Transform With Linear Decay 3D | z = a * sin(bx+c) * sin(dy+f) z = z / xy | |
| Sine B [radians] With Linear Decay 3D | z = a * sin(x) * sin(y) z = z / xy | |
| Sine XY [radians] Transform With Linear Decay 3D | z = a * sin(b * xy + c) z = z / xy | |
| Sine XY [radians] With Linear Decay 3D | z = a * sin(xy) z = z / xy | |
| Tan A [radians] Transform With Linear Decay 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z / (i * xy) | |
| Tan A [radians] With Linear Decay 3D | z = a * tan(x) + b * tan(y) z = z / (d * xy) | |
| Tan B [radians] Transform With Linear Decay 3D | z = a * tan(bx + c) * tan(dy + f) z = z / xy | |
| Tan B [radians] With Linear Decay 3D | z = a * tan(x) * tan(y) z = z / xy | |
| Tan XY [radians] Transform With Linear Decay 3D | z = a * tan(b * xy + c) z = z / xy | |
| Tan XY [radians] With Linear Decay 3D | z = a * tan(xy) z = z / xy | |
| Cosh A [radians] Transform With Linear Decay And Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z / (j * xy) + Offset | |
| Cosh A [radians] With Linear Decay And Offset 3D | z = a * cosh(x) + b * cosh(y) z = z / (f * xy) + Offset | |
| Cosh B [radians] Transform With Linear Decay And Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z / xy + Offset | |
| Cosh B [radians] With Linear Decay And Offset 3D | z = a * cosh(x) * cosh(y) z = z / xy + Offset | |
| Cosh XY [radians] Transform With Linear Decay And Offset 3D | z = a * cosh(b * xy + c) z = z / xy + Offset | |
| Cosh XY [radians] With Linear Decay And Offset 3D | z = a * cosh(xy) z = z / xy + Offset | |
| Reza's Custom Equation One [radians] With Linear Decay And Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z / (n * xy) + Offset | |
| Reza's Custom Equation Two [radians] With Linear Decay And Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z / (k * xy) + Offset | |
| Sine A [radians] Transform With Linear Decay And Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z / (j * xy) + Offset | |
| Sine A [radians] With Linear Decay And Offset 3D | z = a * sin(x) + b * sin(y) z = z / (f * xy) + Offset | |
| Sine B [radians] Transform With Linear Decay And Offset 3D | z = a * sin(bx+c) * sin(dy+f) z = z / xy + Offset | |
| Sine B [radians] With Linear Decay And Offset 3D | z = a * sin(x) * sin(y) z = z / xy + Offset | |
| Sine XY [radians] Transform With Linear Decay And Offset 3D | z = a * sin(b * xy + c) z = z / xy + Offset | |
| Sine XY [radians] With Linear Decay And Offset 3D | z = a * sin(xy) z = z / xy + Offset | |
| Tan A [radians] Transform With Linear Decay And Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z / (j * xy) + Offset | |
| Tan A [radians] With Linear Decay And Offset 3D | z = a * tan(x) + b * tan(y) z = z / (f * xy) + Offset | |
| Tan B [radians] Transform With Linear Decay And Offset 3D | z = a * tan(bx + c) * tan(dy + f) z = z / xy + Offset | |
| Tan B [radians] With Linear Decay And Offset 3D | z = a * tan(x) * tan(y) z = z / xy + Offset | |
| Tan XY [radians] With Linear Decay And Offset 3D | z = a * tan(xy) z = z / xy + Offset | |
| Cosh A [radians] Transform With Linear Growth 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z * (i * xy) + Offset | |
| Cosh A [radians] With Linear Growth 3D | z = a * cosh(x) + b * cosh(y) z = z * (d * xy) + Offset | |
| Cosh B [radians] Transform With Linear Growth 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z * xy | |
| Cosh B [radians] With Linear Growth 3D | z = a * cosh(x) * cosh(y) z = z * xy | |
| Cosh XY [radians] Transform With Linear Growth 3D | z = a * cosh(b * xy + c) z = z * xy | |
| Cosh XY [radians] With Linear Growth 3D | z = a * cosh(xy) z = z * xy | |
| Reza's Custom Equation One [radians] With Linear Growth 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z * (m * xy) + Offset | |
| Reza's Custom Equation Two [radians] With Linear Growth 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z * (j * xy) + Offset | |
| Sine A [radians] Transform With Linear Growth 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z * (i * xy) + Offset | |
| Sine A [radians] With Linear Growth 3D | z = a * sin(x) + b * sin(y) z = z * (d * xy) + Offset | |
| Sine B [radians] Transform With Linear Growth 3D | z = a * sin(bx+c) * sin(dy+f) z = z * xy | |
| Sine B [radians] With Linear Growth 3D | z = a * sin(x) * sin(y) z = z * xy | |
| Sine XY [radians] Transform With Linear Growth 3D | z = a * sin(b * xy + c) z = z * xy | |
| Sine XY [radians] With Linear Growth 3D | z = a * sin(xy) z = z * xy | |
| Tan A [radians] Transform With Linear Growth 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z * (i * xy) + Offset | |
| Tan A [radians] With Linear Growth 3D | z = a * tan(x) + b * tan(y) z = z * (d * xy) + Offset | |
| Tan B [radians] Transform With Linear Growth 3D | z = a * tan(bx + c) * tan(dy + f) z = z * xy | |
| Tan B [radians] With Linear Growth 3D | z = a * tan(x) * tan(y) z = z * xy | |
| Tan XY [radians] Transform With Linear Growth 3D | z = a * tan(b * xy + c) z = z * xy | |
| Tan XY [radians] With Linear Growth 3D | z = a * tan(xy) z = z * xy | |
| Cosh A [radians] Transform With Linear Growth And Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = z * (j * xy) + Offset | |
| Cosh A [radians] With Linear Growth And Offset 3D | z = a * cosh(x) + b * cosh(y) z = z * (f * xy) + Offset | |
| Cosh B [radians] Transform With Linear Growth And Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) z = z * xy + Offset | |
| Cosh B [radians] With Linear Growth And Offset 3D | z = a * cosh(x) * cosh(y) z = z * xy + Offset | |
| Cosh XY [radians] Transform With Linear Growth And Offset 3D | z = a * cosh(b * xy + c) z = z * xy + Offset | |
| Cosh XY [radians] With Linear Growth And Offset 3D | z = a * cosh(xy) z = z * xy + Offset | |
| Reza's Custom Equation One [radians] With Linear Growth And Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = z * (n * xy) + Offset | |
| Reza's Custom Equation Two [radians] With Linear Growth And Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = z * (k * xy) + Offset | |
| Sine A [radians] Transform With Linear Growth And Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) z = z * (j * xy) + Offset | |
| Sine A [radians] With Linear Growth And Offset 3D | z = a * sin(x) + b * sin(y) z = z * (f * xy) + Offset | |
| Sine B [radians] Transform With Linear Growth And Offset 3D | z = a * sin(bx+c) * sin(dy+f) z = z * xy + Offset | |
| Sine B [radians] With Linear Growth And Offset 3D | z = a * sin(x) * sin(y) z = z * xy + Offset | |
| Sine XY [radians] Transform With Linear Growth And Offset 3D | z = a * sin(b * xy + c) z = z * xy + Offset | |
| Sine XY [radians] With Linear Growth And Offset 3D | z = a * sin(xy) z = z * xy + Offset | |
| Tan A [radians] Transform With Linear Growth And Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) z = z * (j * xy) + Offset | |
| Tan A [radians] With Linear Growth And Offset 3D | z = a * tan(x) + b * tan(y) z = z * (f * xy) + Offset | |
| Tan B [radians] Transform With Linear Growth And Offset 3D | z = a * tan(bx + c) * tan(dy + f) z = z * xy + Offset | |
| Tan B [radians] With Linear Growth And Offset 3D | z = a * tan(x) * tan(y) z = z * xy + Offset | |
| Tan XY [radians] With Linear Growth And Offset 3D | z = a * tan(xy) z = z * xy + Offset | |
| Reciprocal Cosh A [radians] 3D | z = a * cosh(x) + b * cosh(y) z = 1.0 / z | |
| Reciprocal Cosh A [radians] Transform 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = 1.0 / z | |
| Reciprocal Cosh B [radians] 3D | z = a * cosh(x) * cosh(y) z = 1.0 / z | |
| Reciprocal Cosh B [radians] Transform 3D | z = a * cosh(bx+c) * cosh(dy+f) z = 1.0 / z | |
| Reciprocal Cosh XY [radians] 3D | z = a * cosh(xy) z = 1.0 / z | |
| Reciprocal Cosh XY [radians] Transform 3D | z = a * cosh(b * xy + c) z = 1.0 / z | |
| Reciprocal Reza's Custom Equation One [radians] 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = 1.0 / z | |
| Reciprocal Reza's Custom Equation Two [radians] 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = 1.0 / z | |
| Reciprocal Sine A [radians] 3D | z = a * sin(x) + b * sin(y) z = 1.0 / z | |
| Reciprocal Sine A [radians] Transform 3D | z = a * sin(bx+c) + d * sin(fy+g) z = 1.0 / z | |
| Reciprocal Sine B [radians] 3D | z = a * sin(x) * sin(y) z = 1.0 / z | |
| Reciprocal Sine B [radians] Transform 3D | z = a * sin(bx+c) * sin(dy+f) z = 1.0 / z | |
| Reciprocal Sine XY [radians] 3D | z = a * sin(xy) z = 1.0 / z | |
| Reciprocal Sine XY [radians] Transform 3D | z = a * sin(b * xy + c) z = 1.0 / z | |
| Reciprocal Tan A [radians] 3D | z = a * tan(x) + b * tan(y) z = 1.0 / z | |
| Reciprocal Tan A [radians] Transform 3D | z = a * tan(bx + c) + d * tan(fy + g) z = 1.0 / z | |
| Reciprocal Tan B [radians] 3D | z = a * tan(x) * tan(y) z = 1.0 / z | |
| Reciprocal Tan B [radians] Transform 3D | z = a * tan(bx + c) * tan(dy + f) z = 1.0 / z | |
| Reciprocal Tan XY [radians] 3D | z = a * tan(xy) z = 1.0 / z | |
| Reciprocal Tan XY [radians] Transform 3D | z = a * tan(b * xy + c) z = 1.0 / z | |
| Reciprocal Cosh A [radians] Transform With Offset 3D | z = a * cosh(bx+c) + d * cosh(fy+g) z = 1.0 / z + Offset | |
| Reciprocal Cosh A [radians] With Offset 3D | z = a * cosh(x) + b * cosh(y) z = 1.0 / z + Offset | |
| Reciprocal Cosh B [radians] Transform With Offset 3D | z = a * cosh(bx+c) * cosh(dy+f) z = 1.0 / z + Offset | |
| Reciprocal Cosh B [radians] With Offset 3D | z = a * cosh(x) * cosh(y) z = 1.0 / z + Offset | |
| Reciprocal Cosh XY [radians] Transform With Offset 3D | z = a * cosh(b * xy + c) z = 1.0 / z + Offset | |
| Reciprocal Cosh XY [radians] With Offset 3D | z = a * cosh(xy) z = 1.0 / z + Offset | |
| Reciprocal Reza's Custom Equation One [radians] With Offset 3D | z = (cos(a*x - b*y) + sin(c*x - d*y))n - (cos(f*x - g*y) + sin(h*x- i*y))n z = 1.0 / z + Offset | |
| Reciprocal Reza's Custom Equation Two [radians] With Offset 3D | z = abs(cos((A*(x+B)) + C*(y+D))) + abs(cos((A*(x+B)) - C*(y+D))) - (sin(E*x+F))2 - (sin(E*y+G))2 z = 1.0 / z + Offset | |
| Reciprocal Sine A [radians] Transform With Offset 3D | z = a * sin(bx+c) + d * sin(fy+g) z = 1.0 / z + Offset | |
| Reciprocal Sine A [radians] With Offset 3D | z = a * sin(x) + b * sin(y) z = 1.0 / z + Offset | |
| Reciprocal Sine B [radians] Transform With Offset 3D | z = a * sin(bx+c) * sin(dy+f) z = 1.0 / z + Offset | |
| Reciprocal Sine B [radians] With Offset 3D | z = a * sin(x) * sin(y) z = 1.0 / z + Offset | |
| Reciprocal Sine XY [radians] Transform With Offset 3D | z = a * sin(b * xy + c) z = 1.0 / z + Offset | |
| Reciprocal Sine XY [radians] With Offset 3D | z = a * sin(xy) z = 1.0 / z + Offset | |
| Reciprocal Tan A [radians] Transform With Offset 3D | z = a * tan(bx + c) + d * tan(fy + g) z = 1.0 / z + Offset | |
| Reciprocal Tan A [radians] With Offset 3D | z = a * tan(x) + b * tan(y) z = 1.0 / z + Offset | |
| Reciprocal Tan B [radians] Transform With Offset 3D | z = a * tan(bx + c) * tan(dy + f) z = 1.0 / z + Offset | |
| Reciprocal Tan B [radians] With Offset 3D | z = a * tan(x) * tan(y) z = 1.0 / z + Offset | |
| Reciprocal Tan XY [radians] With Offset 3D | z = a * tan(xy) z = 1.0 / z + Offset | |