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    Chen-Clayton Scaled With Exponential Decay And Offset 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z / exp(xy) + Offset   [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) / (f * 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 / (f * 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) / (d * exp(xy)) + Offset   [web citation]
    Modified Halsey Scaled With Exponential Decay And Offset 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z / 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) / (d * 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) / (d * 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) / (f * exp(xy)) + Offset   [web citation]
     
     
    Chen-Clayton Scaled With Exponential Decay 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z / exp(xy)   [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) / (f * 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 / (h * exp(xy))
    Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Exponential Decay 3D  
z = ay / (b + x + y) + cy / (d + x + y)
z = z / (f * 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) / (d * exp(xy))   [web citation]
    Modified Halsey Scaled With Exponential Decay 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z / 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) / (d * 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) / (d * 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) / (f * exp(xy))   [web citation]
     
     
    Chen-Clayton Scaled With Exponential Growth And Offset 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z * exp(xy) + Offset   [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) * (f * 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 * (f * 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) * (d * exp(xy)) + Offset   [web citation]
    Modified Halsey Scaled With Exponential Growth And Offset 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z * 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) * (d * 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) * (d * 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) * (f * exp(xy)) + Offset   [web citation]
     
     
    Chen-Clayton Scaled With Exponential Growth 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z * exp(xy)   [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) * (f * 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 * (h * exp(xy))
    Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Exponential Growth 3D  
z = ay / (b + x + y) + cy / (d + x + y)
z = z * (f * 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) * (d * exp(xy))   [web citation]
    Modified Halsey Scaled With Exponential Growth 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z * 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) * (d * 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) * (d * 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) * (f * exp(xy))   [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 Chen-Clayton Scaled 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = xy / z   [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 Halsey Scaled 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = xy / z   [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 Scaled With Offset 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = xy / (z + Offset   [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 Scaled With Offset 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = xy / (z + 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 Scaled With Linear Decay And Offset 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z / xy + Offset   [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) / (f * 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 / (f * 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) / (d * xy) + Offset   [web citation]
    Modified Halsey Scaled With Linear Decay And Offset 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z / 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) / (d * 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) / (d * 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) / (f * xy) + Offset   [web citation]
     
     
    Chen-Clayton Scaled With Linear Decay 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z / xy   [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) / (f * 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 / (h * xy)
    Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Linear Decay 3D  
z = ay / (b + x + y) + cy / (d + x + y)
z = z / (f * 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) / (d * xy)   [web citation]
    Modified Halsey Scaled With Linear Decay 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z / 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) / (d * 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) / (d * 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) / (f * xy)   [web citation]
     
     
    Chen-Clayton Scaled With Linear Growth And Offset 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z * 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) * (f * 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 * (f * 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) * (d * xy) + Offset   [web citation]
    Modified Halsey Scaled With Linear Growth And Offset 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z * 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) * (d * 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) * (d * 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) * (f * xy) + Offset   [web citation]
     
     
    Chen-Clayton Scaled With Linear Growth 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = z * xy   [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) * (f * xy)   [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 * (h * xy)
    Michaelis-Menten Double Isotope Displacement (y = [Hot]) With Linear Growth 3D  
z = ay / (b + x + y) + cy / (d + x + y)
z = z * (f * xy)
    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) * (d * xy)   [web citation]
    Modified Halsey Scaled With Linear Growth 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = z * xy   [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) * (d * xy)   [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) * (d * xy)   [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) * (f * xy)   [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 Chen-Clayton Scaled 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = 1.0 / z   [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 Halsey Scaled 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = 1.0 / z   [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 Scaled With Offset 3D  
z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M))
z = 1.0 / z + Offset   [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 Scaled With Offset 3D  
z = Scale * exp(-exp(C1 + C2*T) * M-C3)
z = 1.0 / z + 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]
     
     
    Chen-Clayton 3D   r.h.(Tk,M) = exp(-(C1/TC2) * exp(-C3*TC4*M))   [web citation]
    Chen-Clayton Scaled 3D   z = Scale * 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 Halsey Scaled 3D   z = Scale * 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 Scaled With Offset 3D   z = Scale * exp(-(C1/TC2) * exp(-C3*TC4*M)) + Offset   [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 Scaled With Offset 3D   z = Scale * exp(-exp(C1 + C2*T) * M-C3) + 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]
     
     
    High-Low Affinity Isotope Displacement (y = [Hot]) Plus Plane 3D  
z = aby / (1+b(x+y))
z = z + (c * x) + (d * y) + f
    Michaelis-Menten Isotope Displacement (y = [Hot]) Plus Plane 3D  
z = ay / (b + x + y)
z = z + (c * x) + (d * y) + f
    Modified Chung-Pfost Plus Plane 3D  
r.h.(T,M) = exp(-(C1/(T+C2)) * exp(-C3*M))
r.h.(T,M) = r.h.(T,M) + (d * x) + (f * y) + g   [web citation]
    Modified Halsey Plus Plane 3D  
r.h.(T,M) = exp(-exp(C1 + C2*T) * M-C3)
r.h.(T,M) = r.h.(T,M) + (d * x) + (f * y) + g   [web citation]
    Modified Henderson Plus Plane 3D  
r.h.(T,M) = 1 - exp(-C1 * (T + C2) * MC3)
r.h.(T,M) = r.h.(T,M) + (d * x) + (f * y) + g   [web citation]
     
     


3D EnzymeKinetics

    Competitive Inhibition A With Exponential Decay And Offset 3D  
z = ax / (b(1 + y/c) + x)
z = z / exp(xy) + Offset
    Competitive Inhibition B With Exponential Decay And Offset 3D  
z = ay / (b(1 + x/c) + y)
z = z / exp(xy) + Offset
    Competitive Inhibition C With Exponential Decay And Offset 3D  
z = axy / (b(1 + x/c) + y)
z = z / exp(xy) + Offset
    Inhibition By Competing Substrate A With Exponential Decay And Offset 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z / exp(xy) + Offset
    Inhibition By Competing Substrate B With Exponential Decay And Offset 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z / exp(xy) + Offset
    Inhibition By Competing Substrate C With Exponential Decay And Offset 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z / exp(xy) + Offset
    Michaelis Menten Product Inhibition With Exponential Decay And Offset 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z / (f * exp(xy)) + Offset
    Mixed Inhibition A With Exponential Decay And Offset 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z / exp(xy) + Offset
    Mixed Inhibition B With Exponential Decay And Offset 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z / exp(xy) + Offset
    Noncompetitive Inhibition A With Exponential Decay And Offset 3D  
z = ax / ((b + x)(1 + y/c))
z = z / exp(xy) + Offset
    Noncompetitive Inhibition B With Exponential Decay And Offset 3D  
z = ay / ((b + y)(1 + x/c))
z = z / exp(xy) + Offset
    Ping Pong Bi Bi A With Exponential Decay And Offset 3D  
z = ax / (bx + cy + xy)
z = z / exp(xy) + Offset
    Ping Pong Bi Bi B With Exponential Decay And Offset 3D  
z = ay / (by + cx + xy)
z = z / exp(xy) + Offset
    Ping Pong Bi Bi C With Exponential Decay And Offset 3D  
z = axy / (by + cx + xy)
z = z / exp(xy) + Offset
    Uncompetitive Inhibition A With Exponential Decay And Offset 3D  
z = ax / (b + x(1 + y/c))
z = z / exp(xy) + Offset
    Uncompetitive Inhibition B With Exponential Decay And Offset 3D  
z = ay / (b + y(1 + x/c))
z = z / exp(xy) + Offset
     
     
    Competitive Inhibition A With Exponential Decay 3D  
z = ax / (b(1 + y/c) + x)
z = z / exp(xy)
    Competitive Inhibition B With Exponential Decay 3D  
z = ay / (b(1 + x/c) + y)
z = z / exp(xy)
    Competitive Inhibition C With Exponential Decay 3D  
z = axy / (b(1 + x/c) + y)
z = z / exp(xy)
    Inhibition By Competing Substrate A With Exponential Decay 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z / exp(xy)
    Inhibition By Competing Substrate B With Exponential Decay 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z / exp(xy)
    Inhibition By Competing Substrate C With Exponential Decay 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z / exp(xy)
    Michaelis Menten Product Inhibition With Exponential Decay 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z / (f * exp(xy))
    Mixed Inhibition A With Exponential Decay 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z / exp(xy)
    Mixed Inhibition B With Exponential Decay 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z / exp(xy)
    Noncompetitive Inhibition A With Exponential Decay 3D  
z = ax / ((b + x)(1 + y/c))
z = z / exp(xy)
    Noncompetitive Inhibition B With Exponential Decay 3D  
z = ay / ((b + y)(1 + x/c))
z = z / exp(xy)
    Ping Pong Bi Bi A With Exponential Decay 3D  
z = ax / (bx + cy + xy)
z = z / exp(xy)
    Ping Pong Bi Bi B With Exponential Decay 3D  
z = ay / (by + cx + xy)
z = z / exp(xy)
    Ping Pong Bi Bi C With Exponential Decay 3D  
z = axy / (by + cx + xy)
z = z / exp(xy)
    Uncompetitive Inhibition A With Exponential Decay 3D  
z = ax / (b + x(1 + y/c))
z = z / exp(xy)
    Uncompetitive Inhibition B With Exponential Decay 3D  
z = ay / (b + y(1 + x/c))
z = z / exp(xy)
     
     
    Competitive Inhibition A With Exponential Growth And Offset 3D  
z = ax / (b(1 + y/c) + x)
z = z * exp(xy) + Offset
    Competitive Inhibition B With Exponential Growth And Offset 3D  
z = ay / (b(1 + x/c) + y)
z = z * exp(xy) + Offset
    Competitive Inhibition C With Exponential Growth And Offset 3D  
z = axy / (b(1 + x/c) + y)
z = z * exp(xy) + Offset
    Inhibition By Competing Substrate A With Exponential Growth And Offset 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z * exp(xy) + Offset
    Inhibition By Competing Substrate B With Exponential Growth And Offset 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z * exp(xy) + Offset
    Inhibition By Competing Substrate C With Exponential Growth And Offset 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z * exp(xy) + Offset
    Michaelis Menten Product Inhibition With Exponential Growth And Offset 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z * (f * exp(xy)) + Offset
    Mixed Inhibition A With Exponential Growth And Offset 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z * exp(xy) + Offset
    Mixed Inhibition B With Exponential Growth And Offset 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z * exp(xy) + Offset
    Noncompetitive Inhibition A With Exponential Growth And Offset 3D  
z = ax / ((b + x)(1 + y/c))
z = z * exp(xy) + Offset
    Noncompetitive Inhibition B With Exponential Growth And Offset 3D  
z = ay / ((b + y)(1 + x/c))
z = z * exp(xy) + Offset
    Ping Pong Bi Bi A With Exponential Growth And Offset 3D  
z = ax / (bx + cy + xy)
z = z * exp(xy) + Offset
    Ping Pong Bi Bi B With Exponential Growth And Offset 3D  
z = ay / (by + cx + xy)
z = z * exp(xy) + Offset
    Ping Pong Bi Bi C With Exponential Growth And Offset 3D  
z = axy / (by + cx + xy)
z = z * exp(xy) + Offset
    Uncompetitive Inhibition A With Exponential Growth And Offset 3D  
z = ax / (b + x(1 + y/c))
z = z * exp(xy) + Offset
    Uncompetitive Inhibition B With Exponential Growth And Offset 3D  
z = ay / (b + y(1 + x/c))
z = z * exp(xy) + Offset
     
     
    Competitive Inhibition A With Exponential Growth 3D  
z = ax / (b(1 + y/c) + x)
z = z * exp(xy)
    Competitive Inhibition B With Exponential Growth 3D  
z = ay / (b(1 + x/c) + y)
z = z * exp(xy)
    Competitive Inhibition C With Exponential Growth 3D  
z = axy / (b(1 + x/c) + y)
z = z * exp(xy)
    Inhibition By Competing Substrate A With Exponential Growth 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z * exp(xy)
    Inhibition By Competing Substrate B With Exponential Growth 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z * exp(xy)
    Inhibition By Competing Substrate C With Exponential Growth 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z * exp(xy)
    Michaelis Menten Product Inhibition With Exponential Growth 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z * (f * exp(xy))
    Mixed Inhibition A With Exponential Growth 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z * exp(xy)
    Mixed Inhibition B With Exponential Growth 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z * exp(xy)
    Noncompetitive Inhibition A With Exponential Growth 3D  
z = ax / ((b + x)(1 + y/c))
z = z * exp(xy)
    Noncompetitive Inhibition B With Exponential Growth 3D  
z = ay / ((b + y)(1 + x/c))
z = z * exp(xy)
    Ping Pong Bi Bi A With Exponential Growth 3D  
z = ax / (bx + cy + xy)
z = z * exp(xy)
    Ping Pong Bi Bi B With Exponential Growth 3D  
z = ay / (by + cx + xy)
z = z * exp(xy)
    Ping Pong Bi Bi C With Exponential Growth 3D  
z = axy / (by + cx + xy)
z = z * exp(xy)
    Uncompetitive Inhibition A With Exponential Growth 3D  
z = ax / (b + x(1 + y/c))
z = z * exp(xy)
    Uncompetitive Inhibition B With Exponential Growth 3D  
z = ay / (b + y(1 + x/c))
z = z * exp(xy)
     
     
    Inverse Competitive Inhibition A 3D  
z = ax / (b(1 + y/c) + x)
z = xy / z
    Inverse Competitive Inhibition B 3D  
z = ay / (b(1 + x/c) + y)
z = xy / z
    Inverse Competitive Inhibition C 3D  
z = axy / (b(1 + x/c) + y)
z = xy / z
    Inverse Inhibition By Competing Substrate A 3D  
z = (ax/b) / (1 + x/b + y/c)
z = xy / z
    Inverse Inhibition By Competing Substrate B 3D  
z = (ay/b) / (1 + y/b + x/c)
z = xy / z
    Inverse Inhibition By Competing Substrate C 3D  
z = (axy/b) / (1 + y/b + x/c)
z = xy / z
    Inverse Michaelis Menten Product Inhibition 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = xy / z
    Inverse Mixed Inhibition A 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = xy / z
    Inverse Mixed Inhibition B 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = xy / z
    Inverse Noncompetitive Inhibition A 3D  
z = ax / ((b + x)(1 + y/c))
z = xy / z
    Inverse Noncompetitive Inhibition B 3D  
z = ay / ((b + y)(1 + x/c))
z = xy / z
    Inverse Ping Pong Bi Bi A 3D  
z = ax / (bx + cy + xy)
z = xy / z
    Inverse Ping Pong Bi Bi B 3D  
z = ay / (by + cx + xy)
z = xy / z
    Inverse Ping Pong Bi Bi C 3D  
z = axy / (by + cx + xy)
z = xy / z
    Inverse Uncompetitive Inhibition A 3D  
z = ax / (b + x(1 + y/c))
z = xy / z
    Inverse Uncompetitive Inhibition B 3D  
z = ay / (b + y(1 + x/c))
z = xy / z
     
     
    Inverse Competitive Inhibition A With Offset 3D  
z = ax / (b(1 + y/c) + x)
z = xy / (z + Offset
    Inverse Competitive Inhibition B With Offset 3D  
z = ay / (b(1 + x/c) + y)
z = xy / (z + Offset
    Inverse Competitive Inhibition C With Offset 3D  
z = axy / (b(1 + x/c) + y)
z = xy / (z + Offset
    Inverse Inhibition By Competing Substrate A With Offset 3D  
z = (ax/b) / (1 + x/b + y/c)
z = xy / (z + Offset
    Inverse Inhibition By Competing Substrate B With Offset 3D  
z = (ay/b) / (1 + y/b + x/c)
z = xy / (z + Offset
    Inverse Inhibition By Competing Substrate C With Offset 3D  
z = (axy/b) / (1 + y/b + x/c)
z = xy / (z + Offset
    Inverse Michaelis Menten Product Inhibition With Offset 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = xy / (z + Offset
    Inverse Mixed Inhibition A With Offset 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = xy / (z + Offset
    Inverse Mixed Inhibition B With Offset 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = xy / (z + Offset
    Inverse Noncompetitive Inhibition A With Offset 3D  
z = ax / ((b + x)(1 + y/c))
z = xy / (z + Offset
    Inverse Noncompetitive Inhibition B With Offset 3D  
z = ay / ((b + y)(1 + x/c))
z = xy / (z + Offset
    Inverse Ping Pong Bi Bi A With Offset 3D  
z = ax / (bx + cy + xy)
z = xy / (z + Offset
    Inverse Ping Pong Bi Bi B With Offset 3D  
z = ay / (by + cx + xy)
z = xy / (z + Offset
    Inverse Ping Pong Bi Bi C With Offset 3D  
z = axy / (by + cx + xy)
z = xy / (z + Offset
    Inverse Uncompetitive Inhibition A With Offset 3D  
z = ax / (b + x(1 + y/c))
z = xy / (z + Offset
    Inverse Uncompetitive Inhibition B With Offset 3D  
z = ay / (b + y(1 + x/c))
z = xy / (z + Offset
     
     
    Competitive Inhibition A With Linear Decay And Offset 3D  
z = ax / (b(1 + y/c) + x)
z = z / xy + Offset
    Competitive Inhibition B With Linear Decay And Offset 3D  
z = ay / (b(1 + x/c) + y)
z = z / xy + Offset
    Competitive Inhibition C With Linear Decay And Offset 3D  
z = axy / (b(1 + x/c) + y)
z = z / xy + Offset
    Inhibition By Competing Substrate A With Linear Decay And Offset 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z / xy + Offset
    Inhibition By Competing Substrate B With Linear Decay And Offset 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z / xy + Offset
    Inhibition By Competing Substrate C With Linear Decay And Offset 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z / xy + Offset
    Michaelis Menten Product Inhibition With Linear Decay And Offset 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z / (f * xy) + Offset
    Mixed Inhibition A With Linear Decay And Offset 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z / xy + Offset
    Mixed Inhibition B With Linear Decay And Offset 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z / xy + Offset
    Noncompetitive Inhibition A With Linear Decay And Offset 3D  
z = ax / ((b + x)(1 + y/c))
z = z / xy + Offset
    Noncompetitive Inhibition B With Linear Decay And Offset 3D  
z = ay / ((b + y)(1 + x/c))
z = z / xy + Offset
    Ping Pong Bi Bi A With Linear Decay And Offset 3D  
z = ax / (bx + cy + xy)
z = z / xy + Offset
    Ping Pong Bi Bi B With Linear Decay And Offset 3D  
z = ay / (by + cx + xy)
z = z / xy + Offset
    Ping Pong Bi Bi C With Linear Decay And Offset 3D  
z = axy / (by + cx + xy)
z = z / xy + Offset
    Uncompetitive Inhibition A With Linear Decay And Offset 3D  
z = ax / (b + x(1 + y/c))
z = z / xy + Offset
    Uncompetitive Inhibition B With Linear Decay And Offset 3D  
z = ay / (b + y(1 + x/c))
z = z / xy + Offset
     
     
    Competitive Inhibition A With Linear Decay 3D  
z = ax / (b(1 + y/c) + x)
z = z / xy
    Competitive Inhibition B With Linear Decay 3D  
z = ay / (b(1 + x/c) + y)
z = z / xy
    Competitive Inhibition C With Linear Decay 3D  
z = axy / (b(1 + x/c) + y)
z = z / xy
    Inhibition By Competing Substrate A With Linear Decay 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z / xy
    Inhibition By Competing Substrate B With Linear Decay 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z / xy
    Inhibition By Competing Substrate C With Linear Decay 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z / xy
    Michaelis Menten Product Inhibition With Linear Decay 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z / (f * xy)
    Mixed Inhibition A With Linear Decay 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z / xy
    Mixed Inhibition B With Linear Decay 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z / xy
    Noncompetitive Inhibition A With Linear Decay 3D  
z = ax / ((b + x)(1 + y/c))
z = z / xy
    Noncompetitive Inhibition B With Linear Decay 3D  
z = ay / ((b + y)(1 + x/c))
z = z / xy
    Ping Pong Bi Bi A With Linear Decay 3D  
z = ax / (bx + cy + xy)
z = z / xy
    Ping Pong Bi Bi B With Linear Decay 3D  
z = ay / (by + cx + xy)
z = z / xy
    Ping Pong Bi Bi C With Linear Decay 3D  
z = axy / (by + cx + xy)
z = z / xy
    Uncompetitive Inhibition A With Linear Decay 3D  
z = ax / (b + x(1 + y/c))
z = z / xy
    Uncompetitive Inhibition B With Linear Decay 3D  
z = ay / (b + y(1 + x/c))
z = z / xy
     
     
    Competitive Inhibition A With Linear Growth And Offset 3D  
z = ax / (b(1 + y/c) + x)
z = z * xy + Offset
    Competitive Inhibition B With Linear Growth And Offset 3D  
z = ay / (b(1 + x/c) + y)
z = z * xy + Offset
    Competitive Inhibition C With Linear Growth And Offset 3D  
z = axy / (b(1 + x/c) + y)
z = z * xy + Offset
    Inhibition By Competing Substrate A With Linear Growth And Offset 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z * xy + Offset
    Inhibition By Competing Substrate B With Linear Growth And Offset 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z * xy + Offset
    Inhibition By Competing Substrate C With Linear Growth And Offset 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z * xy + Offset
    Michaelis Menten Product Inhibition With Linear Growth And Offset 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z * (f * xy) + Offset
    Mixed Inhibition A With Linear Growth And Offset 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z * xy + Offset
    Mixed Inhibition B With Linear Growth And Offset 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z * xy + Offset
    Noncompetitive Inhibition A With Linear Growth And Offset 3D  
z = ax / ((b + x)(1 + y/c))
z = z * xy + Offset
    Noncompetitive Inhibition B With Linear Growth And Offset 3D  
z = ay / ((b + y)(1 + x/c))
z = z * xy + Offset
    Ping Pong Bi Bi A With Linear Growth And Offset 3D  
z = ax / (bx + cy + xy)
z = z * xy + Offset
    Ping Pong Bi Bi B With Linear Growth And Offset 3D  
z = ay / (by + cx + xy)
z = z * xy + Offset
    Ping Pong Bi Bi C With Linear Growth And Offset 3D  
z = axy / (by + cx + xy)
z = z * xy + Offset
    Uncompetitive Inhibition A With Linear Growth And Offset 3D  
z = ax / (b + x(1 + y/c))
z = z * xy + Offset
    Uncompetitive Inhibition B With Linear Growth And Offset 3D  
z = ay / (b + y(1 + x/c))
z = z * xy + Offset
     
     
    Competitive Inhibition A With Linear Growth 3D  
z = ax / (b(1 + y/c) + x)
z = z * xy
    Competitive Inhibition B With Linear Growth 3D  
z = ay / (b(1 + x/c) + y)
z = z * xy
    Competitive Inhibition C With Linear Growth 3D  
z = axy / (b(1 + x/c) + y)
z = z * xy
    Inhibition By Competing Substrate A With Linear Growth 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z * xy
    Inhibition By Competing Substrate B With Linear Growth 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z * xy
    Inhibition By Competing Substrate C With Linear Growth 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z * xy
    Michaelis Menten Product Inhibition With Linear Growth 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = z * (f * xy)
    Mixed Inhibition A With Linear Growth 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = z * xy
    Mixed Inhibition B With Linear Growth 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = z * xy
    Noncompetitive Inhibition A With Linear Growth 3D  
z = ax / ((b + x)(1 + y/c))
z = z * xy
    Noncompetitive Inhibition B With Linear Growth 3D  
z = ay / ((b + y)(1 + x/c))
z = z * xy
    Ping Pong Bi Bi A With Linear Growth 3D  
z = ax / (bx + cy + xy)
z = z * xy
    Ping Pong Bi Bi B With Linear Growth 3D  
z = ay / (by + cx + xy)
z = z * xy
    Ping Pong Bi Bi C With Linear Growth 3D  
z = axy / (by + cx + xy)
z = z * xy
    Uncompetitive Inhibition A With Linear Growth 3D  
z = ax / (b + x(1 + y/c))
z = z * xy
    Uncompetitive Inhibition B With Linear Growth 3D  
z = ay / (b + y(1 + x/c))
z = z * xy
     
     
    Reciprocal Competitive Inhibition A 3D  
z = ax / (b(1 + y/c) + x)
z = 1.0 / z
    Reciprocal Competitive Inhibition B 3D  
z = ay / (b(1 + x/c) + y)
z = 1.0 / z
    Reciprocal Competitive Inhibition C 3D  
z = axy / (b(1 + x/c) + y)
z = 1.0 / z
    Reciprocal Inhibition By Competing Substrate A 3D  
z = (ax/b) / (1 + x/b + y/c)
z = 1.0 / z
    Reciprocal Inhibition By Competing Substrate B 3D  
z = (ay/b) / (1 + y/b + x/c)
z = 1.0 / z
    Reciprocal Inhibition By Competing Substrate C 3D  
z = (axy/b) / (1 + y/b + x/c)
z = 1.0 / z
    Reciprocal Michaelis Menten Product Inhibition 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = 1.0 / z
    Reciprocal Mixed Inhibition A 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = 1.0 / z
    Reciprocal Mixed Inhibition B 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = 1.0 / z
    Reciprocal Noncompetitive Inhibition A 3D  
z = ax / ((b + x)(1 + y/c))
z = 1.0 / z
    Reciprocal Noncompetitive Inhibition B 3D  
z = ay / ((b + y)(1 + x/c))
z = 1.0 / z
    Reciprocal Ping Pong Bi Bi A 3D  
z = ax / (bx + cy + xy)
z = 1.0 / z
    Reciprocal Ping Pong Bi Bi B 3D  
z = ay / (by + cx + xy)
z = 1.0 / z
    Reciprocal Ping Pong Bi Bi C 3D  
z = axy / (by + cx + xy)
z = 1.0 / z
    Reciprocal Uncompetitive Inhibition A 3D  
z = ax / (b + x(1 + y/c))
z = 1.0 / z
    Reciprocal Uncompetitive Inhibition B 3D  
z = ay / (b + y(1 + x/c))
z = 1.0 / z
     
     
    Reciprocal Competitive Inhibition A With Offset 3D  
z = ax / (b(1 + y/c) + x)
z = 1.0 / z + Offset
    Reciprocal Competitive Inhibition B With Offset 3D  
z = ay / (b(1 + x/c) + y)
z = 1.0 / z + Offset
    Reciprocal Competitive Inhibition C With Offset 3D  
z = axy / (b(1 + x/c) + y)
z = 1.0 / z + Offset
    Reciprocal Inhibition By Competing Substrate A With Offset 3D  
z = (ax/b) / (1 + x/b + y/c)
z = 1.0 / z + Offset
    Reciprocal Inhibition By Competing Substrate B With Offset 3D  
z = (ay/b) / (1 + y/b + x/c)
z = 1.0 / z + Offset
    Reciprocal Inhibition By Competing Substrate C With Offset 3D  
z = (axy/b) / (1 + y/b + x/c)
z = 1.0 / z + Offset
    Reciprocal Michaelis Menten Product Inhibition With Offset 3D  
z = (ax/b - cy/d) / (1 + x/b + y/d)
z = 1.0 / z + Offset
    Reciprocal Mixed Inhibition A With Offset 3D  
z = ax / (b(1 + y/c) + x(1 + y/d))
z = 1.0 / z + Offset
    Reciprocal Mixed Inhibition B With Offset 3D  
z = ay / (b(1 + x/c) + y(1 + x/d))
z = 1.0 / z + Offset
    Reciprocal Noncompetitive Inhibition A With Offset 3D  
z = ax / ((b + x)(1 + y/c))
z = 1.0 / z + Offset
    Reciprocal Noncompetitive Inhibition B With Offset 3D  
z = ay / ((b + y)(1 + x/c))
z = 1.0 / z + Offset
    Reciprocal Ping Pong Bi Bi A With Offset 3D  
z = ax / (bx + cy + xy)
z = 1.0 / z + Offset
    Reciprocal Ping Pong Bi Bi B With Offset 3D  
z = ay / (by + cx + xy)
z = 1.0 / z + Offset
    Reciprocal Ping Pong Bi Bi C With Offset 3D  
z = axy / (by + cx + xy)
z = 1.0 / z + Offset
    Reciprocal Uncompetitive Inhibition A With Offset 3D  
z = ax / (b + x(1 + y/c))
z = 1.0 / z + Offset
    Reciprocal Uncompetitive Inhibition B With Offset 3D  
z = ay / (b + y(1 + x/c))
z = 1.0 / z + Offset
     
     
    Competitive Inhibition A 3D   z = ax / (b(1 + y/c) + x)
    Competitive Inhibition B 3D   z = ay / (b(1 + x/c) + y)
    Competitive Inhibition C 3D   z = axy / (b(1 + x/c) + y)
    Inhibition By Competing Substrate A 3D   z = (ax/b) / (1 + x/b + y/c)
    Inhibition By Competing Substrate B 3D   z = (ay/b) / (1 + y/b + x/c)
    Inhibition By Competing Substrate C 3D   z = (axy/b) / (1 + y/b + x/c)
    Michaelis Menten Product Inhibition 3D   z = (ax/b - cy/d) / (1 + x/b + y/d)
    Mixed Inhibition A 3D   z = ax / (b(1 + y/c) + x(1 + y/d))
    Mixed Inhibition B 3D   z = ay / (b(1 + x/c) + y(1 + x/d))
    Noncompetitive Inhibition A 3D   z = ax / ((b + x)(1 + y/c))
    Noncompetitive Inhibition B 3D   z = ay / ((b + y)(1 + x/c))
    Ping Pong Bi Bi A 3D   z = ax / (bx + cy + xy)
    Ping Pong Bi Bi B 3D   z = ay / (by + cx + xy)
    Ping Pong Bi Bi C 3D   z = axy / (by + cx + xy)
    Uncompetitive Inhibition A 3D   z = ax / (b + x(1 + y/c))
    Uncompetitive Inhibition B 3D   z = ay / (b + y(1 + x/c))
     
     
    Competitive Inhibition A With Offset 3D   z = ax / (b(1 + y/c) + x) + Offset
    Competitive Inhibition B With Offset 3D   z = ay / (b(1 + x/c) + y) + Offset
    Competitive Inhibition C With Offset 3D   z = axy / (b(1 + x/c) + y) + Offset
    Inhibition By Competing Substrate A With Offset 3D   z = (ax/b) / (1 + x/b + y/c) + Offset
    Inhibition By Competing Substrate B With Offset 3D   z = (ay/b) / (1 + y/b + x/c) + Offset
    Inhibition By Competing Substrate C With Offset 3D   z = (axy/b) / (1 + y/b + x/c) + Offset
    Michaelis Menten Product Inhibition With Offset 3D   z = (ax/b - cy/d) / (1 + x/b + y/d) + Offset
    Mixed Inhibition A With Offset 3D   z = ax / (b(1 + y/c) + x(1 + y/d)) + Offset
    Mixed Inhibition B With Offset 3D   z = ay / (b(1 + x/c) + y(1 + x/d)) + Offset
    Noncompetitive Inhibition A With Offset 3D   z = ax / ((b + x)(1 + y/c)) + Offset
    Noncompetitive Inhibition B With Offset 3D   z = ay / ((b + y)(1 + x/c)) + Offset
    Ping Pong Bi Bi A With Offset 3D   z = ax / (bx + cy + xy) + Offset
    Ping Pong Bi Bi B With Offset 3D   z = ay / (by + cx + xy) + Offset
    Ping Pong Bi Bi C With Offset 3D   z = axy / (by + cx + xy) + Offset
    Uncompetitive Inhibition A With Offset 3D   z = ax / (b + x(1 + y/c)) + Offset
    Uncompetitive Inhibition B With Offset 3D   z = ay / (b + y(1 + x/c)) + Offset
     
     
    Competitive Inhibition A Plus Plane 3D  
z = ax / (b(1 + y/c) + x)
z = z + (d * x) + (f * y) + g
    Competitive Inhibition B Plus Plane 3D  
z = ay / (b(1 + x/c) + y)
z = z + (d * x) + (f * y) + g
    Competitive Inhibition C Plus Plane 3D  
z = axy / (b(1 + x/c) + y)
z = z + (d * x) + (f * y) + g
    Inhibition By Competing Substrate A Plus Plane 3D  
z = (ax/b) / (1 + x/b + y/c)
z = z + (d * x) + (f * y) + g
    Inhibition By Competing Substrate B Plus Plane 3D  
z = (ay/b) / (1 + y/b + x/c)
z = z + (d * x) + (f * y) + g
    Inhibition By Competing Substrate C Plus Plane 3D  
z = (axy/b) / (1 + y/b + x/c)
z = z + (d * x) + (f * y) + g
    Noncompetitive Inhibition A Plus Plane 3D  
z = ax / ((b + x)(1 + y/c))
z = z + (d * x) + (f * y) + g
    Noncompetitive Inhibition B Plus Plane 3D  
z = ay / ((b + y)(1 + x/c))
z = z + (d * x) + (f * y) + g
    Ping Pong Bi Bi A Plus Plane 3D  
z = ax / (bx + cy + xy)
z = z + (d * x) + (f * y) + g
    Ping Pong Bi Bi B Plus Plane 3D  
z = ay / (by + cx + xy)
z = z + (d * x) + (f * y) + g
    Ping Pong Bi Bi C Plus Plane 3D  
z = axy / (by + cx + xy)
z = z + (d * x) + (f * y) + g
    Uncompetitive Inhibition A Plus Plane 3D  
z = ax / (b + x(1 + y/c))
z = z + (d * x) + (f * y) + g
    Uncompetitive Inhibition B Plus Plane 3D  
z = ay / (b + y(1 + x/c))
z = z + (d * x) + (f * y) + g
     
     


3D Exponential

    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 / (m * 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 / (h * exp(xy))
    Linear Exponential With Exponential Decay 3D  
z = a + b*exp(x) + c*exp(y)
z = z / (d * 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 / (i * 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 / (g * exp(xy))
    Transform Full Cubic Exponential 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 / (r * exp(xy))
    Transform Full Quadratic Exponential 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 / (m * exp(xy))
    Transform Linear Exponential With Exponential Decay 3D  
z = a + b*exp(d*x+f) + c*exp(g*y+h)
z = z / (i * exp(xy))
    Transform Simplified Cubic Exponential 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 / (n * exp(xy))
    Transform Simplified Quadratic Exponential 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 / (k * 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 * (m * 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 * (h * exp(xy))
    Linear Exponential With Exponential Growth 3D  
z = a + b*exp(x) + c*exp(y)
z = z * (d * 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 * (i * 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 * (g * exp(xy))
    Transform Full Cubic Exponential 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 * (r * exp(xy))
    Transform Full Quadratic Exponential 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 * (m * exp(xy))
    Transform Linear Exponential With Exponential Growth 3D  
z = a + b*exp(d*x+f) + c*exp(g*y+h)
z = z * (i * exp(xy))
    Transform Simplified Cubic Exponential 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 * (n * exp(xy))
    Transform Simplified Quadratic Exponential 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 * (k * 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 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 Linear Exponential 3D  
z = a + b*exp(x) + c*exp(y)
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 Quadratic Exponential 3D  
z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2
z = xy / z
    Inverse Transform Full Cubic Exponential 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 Transform Full Quadratic Exponential 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 Transform Linear Exponential 3D  
z = a + b*exp(d*x+f) + c*exp(g*y+h)
z = xy / z
    Inverse Transform Simplified Cubic Exponential 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 Transform Simplified Quadratic Exponential 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 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 / (m * 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 / (h * xy)
    Linear Exponential With Linear Decay 3D  
z = a + b*exp(x) + c*exp(y)
z = z / (d * 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 / (i * 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 / (g * xy)
    Transform Full Cubic Exponential 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 / (r * xy)
    Transform Full Quadratic Exponential 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 / (m * xy)
    Transform Linear Exponential With Linear Decay 3D  
z = a + b*exp(d*x+f) + c*exp(g*y+h)
z = z / (i * xy)
    Transform Simplified Cubic Exponential 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 / (n * xy)
    Transform Simplified Quadratic Exponential 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 / (k * xy)
     
     
    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 * (m * xy)
    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 * (h * xy)
    Linear Exponential With Linear Growth 3D  
z = a + b*exp(x) + c*exp(y)
z = z * (d * xy)
    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 * (i * xy)
    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 * (g * xy)
    Transform Full Cubic Exponential 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 * (r * xy)
    Transform Full Quadratic Exponential 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 * (m * xy)
    Transform Linear Exponential With Linear Growth 3D  
z = a + b*exp(d*x+f) + c*exp(g*y+h)
z = z * (i * xy)
    Transform Simplified Cubic Exponential 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 * (n * xy)
    Transform Simplified Quadratic Exponential 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 * (k * xy)
     
     
    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 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 Linear Exponential 3D  
z = a + b*exp(x) + c*exp(y)
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 Quadratic Exponential 3D  
z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2
z = 1.0 / z
    Reciprocal Transform Full Cubic Exponential 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 Transform Full Quadratic Exponential 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 Transform Linear Exponential 3D  
z = a + b*exp(d*x+f) + c*exp(g*y+h)
z = 1.0 / z
    Reciprocal Transform Simplified Cubic Exponential 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 Transform Simplified Quadratic Exponential 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 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 Quadratic Exponential 3D   z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2 + g*exp(x)*exp(y)
    Linear Exponential 3D   z = a + b*exp(x) + c*exp(y)
    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 Quadratic Exponential 3D   z = a + b*exp(x) + c*exp(y) + d*exp(x)2 + f*exp(y)2
    Transform Full Cubic Exponential 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
    Transform Full Quadratic Exponential 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)
    Transform Linear Exponential 3D   z = a + b*exp(d*x+f) + c*exp(g*y+h)
    Transform Simplified Cubic Exponential 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
    Transform Simplified Quadratic Exponential 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
     
     


3D Logarithmic

    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 / (m * 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 / (h * exp(xy))
    Linear Logarithmic With Exponential Decay 3D  
z = a + b*ln(x) + c*ln(y)
z = z / (d * 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 / (i * 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 / (g * exp(xy))
    Transform Full Cubic Logarithmic 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 / (r * exp(xy))
    Transform Full Quadratic Logarithmic 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 / (m * exp(xy))
    Transform Linear Logarithmic With Exponential Decay 3D  
z = a + b*ln(d*x+f) + c*ln(g*y+h)
z = z / (i * exp(xy))
    Transform Simplified Cubic Logarithmic 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 / (n * exp(xy))
    Transform Simplified Quadratic Logarithmic 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 / (k * 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 * (m * 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 * (h * exp(xy))
    Linear Logarithmic With Exponential Growth 3D  
z = a + b*ln(x) + c*ln(y)
z = z * (d * 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 * (i * 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 * (g * exp(xy))
    Transform Full Cubic Logarithmic 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 * (r * exp(xy))
    Transform Full Quadratic Logarithmic 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 * (m * exp(xy))
    Transform Linear Logarithmic With Exponential Growth 3D  
z = a + b*ln(d*x+f) + c*ln(g*y+h)
z = z * (i * exp(xy))
    Transform Simplified Cubic Logarithmic 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 * (n * exp(xy))
    Transform Simplified Quadratic Logarithmic 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 * (k * 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 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 Linear Logarithmic 3D  
z = a + b*ln(x) + c*ln(y)
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 Quadratic Logarithmic 3D  
z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2
z = xy / z
    Inverse Transform Full Cubic Logarithmic 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 Transform Full Quadratic Logarithmic 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 Transform Linear Logarithmic 3D  
z = a + b*ln(d*x+f) + c*ln(g*y+h)
z = xy / z
    Inverse Transform Simplified Cubic Logarithmic 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 Transform Simplified Quadratic Logarithmic 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 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 / (m * 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 / (h * xy)
    Linear Logarithmic With Linear Decay 3D  
z = a + b*ln(x) + c*ln(y)
z = z / (d * 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 / (i * 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 / (g * xy)
    Transform Full Cubic Logarithmic 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 / (r * xy)
    Transform Full Quadratic Logarithmic 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 / (m * xy)
    Transform Linear Logarithmic With Linear Decay 3D  
z = a + b*ln(d*x+f) + c*ln(g*y+h)
z = z / (i * xy)
    Transform Simplified Cubic Logarithmic 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 / (n * xy)
    Transform Simplified Quadratic Logarithmic 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 / (k * xy)
     
     
    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 * (m * xy)
    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 * (h * xy)
    Linear Logarithmic With Linear Growth 3D  
z = a + b*ln(x) + c*ln(y)
z = z * (d * xy)
    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 * (i * xy)
    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 * (g * xy)
    Transform Full Cubic Logarithmic 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 * (r * xy)
    Transform Full Quadratic Logarithmic 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 * (m * xy)
    Transform Linear Logarithmic With Linear Growth 3D  
z = a + b*ln(d*x+f) + c*ln(g*y+h)
z = z * (i * xy)
    Transform Simplified Cubic Logarithmic 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 * (n * xy)
    Transform Simplified Quadratic Logarithmic 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 * (k * xy)
     
     
    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 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 Linear Logarithmic 3D  
z = a + b*ln(x) + c*ln(y)
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 Quadratic Logarithmic 3D  
z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2
z = 1.0 / z
    Reciprocal Transform Full Cubic Logarithmic 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 Transform Full Quadratic Logarithmic 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 Transform Linear Logarithmic 3D  
z = a + b*ln(d*x+f) + c*ln(g*y+h)
z = 1.0 / z
    Reciprocal Transform Simplified Cubic Logarithmic 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 Transform Simplified Quadratic Logarithmic 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
     
     
    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 Quadratic Logarithmic 3D   z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2 + g*ln(x)*ln(y)
    Linear Logarithmic 3D   z = a + b*ln(x) + c*ln(y)
    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 Quadratic Logarithmic 3D   z = a + b*ln(x) + c*ln(y) + d*ln(x)2 + f*ln(y)2
    Transform Full Cubic Logarithmic 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
    Transform Full Quadratic Logarithmic 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)
    Transform Linear Logarithmic 3D   z = a + b*ln(d*x+f) + c*ln(g*y+h)
    Transform Simplified Cubic Logarithmic 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
    Transform Simplified Quadratic Logarithmic 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
     
     


3D Miscellaneous

    Gary Cler's Custom Equation Transform With Exponential Decay And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z / exp(xy) + Offset
    Gaussian Curvature Of Paraboloid Scaled With Exponential Decay And Offset 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / exp(xy) + Offset
    Gaussian Curvature Of Paraboloid With Exponential Decay And Offset 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / (b * exp(xy)) + Offset
    Gaussian Curvature Of Richmond's Minimal Surface With Exponential Decay And Offset 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z / exp(xy) + Offset
    Gaussian Curvature Of Whitney's Umbrella A With Exponential Decay And Offset 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z / (b * exp(xy)) + Offset
    Gaussian Curvature Of Whitney's Umbrella B With Exponential Decay And Offset 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z / (b * exp(xy)) + Offset
    Liping Zheng's core loss coefficients With Exponential Decay And Offset 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z / (d * exp(xy)) + Offset
    Mean Curvature Of Paraboloid Scaled With Exponential Decay And Offset 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / exp(xy) + Offset
    Mean Curvature Of Paraboloid With Exponential Decay And Offset 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / (b * exp(xy)) + Offset
    Mean Curvature Of Whitney's Umbrella A With Exponential Decay And Offset 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z / (c * exp(xy)) + Offset
    Mean Curvature Of Whitney's Umbrella B With Exponential Decay And Offset 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z / (c * exp(xy)) + Offset
    Menn's Surface A With Exponential Decay And Offset 3D  
z = ax4 + bx2y - cy2
z = z / (d * exp(xy)) + Offset
    Menn's Surface B With Exponential Decay And Offset 3D  
z = ay4 + by2x - cx2
z = z / (d * exp(xy)) + Offset
    Monkey Saddle A With Exponential Decay And Offset 3D  
z = ax3 - bxy2
z = z / (c * exp(xy)) + Offset
    Monkey Saddle B With Exponential Decay And Offset 3D  
z = ay3 - byx2
z = z / (c * exp(xy)) + Offset
    Monkey Saddle Transform A With Exponential Decay And Offset 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z / (h * exp(xy)) + Offset
    Monkey Saddle Transform B With Exponential Decay And Offset 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z / (h * exp(xy)) + Offset
    Paraboloid Transform With Exponential Decay And Offset 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z / exp(xy) + Offset
    Paraboloid With Exponential Decay And Offset 3D  
z = a * (x2 + y2)
z = z / exp(xy) + Offset
    Paschen's Law for Breakdown Field Strength With Exponential Decay And Offset 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown / (c * exp(xy)) + Offset
    Paschen's Law for Breakdown Voltage With Exponential Decay And Offset 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown / exp(xy) + Offset
    Rex Kelfkens' Custom Equation Transform With Exponential Decay And Offset 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z / (i * exp(xy)) + Offset
    Rex Kelfkens' Custom Equation With Exponential Decay And Offset 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z / (d * exp(xy)) + Offset
     
     
    Gary Cler's Custom Equation Transform With Exponential Decay 3D  
z = a * (dx + f)b * (gy + h)c
z = z / exp(xy)
    Gaussian Curvature Of Paraboloid Scaled With Exponential Decay 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / exp(xy)
    Gaussian Curvature Of Paraboloid With Exponential Decay 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / (b * exp(xy))
    Gaussian Curvature Of Richmond's Minimal Surface With Exponential Decay 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z / exp(xy)
    Gaussian Curvature Of Whitney's Umbrella A With Exponential Decay 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z / (b * exp(xy))
    Gaussian Curvature Of Whitney's Umbrella B With Exponential Decay 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z / (b * exp(xy))
    Liping Zheng's core loss coefficients With Exponential Decay 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z / (d * exp(xy))
    Mean Curvature Of Paraboloid Scaled With Exponential Decay 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / exp(xy)
    Mean Curvature Of Paraboloid With Exponential Decay 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / (b * exp(xy))
    Mean Curvature Of Whitney's Umbrella A With Exponential Decay 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z / (c * exp(xy))
    Mean Curvature Of Whitney's Umbrella B With Exponential Decay 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z / (c * exp(xy))
    Menn's Surface A With Exponential Decay 3D  
z = ax4 + bx2y - cy2
z = z / (d * exp(xy))
    Menn's Surface B With Exponential Decay 3D  
z = ay4 + by2x - cx2
z = z / (d * exp(xy))
    Monkey Saddle A With Exponential Decay 3D  
z = ax3 - bxy2
z = z / (c * exp(xy))
    Monkey Saddle B With Exponential Decay 3D  
z = ay3 - byx2
z = z / (c * exp(xy))
    Monkey Saddle Transform A With Exponential Decay 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z / (h * exp(xy))
    Monkey Saddle Transform B With Exponential Decay 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z / (h * exp(xy))
    Paraboloid Transform With Exponential Decay 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z / exp(xy)
    Paraboloid With Exponential Decay 3D  
z = a * (x2 + y2)
z = z / exp(xy)
    Paschen's Law for Breakdown Field Strength With Exponential Decay 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown / (c * exp(xy))
    Paschen's Law for Breakdown Voltage With Exponential Decay 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown / exp(xy)
    Rex Kelfkens' Custom Equation Transform With Exponential Decay 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z / (i * exp(xy))
    Rex Kelfkens' Custom Equation With Exponential Decay 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z / (d * exp(xy))
     
     
    Gary Cler's Custom Equation Transform With Exponential Growth And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z * exp(xy) + Offset
    Gaussian Curvature Of Paraboloid Scaled With Exponential Growth And Offset 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * exp(xy) + Offset
    Gaussian Curvature Of Paraboloid With Exponential Growth And Offset 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * (b * exp(xy)) + Offset
    Gaussian Curvature Of Richmond's Minimal Surface With Exponential Growth And Offset 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z * exp(xy) + Offset
    Gaussian Curvature Of Whitney's Umbrella A With Exponential Growth And Offset 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z * (b * exp(xy)) + Offset
    Gaussian Curvature Of Whitney's Umbrella B With Exponential Growth And Offset 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z * (b * exp(xy)) + Offset
    Liping Zheng's core loss coefficients With Exponential Growth And Offset 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z * (d * exp(xy)) + Offset
    Mean Curvature Of Paraboloid Scaled With Exponential Growth And Offset 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * exp(xy) + Offset
    Mean Curvature Of Paraboloid With Exponential Growth And Offset 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * (b * exp(xy)) + Offset
    Mean Curvature Of Whitney's Umbrella A With Exponential Growth And Offset 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z * (c * exp(xy)) + Offset
    Mean Curvature Of Whitney's Umbrella B With Exponential Growth And Offset 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z * (c * exp(xy)) + Offset
    Menn's Surface A With Exponential Growth And Offset 3D  
z = ax4 + bx2y - cy2
z = z * (d * exp(xy)) + Offset
    Menn's Surface B With Exponential Growth And Offset 3D  
z = ay4 + by2x - cx2
z = z * (d * exp(xy)) + Offset
    Monkey Saddle A With Exponential Growth And Offset 3D  
z = ax3 - bxy2
z = z * (c * exp(xy)) + Offset
    Monkey Saddle B With Exponential Growth And Offset 3D  
z = ay3 - byx2
z = z * (c * exp(xy)) + Offset
    Monkey Saddle Transform A With Exponential Growth And Offset 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z * (h * exp(xy)) + Offset
    Monkey Saddle Transform B With Exponential Growth And Offset 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z * (h * exp(xy)) + Offset
    Paraboloid Transform With Exponential Growth And Offset 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z * exp(xy) + Offset
    Paraboloid With Exponential Growth And Offset 3D  
z = a * (x2 + y2)
z = z * exp(xy) + Offset
    Paschen's Law for Breakdown Field Strength With Exponential Growth And Offset 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown * (c * exp(xy)) + Offset
    Paschen's Law for Breakdown Voltage With Exponential Growth And Offset 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown * exp(xy) + Offset
    Rex Kelfkens' Custom Equation Transform With Exponential Growth And Offset 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z * (i * exp(xy)) + Offset
    Rex Kelfkens' Custom Equation With Exponential Growth And Offset 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z * (d * exp(xy)) + Offset
     
     
    Gary Cler's Custom Equation Transform With Exponential Growth 3D  
z = a * (dx + f)b * (gy + h)c
z = z * exp(xy)
    Gaussian Curvature Of Paraboloid Scaled With Exponential Growth 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * exp(xy)
    Gaussian Curvature Of Paraboloid With Exponential Growth 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * (b * exp(xy))
    Gaussian Curvature Of Richmond's Minimal Surface With Exponential Growth 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z * exp(xy)
    Gaussian Curvature Of Whitney's Umbrella A With Exponential Growth 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z * (b * exp(xy))
    Gaussian Curvature Of Whitney's Umbrella B With Exponential Growth 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z * (b * exp(xy))
    Liping Zheng's core loss coefficients With Exponential Growth 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z * (d * exp(xy))
    Mean Curvature Of Paraboloid Scaled With Exponential Growth 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * exp(xy)
    Mean Curvature Of Paraboloid With Exponential Growth 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * (b * exp(xy))
    Mean Curvature Of Whitney's Umbrella A With Exponential Growth 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z * (c * exp(xy))
    Mean Curvature Of Whitney's Umbrella B With Exponential Growth 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z * (c * exp(xy))
    Menn's Surface A With Exponential Growth 3D  
z = ax4 + bx2y - cy2
z = z * (d * exp(xy))
    Menn's Surface B With Exponential Growth 3D  
z = ay4 + by2x - cx2
z = z * (d * exp(xy))
    Monkey Saddle A With Exponential Growth 3D  
z = ax3 - bxy2
z = z * (c * exp(xy))
    Monkey Saddle B With Exponential Growth 3D  
z = ay3 - byx2
z = z * (c * exp(xy))
    Monkey Saddle Transform A With Exponential Growth 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z * (h * exp(xy))
    Monkey Saddle Transform B With Exponential Growth 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z * (h * exp(xy))
    Paraboloid Transform With Exponential Growth 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z * exp(xy)
    Paraboloid With Exponential Growth 3D  
z = a * (x2 + y2)
z = z * exp(xy)
    Paschen's Law for Breakdown Field Strength With Exponential Growth 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown * (c * exp(xy))
    Paschen's Law for Breakdown Voltage With Exponential Growth 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown * exp(xy)
    Rex Kelfkens' Custom Equation Transform With Exponential Growth 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z * (i * exp(xy))
    Rex Kelfkens' Custom Equation With Exponential Growth 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z * (d * exp(xy))
     
     
    Inverse Gary Cler's Custom Equation Transform 3D  
z = a * (dx + f)b * (gy + h)c
z = xy / z
    Inverse Gaussian Curvature Of Paraboloid 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = xy / z
    Inverse Gaussian Curvature Of Paraboloid Scaled 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = xy / z
    Inverse Gaussian Curvature Of Richmond's Minimal Surface 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = xy / z
    Inverse Gaussian Curvature Of Whitney's Umbrella A 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = xy / z
    Inverse Gaussian Curvature Of Whitney's Umbrella B 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = xy / z
    Inverse Liping Zheng's core loss coefficients 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = xy / z
    Inverse Mean Curvature Of Paraboloid 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = xy / z
    Inverse Mean Curvature Of Paraboloid Scaled 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = xy / z
    Inverse Mean Curvature Of Whitney's Umbrella A 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = xy / z
    Inverse Mean Curvature Of Whitney's Umbrella B 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = xy / z
    Inverse Menn's Surface A 3D  
z = ax4 + bx2y - cy2
z = xy / z
    Inverse Menn's Surface B 3D  
z = ay4 + by2x - cx2
z = xy / z
    Inverse Monkey Saddle A 3D  
z = ax3 - bxy2
z = xy / z
    Inverse Monkey Saddle B 3D  
z = ay3 - byx2
z = xy / z
    Inverse Monkey Saddle Transform A 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = xy / z
    Inverse Monkey Saddle Transform B 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = xy / z
    Inverse Paraboloid 3D  
z = a * (x2 + y2)
z = xy / z
    Inverse Paraboloid Transform 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = xy / z
    Inverse Paschen's Law for Breakdown Field Strength 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = xy / Ebreakdown
    Inverse Paschen's Law for Breakdown Voltage 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = xy / Vbreakdown
    Inverse Rex Kelfkens' Custom Equation 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = xy / z
    Inverse Rex Kelfkens' Custom Equation Transform 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = xy / z
     
     
    Inverse Gary Cler's Custom Equation Transform With Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = xy / (z + Offset
    Inverse Gaussian Curvature Of Paraboloid Scaled With Offset 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = xy / (z + Offset
    Inverse Gaussian Curvature Of Paraboloid With Offset 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = xy / (z + Offset
    Inverse Gaussian Curvature Of Richmond's Minimal Surface With Offset 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = xy / (z + Offset
    Inverse Gaussian Curvature Of Whitney's Umbrella A With Offset 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = xy / (z + Offset
    Inverse Gaussian Curvature Of Whitney's Umbrella B With Offset 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = xy / (z + Offset
    Inverse Liping Zheng's core loss coefficients With Offset 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = xy / (z + Offset
    Inverse Mean Curvature Of Paraboloid Scaled With Offset 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = xy / (z + Offset
    Inverse Mean Curvature Of Paraboloid With Offset 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = xy / (z + Offset
    Inverse Mean Curvature Of Whitney's Umbrella A With Offset 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = xy / (z + Offset
    Inverse Mean Curvature Of Whitney's Umbrella B With Offset 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = xy / (z + Offset
    Inverse Menn's Surface A With Offset 3D  
z = ax4 + bx2y - cy2
z = xy / (z + Offset
    Inverse Menn's Surface B With Offset 3D  
z = ay4 + by2x - cx2
z = xy / (z + Offset
    Inverse Monkey Saddle A With Offset 3D  
z = ax3 - bxy2
z = xy / (z + Offset
    Inverse Monkey Saddle B With Offset 3D  
z = ay3 - byx2
z = xy / (z + Offset
    Inverse Monkey Saddle Transform A With Offset 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = xy / (z + Offset
    Inverse Monkey Saddle Transform B With Offset 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = xy / (z + Offset
    Inverse Paraboloid Transform With Offset 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = xy / (z + Offset
    Inverse Paraboloid With Offset 3D  
z = a * (x2 + y2)
z = xy / (z + Offset
    Inverse Paschen's Law for Breakdown Field Strength With Offset 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = xy / (Ebreakdown + Offset
    Inverse Paschen's Law for Breakdown Voltage With Offset 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = xy / (Vbreakdown + Offset
    Inverse Rex Kelfkens' Custom Equation Transform With Offset 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = xy / (z + Offset
    Inverse Rex Kelfkens' Custom Equation With Offset 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = xy / (z + Offset
     
     
    Gary Cler's Custom Equation Transform With Linear Decay And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z / xy + Offset
    Gaussian Curvature Of Paraboloid Scaled With Linear Decay And Offset 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / xy + Offset
    Gaussian Curvature Of Paraboloid With Linear Decay And Offset 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / (b * xy) + Offset
    Gaussian Curvature Of Richmond's Minimal Surface With Linear Decay And Offset 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z / xy + Offset
    Gaussian Curvature Of Whitney's Umbrella A With Linear Decay And Offset 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z / (b * xy) + Offset
    Gaussian Curvature Of Whitney's Umbrella B With Linear Decay And Offset 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z / (b * xy) + Offset
    Liping Zheng's core loss coefficients With Linear Decay And Offset 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z / (d * xy) + Offset
    Mean Curvature Of Paraboloid Scaled With Linear Decay And Offset 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / xy + Offset
    Mean Curvature Of Paraboloid With Linear Decay And Offset 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / (b * xy) + Offset
    Mean Curvature Of Whitney's Umbrella A With Linear Decay And Offset 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z / (c * xy) + Offset
    Mean Curvature Of Whitney's Umbrella B With Linear Decay And Offset 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z / (c * xy) + Offset
    Menn's Surface A With Linear Decay And Offset 3D  
z = ax4 + bx2y - cy2
z = z / (d * xy) + Offset
    Menn's Surface B With Linear Decay And Offset 3D  
z = ay4 + by2x - cx2
z = z / (d * xy) + Offset
    Monkey Saddle A With Linear Decay And Offset 3D  
z = ax3 - bxy2
z = z / (c * xy) + Offset
    Monkey Saddle B With Linear Decay And Offset 3D  
z = ay3 - byx2
z = z / (c * xy) + Offset
    Monkey Saddle Transform A With Linear Decay And Offset 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z / (h * xy) + Offset
    Monkey Saddle Transform B With Linear Decay And Offset 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z / (h * xy) + Offset
    Paraboloid Transform With Linear Decay And Offset 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z / xy + Offset
    Paraboloid With Linear Decay And Offset 3D  
z = a * (x2 + y2)
z = z / xy + Offset
    Paschen's Law for Breakdown Field Strength With Linear Decay And Offset 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown / (c * xy) + Offset
    Paschen's Law for Breakdown Voltage With Linear Decay And Offset 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown / xy + Offset
    Rex Kelfkens' Custom Equation Transform With Linear Decay And Offset 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z / (i * xy) + Offset
    Rex Kelfkens' Custom Equation With Linear Decay And Offset 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z / (d * xy) + Offset
     
     
    Gary Cler's Custom Equation Transform With Linear Decay 3D  
z = a * (dx + f)b * (gy + h)c
z = z / xy
    Gaussian Curvature Of Paraboloid Scaled With Linear Decay 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / xy
    Gaussian Curvature Of Paraboloid With Linear Decay 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z / (b * xy)
    Gaussian Curvature Of Richmond's Minimal Surface With Linear Decay 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z / xy
    Gaussian Curvature Of Whitney's Umbrella A With Linear Decay 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z / (b * xy)
    Gaussian Curvature Of Whitney's Umbrella B With Linear Decay 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z / (b * xy)
    Liping Zheng's core loss coefficients With Linear Decay 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z / (d * xy)
    Mean Curvature Of Paraboloid Scaled With Linear Decay 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / xy
    Mean Curvature Of Paraboloid With Linear Decay 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z / (b * xy)
    Mean Curvature Of Whitney's Umbrella A With Linear Decay 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z / (c * xy)
    Mean Curvature Of Whitney's Umbrella B With Linear Decay 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z / (c * xy)
    Menn's Surface A With Linear Decay 3D  
z = ax4 + bx2y - cy2
z = z / (d * xy)
    Menn's Surface B With Linear Decay 3D  
z = ay4 + by2x - cx2
z = z / (d * xy)
    Monkey Saddle A With Linear Decay 3D  
z = ax3 - bxy2
z = z / (c * xy)
    Monkey Saddle B With Linear Decay 3D  
z = ay3 - byx2
z = z / (c * xy)
    Monkey Saddle Transform A With Linear Decay 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z / (h * xy)
    Monkey Saddle Transform B With Linear Decay 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z / (h * xy)
    Paraboloid Transform With Linear Decay 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z / xy
    Paraboloid With Linear Decay 3D  
z = a * (x2 + y2)
z = z / xy
    Paschen's Law for Breakdown Field Strength With Linear Decay 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown / (c * xy)
    Paschen's Law for Breakdown Voltage With Linear Decay 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown / xy
    Rex Kelfkens' Custom Equation Transform With Linear Decay 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z / (i * xy)
    Rex Kelfkens' Custom Equation With Linear Decay 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z / (d * xy)
     
     
    Gary Cler's Custom Equation Transform With Linear Growth And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z * xy + Offset
    Gaussian Curvature Of Paraboloid Scaled With Linear Growth And Offset 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * xy + Offset
    Gaussian Curvature Of Paraboloid With Linear Growth And Offset 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * (b * xy) + Offset
    Gaussian Curvature Of Richmond's Minimal Surface With Linear Growth And Offset 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z * xy + Offset
    Gaussian Curvature Of Whitney's Umbrella A With Linear Growth And Offset 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z * (b * xy) + Offset
    Gaussian Curvature Of Whitney's Umbrella B With Linear Growth And Offset 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z * (b * xy) + Offset
    Liping Zheng's core loss coefficients With Linear Growth And Offset 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z * (d * xy) + Offset
    Mean Curvature Of Paraboloid Scaled With Linear Growth And Offset 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * xy + Offset
    Mean Curvature Of Paraboloid With Linear Growth And Offset 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * (b * xy) + Offset
    Mean Curvature Of Whitney's Umbrella A With Linear Growth And Offset 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z * (c * xy) + Offset
    Mean Curvature Of Whitney's Umbrella B With Linear Growth And Offset 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z * (c * xy) + Offset
    Menn's Surface A With Linear Growth And Offset 3D  
z = ax4 + bx2y - cy2
z = z * (d * xy) + Offset
    Menn's Surface B With Linear Growth And Offset 3D  
z = ay4 + by2x - cx2
z = z * (d * xy) + Offset
    Monkey Saddle A With Linear Growth And Offset 3D  
z = ax3 - bxy2
z = z * (c * xy) + Offset
    Monkey Saddle B With Linear Growth And Offset 3D  
z = ay3 - byx2
z = z * (c * xy) + Offset
    Monkey Saddle Transform A With Linear Growth And Offset 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z * (h * xy) + Offset
    Monkey Saddle Transform B With Linear Growth And Offset 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z * (h * xy) + Offset
    Paraboloid Transform With Linear Growth And Offset 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z * xy + Offset
    Paraboloid With Linear Growth And Offset 3D  
z = a * (x2 + y2)
z = z * xy + Offset
    Paschen's Law for Breakdown Field Strength With Linear Growth And Offset 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown * (c * xy) + Offset
    Paschen's Law for Breakdown Voltage With Linear Growth And Offset 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown * xy + Offset
    Rex Kelfkens' Custom Equation Transform With Linear Growth And Offset 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z * (i * xy) + Offset
    Rex Kelfkens' Custom Equation With Linear Growth And Offset 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z * (d * xy) + Offset
     
     
    Gary Cler's Custom Equation Transform With Linear Growth 3D  
z = a * (dx + f)b * (gy + h)c
z = z * xy
    Gaussian Curvature Of Paraboloid Scaled With Linear Growth 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * xy
    Gaussian Curvature Of Paraboloid With Linear Growth 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z * (b * xy)
    Gaussian Curvature Of Richmond's Minimal Surface With Linear Growth 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z * xy
    Gaussian Curvature Of Whitney's Umbrella A With Linear Growth 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z * (b * xy)
    Gaussian Curvature Of Whitney's Umbrella B With Linear Growth 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z * (b * xy)
    Liping Zheng's core loss coefficients With Linear Growth 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z * (d * xy)
    Mean Curvature Of Paraboloid Scaled With Linear Growth 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * xy
    Mean Curvature Of Paraboloid With Linear Growth 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z * (b * xy)
    Mean Curvature Of Whitney's Umbrella A With Linear Growth 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z * (c * xy)
    Mean Curvature Of Whitney's Umbrella B With Linear Growth 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z * (c * xy)
    Menn's Surface A With Linear Growth 3D  
z = ax4 + bx2y - cy2
z = z * (d * xy)
    Menn's Surface B With Linear Growth 3D  
z = ay4 + by2x - cx2
z = z * (d * xy)
    Monkey Saddle A With Linear Growth 3D  
z = ax3 - bxy2
z = z * (c * xy)
    Monkey Saddle B With Linear Growth 3D  
z = ay3 - byx2
z = z * (c * xy)
    Monkey Saddle Transform A With Linear Growth 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = z * (h * xy)
    Monkey Saddle Transform B With Linear Growth 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = z * (h * xy)
    Paraboloid Transform With Linear Growth 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = z * xy
    Paraboloid With Linear Growth 3D  
z = a * (x2 + y2)
z = z * xy
    Paschen's Law for Breakdown Field Strength With Linear Growth 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown * (c * xy)
    Paschen's Law for Breakdown Voltage With Linear Growth 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown * xy
    Rex Kelfkens' Custom Equation Transform With Linear Growth 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = z * (i * xy)
    Rex Kelfkens' Custom Equation With Linear Growth 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z * (d * xy)
     
     
    Reciprocal Gary Cler's Custom Equation Transform 3D  
z = a * (dx + f)b * (gy + h)c
z = 1.0 / z
    Reciprocal Gaussian Curvature Of Paraboloid 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = 1.0 / z
    Reciprocal Gaussian Curvature Of Paraboloid Scaled 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = 1.0 / z
    Reciprocal Gaussian Curvature Of Richmond's Minimal Surface 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = 1.0 / z
    Reciprocal Gaussian Curvature Of Whitney's Umbrella A 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = 1.0 / z
    Reciprocal Gaussian Curvature Of Whitney's Umbrella B 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = 1.0 / z
    Reciprocal Liping Zheng's core loss coefficients 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = 1.0 / z
    Reciprocal Mean Curvature Of Paraboloid 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = 1.0 / z
    Reciprocal Mean Curvature Of Paraboloid Scaled 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = 1.0 / z
    Reciprocal Mean Curvature Of Whitney's Umbrella A 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = 1.0 / z
    Reciprocal Mean Curvature Of Whitney's Umbrella B 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = 1.0 / z
    Reciprocal Menn's Surface A 3D  
z = ax4 + bx2y - cy2
z = 1.0 / z
    Reciprocal Menn's Surface B 3D  
z = ay4 + by2x - cx2
z = 1.0 / z
    Reciprocal Monkey Saddle A 3D  
z = ax3 - bxy2
z = 1.0 / z
    Reciprocal Monkey Saddle B 3D  
z = ay3 - byx2
z = 1.0 / z
    Reciprocal Monkey Saddle Transform A 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = 1.0 / z
    Reciprocal Monkey Saddle Transform B 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = 1.0 / z
    Reciprocal Paraboloid 3D  
z = a * (x2 + y2)
z = 1.0 / z
    Reciprocal Paraboloid Transform 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = 1.0 / z
    Reciprocal Paschen's Law for Breakdown Field Strength 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = 1.0 / Ebreakdown
    Reciprocal Paschen's Law for Breakdown Voltage 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = 1.0 / Vbreakdown
    Reciprocal Rex Kelfkens' Custom Equation 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = 1.0 / z
    Reciprocal Rex Kelfkens' Custom Equation Transform 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = 1.0 / z
     
     
    Reciprocal Gary Cler's Custom Equation Transform With Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = 1.0 / z + Offset
    Reciprocal Gaussian Curvature Of Paraboloid Scaled With Offset 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = 1.0 / z + Offset
    Reciprocal Gaussian Curvature Of Paraboloid With Offset 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = 1.0 / z + Offset
    Reciprocal Gaussian Curvature Of Richmond's Minimal Surface With Offset 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = 1.0 / z + Offset
    Reciprocal Gaussian Curvature Of Whitney's Umbrella A With Offset 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = 1.0 / z + Offset
    Reciprocal Gaussian Curvature Of Whitney's Umbrella B With Offset 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = 1.0 / z + Offset
    Reciprocal Liping Zheng's core loss coefficients With Offset 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = 1.0 / z + Offset
    Reciprocal Mean Curvature Of Paraboloid Scaled With Offset 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = 1.0 / z + Offset
    Reciprocal Mean Curvature Of Paraboloid With Offset 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = 1.0 / z + Offset
    Reciprocal Mean Curvature Of Whitney's Umbrella A With Offset 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = 1.0 / z + Offset
    Reciprocal Mean Curvature Of Whitney's Umbrella B With Offset 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = 1.0 / z + Offset
    Reciprocal Menn's Surface A With Offset 3D  
z = ax4 + bx2y - cy2
z = 1.0 / z + Offset
    Reciprocal Menn's Surface B With Offset 3D  
z = ay4 + by2x - cx2
z = 1.0 / z + Offset
    Reciprocal Monkey Saddle A With Offset 3D  
z = ax3 - bxy2
z = 1.0 / z + Offset
    Reciprocal Monkey Saddle B With Offset 3D  
z = ay3 - byx2
z = 1.0 / z + Offset
    Reciprocal Monkey Saddle Transform A With Offset 3D  
z = a(cx + d)3 - b(cx + d)(fy + g)2
z = 1.0 / z + Offset
    Reciprocal Monkey Saddle Transform B With Offset 3D  
z = a(cy + d)3 - b(cy + d)(fx + g)2
z = 1.0 / z + Offset
    Reciprocal Paraboloid Transform With Offset 3D  
z = a * ((bx + c)2 + (dy + f)2)
z = 1.0 / z + Offset
    Reciprocal Paraboloid With Offset 3D  
z = a * (x2 + y2)
z = 1.0 / z + Offset
    Reciprocal Paschen's Law for Breakdown Field Strength With Offset 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = 1.0 / Ebreakdown + Offset
    Reciprocal Paschen's Law for Breakdown Voltage With Offset 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = 1.0 / Vbreakdown + Offset
    Reciprocal Rex Kelfkens' Custom Equation Transform With Offset 3D  
z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
z = 1.0 / z + Offset
    Reciprocal Rex Kelfkens' Custom Equation With Offset 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = 1.0 / z + Offset
     
     
    Gary Cler's Custom Equation Transform 3D   z = a * (dx + f)b * (gy + h)c
    Gaussian Curvature Of Paraboloid 3D   z = 4a2 / (1 + 4a2 * (x2 + y2))2
    Gaussian Curvature Of Paraboloid Scaled 3D   z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
    Gaussian Curvature Of Richmond's Minimal Surface 3D   z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
    Gaussian Curvature Of Whitney's Umbrella A 3D   z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
    Gaussian Curvature Of Whitney's Umbrella B 3D   z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
    Liping Zheng's core loss coefficients 3D   z = ax2y + bx2y2 + cx1.5y1.5
    Mean Curvature Of Paraboloid 3D   z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
    Mean Curvature Of Paraboloid Scaled 3D   z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
    Mean Curvature Of Whitney's Umbrella A 3D   z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
    Mean Curvature Of Whitney's Umbrella B 3D   z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
    Menn's Surface A 3D   z = ax4 + bx2y - cy2
    Menn's Surface B 3D   z = ay4 + by2x - cx2
    Monkey Saddle A 3D   z = ax3 - bxy2
    Monkey Saddle B 3D   z = ay3 - byx2
    Monkey Saddle Transform A 3D   z = a(cx + d)3 - b(cx + d)(fy + g)2
    Monkey Saddle Transform B 3D   z = a(cy + d)3 - b(cy + d)(fx + g)2
    Paraboloid 3D   z = a * (x2 + y2)
    Paraboloid Transform 3D   z = a * ((bx + c)2 + (dy + f)2)
    Paschen's Law for Breakdown Field Strength 3D   Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
    Paschen's Law for Breakdown Voltage 3D   Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
    Rex Kelfkens' Custom Equation 3D   z = exp(A+B*ln(x)+C*ln(y))
    Rex Kelfkens' Custom Equation Transform 3D   z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset))
     
     
    Gary Cler's Custom Equation Transform With Offset 3D   z = a * (dx + f)b * (gy + h)c + Offset
    Gaussian Curvature Of Paraboloid Scaled With Offset 3D   z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2 + Offset
    Gaussian Curvature Of Paraboloid With Offset 3D   z = 4a2 / (1 + 4a2 * (x2 + y2))2 + Offset
    Gaussian Curvature Of Richmond's Minimal Surface With Offset 3D   z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4 + Offset
    Gaussian Curvature Of Whitney's Umbrella A With Offset 3D   z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2 + Offset
    Gaussian Curvature Of Whitney's Umbrella B With Offset 3D   z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2 + Offset
    Liping Zheng's core loss coefficients With Offset 3D   z = ax2y + bx2y2 + cx1.5y1.5 + Offset
    Mean Curvature Of Paraboloid Scaled With Offset 3D   z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5 + Offset
    Mean Curvature Of Paraboloid With Offset 3D   z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5 + Offset
    Mean Curvature Of Whitney's Umbrella A With Offset 3D   z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5 + Offset
    Mean Curvature Of Whitney's Umbrella B With Offset 3D   z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5 + Offset
    Menn's Surface A With Offset 3D   z = ax4 + bx2y - cy2 + Offset
    Menn's Surface B With Offset 3D   z = ay4 + by2x - cx2 + Offset
    Monkey Saddle A With Offset 3D   z = ax3 - bxy2 + Offset
    Monkey Saddle B With Offset 3D   z = ay3 - byx2 + Offset
    Monkey Saddle Transform A With Offset 3D   z = a(cx + d)3 - b(cx + d)(fy + g)2 + Offset
    Monkey Saddle Transform B With Offset 3D   z = a(cy + d)3 - b(cy + d)(fx + g)2 + Offset
    Paraboloid Transform With Offset 3D   z = a * ((bx + c)2 + (dy + f)2) + Offset
    Paraboloid With Offset 3D   z = a * (x2 + y2) + Offset
    Paschen's Law for Breakdown Field Strength With Offset 3D   Ebreakdown = pressure * (a / (ln(pressure * distance) + b)) + Offset
    Paschen's Law for Breakdown Voltage With Offset 3D   Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b) + Offset
    Rex Kelfkens' Custom Equation Transform With Offset 3D   z = exp(A+B*ln(x * xscale + xoffset)+C*ln(y * yscale + yoffset)) + Offset
    Rex Kelfkens' Custom Equation With Offset 3D   z = exp(A+B*ln(x)+C*ln(y)) + Offset
     
     
    Gaussian Curvature Of Paraboloid Plus Plane 3D  
z = 4a2 / (1 + 4a2 * (x2 + y2))2
z = z + (b * x) + (c * y) + d
    Gaussian Curvature Of Paraboloid Scaled Plus Plane 3D  
z = Scale * 4a2 / (1 + 4a2 * (x2 + y2))2
z = z + (c * x) + (d * y) + f
    Gaussian Curvature Of Richmond's Minimal Surface Plus Plane 3D  
z = -1.0 * a * (x2 + y2)3 / (b + (x2 + y2)2)4
z = z + (c * x) + (d * y) + f
    Gaussian Curvature Of Whitney's Umbrella A Plus Plane 3D  
z = -1.0 * a * y2 / (x2 + a * (y2 + y4))2
z = z + (b * x) + (c * y) + d
    Gaussian Curvature Of Whitney's Umbrella B Plus Plane 3D  
z = -1.0 * a * x2 / (y2 + a * (x2 + x4))2
z = z + (b * x) + (c * y) + d
    Liping Zheng's core loss coefficients Plus Plane 3D  
z = ax2y + bx2y2 + cx1.5y1.5
z = z + (d * x) + (f * y) + g
    Mean Curvature Of Paraboloid Plus Plane 3D  
z = 2 * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z + (b * x) + (c * y) + d
    Mean Curvature Of Paraboloid Scaled Plus Plane 3D  
z = Scale * (a + 2a3 * (x2 + y2)) / (1 + 4a2 * (x2 + y2))1.5
z = z + (c * x) + (d * y) + f
    Mean Curvature Of Whitney's Umbrella A Plus Plane 3D  
z = -1.0 * x * (a + b * y2) / (x2 + a * (y2 + y4))1.5
z = z + (c * x) + (d * y) + f
    Mean Curvature Of Whitney's Umbrella B Plus Plane 3D  
z = -1.0 * y * (a + b * x2) / (y2 + a * (x2 + x4))1.5
z = z + (c * x) + (d * y) + f
    Menn's Surface A Plus Plane 3D  
z = ax4 + bx2y - cy2
z = z + (d * x) + (f * y) + g
    Menn's Surface B Plus Plane 3D  
z = ay4 + by2x - cx2
z = z + (d * x) + (f * y) + g
    Monkey Saddle A Plus Plane 3D  
z = ax3 - bxy2
z = z + (c * x) + (d * y) + f
    Monkey Saddle B Plus Plane 3D  
z = ay3 - byx2
z = z + (c * x) + (d * y) + f
    Paraboloid Plus Plane 3D  
z = a * (x2 + y2)
z = z + (b * x) + (c * y) + d
    Paschen's Law for Breakdown Field Strength Plus Plane 3D  
Ebreakdown = pressure * (a / (ln(pressure * distance) + b))
Ebreakdown = Ebreakdown + (c * x) + (d * y) + f
    Paschen's Law for Breakdown Voltage Plus Plane 3D  
Vbreakdown = a(pressure * distance) / (ln(pressure * distance) + b)
Vbreakdown = Vbreakdown + (c * x) + (d * y) + f
    Rex Kelfkens' Custom Equation Plus Plane 3D  
z = exp(A+B*ln(x)+C*ln(y))
z = z + (d * x) + (f * y) + g
     
     


3D NIST

    NIST Nelson Autolog With Exponential Decay And Offset 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z / (d * exp(xy)) + Offset   [web citation]
     
     
    NIST Nelson Autolog With Exponential Decay 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z / (d * exp(xy))   [web citation]
    NIST Nelson With Exponential Decay 3D  
log(y) = b1 - b2 * X1 * exp(-b3*X2)
log(y) = log(y) / (d * exp(xy))   [web citation]
     
     
    NIST Nelson Autolog With Exponential Growth And Offset 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z * (d * exp(xy)) + Offset   [web citation]
     
     
    NIST Nelson Autolog With Exponential Growth 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z * (d * exp(xy))   [web citation]
    NIST Nelson With Exponential Growth 3D  
log(y) = b1 - b2 * X1 * exp(-b3*X2)
log(y) = log(y) * (d * exp(xy))   [web citation]
     
     
    Inverse NIST Nelson 3D  
log(y) = b1 - b2 * X1 * exp(-b3*X2)
log(y) = xy / log(y)   [web citation]
    Inverse NIST Nelson Autolog 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = xy / z   [web citation]
     
     
    Inverse NIST Nelson Autolog With Offset 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = xy / (z + Offset   [web citation]
     
     
    NIST Nelson Autolog With Linear Decay And Offset 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z / (d * xy) + Offset   [web citation]
     
     
    NIST Nelson Autolog With Linear Decay 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z / (d * xy)   [web citation]
    NIST Nelson With Linear Decay 3D  
log(y) = b1 - b2 * X1 * exp(-b3*X2)
log(y) = log(y) / (d * xy)   [web citation]
     
     
    NIST Nelson Autolog With Linear Growth And Offset 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z * (d * xy) + Offset   [web citation]
     
     
    NIST Nelson Autolog With Linear Growth 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z * (d * xy)   [web citation]
    NIST Nelson With Linear Growth 3D  
log(y) = b1 - b2 * X1 * exp(-b3*X2)
log(y) = log(y) * (d * xy)   [web citation]
     
     
    Reciprocal NIST Nelson 3D  
log(y) = b1 - b2 * X1 * exp(-b3*X2)
log(y) = 1.0 / log(y)   [web citation]
    Reciprocal NIST Nelson Autolog 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = 1.0 / z   [web citation]
     
     
    Reciprocal NIST Nelson Autolog With Offset 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = 1.0 / z + Offset   [web citation]
     
     
    NIST Nelson 3D   log(y) = b1 - b2 * X1 * exp(-b3*X2)   [web citation]
    NIST Nelson Autolog 3D   z = exp(b1 - b2 * x * exp(-b3*y))   [web citation]
     
     
    NIST Nelson Autolog With Offset 3D   z = exp(b1 - b2 * x * exp(-b3*y)) + Offset   [web citation]
     
     
    NIST Nelson Autolog Plus Plane 3D  
z = exp(b1 - b2 * x * exp(-b3*y))
z = z + (d * x) + (f * y) + g   [web citation]
     
     


3D Optical

    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 / (g * exp(xy)) + Offset
    Sag For Asphere 0 Scaled With Exponential Decay And Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (d * exp(xy)) + Offset   [web citation]
    Sag For Asphere 0 With Exponential Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (c * exp(xy)) + Offset   [web citation]
    Sag For Asphere 1 With Exponential Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (d * exp(xy)) + Offset   [web citation]
    Sag For Asphere 2 With Exponential Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (f * exp(xy)) + Offset   [web citation]
    Sag For Asphere 3 With Exponential Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (g * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 0 With Exponential Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (h * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 1 With Exponential Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (i * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 2 With Exponential Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (j * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 3 With Exponential Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (k * exp(xy)) + Offset   [web citation]
     
     
    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 / (g * exp(xy))
    Sag For Asphere 0 Scaled With Exponential Decay 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (d * exp(xy))   [web citation]
    Sag For Asphere 0 With Exponential Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (c * exp(xy))   [web citation]
    Sag For Asphere 1 With Exponential Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (d * exp(xy))   [web citation]
    Sag For Asphere 2 With Exponential Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (f * exp(xy))   [web citation]
    Sag For Asphere 3 With Exponential Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (g * exp(xy))   [web citation]
    Transform Sag For Asphere 0 With Exponential Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (h * exp(xy))   [web citation]
    Transform Sag For Asphere 1 With Exponential Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (i * exp(xy))   [web citation]
    Transform Sag For Asphere 2 With Exponential Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (j * exp(xy))   [web citation]
    Transform Sag For Asphere 3 With Exponential Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (k * exp(xy))   [web citation]
     
     
    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 * (g * exp(xy)) + Offset
    Sag For Asphere 0 Scaled With Exponential Growth And Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (d * exp(xy)) + Offset   [web citation]
    Sag For Asphere 0 With Exponential Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (c * exp(xy)) + Offset   [web citation]
    Sag For Asphere 1 With Exponential Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (d * exp(xy)) + Offset   [web citation]
    Sag For Asphere 2 With Exponential Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (f * exp(xy)) + Offset   [web citation]
    Sag For Asphere 3 With Exponential Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (g * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 0 With Exponential Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (h * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 1 With Exponential Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (i * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 2 With Exponential Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (j * exp(xy)) + Offset   [web citation]
    Transform Sag For Asphere 3 With Exponential Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (k * exp(xy)) + Offset   [web citation]
     
     
    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 * (g * exp(xy))
    Sag For Asphere 0 Scaled With Exponential Growth 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (d * exp(xy))   [web citation]
    Sag For Asphere 0 With Exponential Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (c * exp(xy))   [web citation]
    Sag For Asphere 1 With Exponential Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (d * exp(xy))   [web citation]
    Sag For Asphere 2 With Exponential Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (f * exp(xy))   [web citation]
    Sag For Asphere 3 With Exponential Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (g * exp(xy))   [web citation]
    Transform Sag For Asphere 0 With Exponential Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (h * exp(xy))   [web citation]
    Transform Sag For Asphere 1 With Exponential Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (i * exp(xy))   [web citation]
    Transform Sag For Asphere 2 With Exponential Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (j * exp(xy))   [web citation]
    Transform Sag For Asphere 3 With Exponential Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (k * exp(xy))   [web citation]
     
     
    Inverse Sag For Asphere 0 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = xy / z   [web citation]
    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 Scaled 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = xy / z   [web citation]
    Inverse Sag For Asphere 1 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = xy / z   [web citation]
    Inverse Sag For Asphere 2 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = xy / z   [web citation]
    Inverse Sag For Asphere 3 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = xy / z   [web citation]
    Inverse Transform Sag For Asphere 0 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = xy / z   [web citation]
    Inverse Transform Sag For Asphere 1 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = xy / z   [web citation]
    Inverse Transform Sag For Asphere 2 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = xy / z   [web citation]
    Inverse Transform Sag For Asphere 3 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = xy / z   [web citation]
     
     
    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
    Inverse Sag For Asphere 0 Scaled With Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = xy / (z + Offset   [web citation]
    Inverse Sag For Asphere 0 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = xy / (z + Offset   [web citation]
    Inverse Sag For Asphere 1 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = xy / (z + Offset   [web citation]
    Inverse Sag For Asphere 2 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = xy / (z + Offset   [web citation]
    Inverse Sag For Asphere 3 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = xy / (z + Offset   [web citation]
    Inverse Transform Sag For Asphere 0 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = xy / (z + Offset   [web citation]
    Inverse Transform Sag For Asphere 1 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = xy / (z + Offset   [web citation]
    Inverse Transform Sag For Asphere 2 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = xy / (z + Offset   [web citation]
    Inverse Transform Sag For Asphere 3 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = xy / (z + Offset   [web citation]
     
     
    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 / (g * xy) + Offset
    Sag For Asphere 0 Scaled With Linear Decay And Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (d * xy) + Offset   [web citation]
    Sag For Asphere 0 With Linear Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (c * xy) + Offset   [web citation]
    Sag For Asphere 1 With Linear Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (d * xy) + Offset   [web citation]
    Sag For Asphere 2 With Linear Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (f * xy) + Offset   [web citation]
    Sag For Asphere 3 With Linear Decay And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (g * xy) + Offset   [web citation]
    Transform Sag For Asphere 0 With Linear Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (h * xy) + Offset   [web citation]
    Transform Sag For Asphere 1 With Linear Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (i * xy) + Offset   [web citation]
    Transform Sag For Asphere 2 With Linear Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (j * xy) + Offset   [web citation]
    Transform Sag For Asphere 3 With Linear Decay And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (k * xy) + Offset   [web citation]
     
     
    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 / (g * xy)
    Sag For Asphere 0 Scaled With Linear Decay 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (d * xy)   [web citation]
    Sag For Asphere 0 With Linear Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (c * xy)   [web citation]
    Sag For Asphere 1 With Linear Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (d * xy)   [web citation]
    Sag For Asphere 2 With Linear Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (f * xy)   [web citation]
    Sag For Asphere 3 With Linear Decay 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (g * xy)   [web citation]
    Transform Sag For Asphere 0 With Linear Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z / (h * xy)   [web citation]
    Transform Sag For Asphere 1 With Linear Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z / (i * xy)   [web citation]
    Transform Sag For Asphere 2 With Linear Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z / (j * xy)   [web citation]
    Transform Sag For Asphere 3 With Linear Decay 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z / (k * xy)   [web citation]
     
     
    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 * (g * xy) + Offset
    Sag For Asphere 0 Scaled With Linear Growth And Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (d * xy) + Offset   [web citation]
    Sag For Asphere 0 With Linear Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (c * xy) + Offset   [web citation]
    Sag For Asphere 1 With Linear Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (d * xy) + Offset   [web citation]
    Sag For Asphere 2 With Linear Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (f * xy) + Offset   [web citation]
    Sag For Asphere 3 With Linear Growth And Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (g * xy) + Offset   [web citation]
    Transform Sag For Asphere 0 With Linear Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (h * xy) + Offset   [web citation]
    Transform Sag For Asphere 1 With Linear Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (i * xy) + Offset   [web citation]
    Transform Sag For Asphere 2 With Linear Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (j * xy) + Offset   [web citation]
    Transform Sag For Asphere 3 With Linear Growth And Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (k * xy) + Offset   [web citation]
     
     
    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 * (g * xy)
    Sag For Asphere 0 Scaled With Linear Growth 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (d * xy)   [web citation]
    Sag For Asphere 0 With Linear Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (c * xy)   [web citation]
    Sag For Asphere 1 With Linear Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (d * xy)   [web citation]
    Sag For Asphere 2 With Linear Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (f * xy)   [web citation]
    Sag For Asphere 3 With Linear Growth 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (g * xy)   [web citation]
    Transform Sag For Asphere 0 With Linear Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z * (h * xy)   [web citation]
    Transform Sag For Asphere 1 With Linear Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z * (i * xy)   [web citation]
    Transform Sag For Asphere 2 With Linear Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = z * (j * xy)   [web citation]
    Transform Sag For Asphere 3 With Linear Growth 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = z * (k * xy)   [web citation]
     
     
    Reciprocal Sag For Asphere 0 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = 1.0 / z   [web citation]
    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 Scaled 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = 1.0 / z   [web citation]
    Reciprocal Sag For Asphere 1 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = 1.0 / z   [web citation]
    Reciprocal Sag For Asphere 2 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = 1.0 / z   [web citation]
    Reciprocal Sag For Asphere 3 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = 1.0 / z   [web citation]
    Reciprocal Transform Sag For Asphere 0 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = 1.0 / z   [web citation]
    Reciprocal Transform Sag For Asphere 1 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = 1.0 / z   [web citation]
    Reciprocal Transform Sag For Asphere 2 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = 1.0 / z   [web citation]
    Reciprocal Transform Sag For Asphere 3 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = 1.0 / z   [web citation]
     
     
    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
    Reciprocal Sag For Asphere 0 Scaled With Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = 1.0 / z + Offset   [web citation]
    Reciprocal Sag For Asphere 0 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = 1.0 / z + Offset   [web citation]
    Reciprocal Sag For Asphere 1 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = 1.0 / z + Offset   [web citation]
    Reciprocal Sag For Asphere 2 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = 1.0 / z + Offset   [web citation]
    Reciprocal Sag For Asphere 3 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = 1.0 / z + Offset   [web citation]
    Reciprocal Transform Sag For Asphere 0 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = 1.0 / z + Offset   [web citation]
    Reciprocal Transform Sag For Asphere 1 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = 1.0 / z + Offset   [web citation]
    Reciprocal Transform Sag For Asphere 2 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6
z = 1.0 / z + Offset   [web citation]
    Reciprocal Transform Sag For Asphere 3 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8
z = 1.0 / z + Offset   [web citation]
     
     
    Sag For Asphere 0 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)   [web citation]
    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 Scaled 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)   [web citation]
    Sag For Asphere 1 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4   [web citation]
    Sag For Asphere 2 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6   [web citation]
    Sag For Asphere 3 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8   [web citation]
    Transform Sag For Asphere 0 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)   [web citation]
    Transform Sag For Asphere 1 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4   [web citation]
    Transform Sag For Asphere 2 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6   [web citation]
    Transform Sag For Asphere 3 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8   [web citation]
     
     
    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 Scaled With Offset 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + Offset   [web citation]
    Sag For Asphere 0 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + Offset   [web citation]
    Sag For Asphere 1 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + Offset   [web citation]
    Sag For Asphere 2 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + Offset   [web citation]
    Sag For Asphere 3 With Offset 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8 + Offset   [web citation]
    Transform Sag For Asphere 0 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + Offset   [web citation]
    Transform Sag For Asphere 1 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + Offset   [web citation]
    Transform Sag For Asphere 2 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + Offset   [web citation]
    Transform Sag For Asphere 3 With Offset 3D  
s2 = (ax+b)2 + (cy+d)2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4 + A6*s6 + A8*s8 + Offset   [web citation]
     
     
    Sag For Asphere 0 Plus Plane 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z + (c * x) + (d * y) + f   [web citation]
    Sag For Asphere 0 Scaled Plus Plane 3D  
s2 = x2 + y2
z = Scale * (s2/r) / (1+(1-(k+1)(s/r)2)1/2)
z = z + (d * x) + (f * y) + g   [web citation]
    Sag For Asphere 1 Plus Plane 3D  
s2 = x2 + y2
z = (s2/r) / (1+(1-(k+1)(s/r)2)1/2) + A4*s4
z = z + (d * x) + (f * y) + g   [web citation]
     
     


3D Peak

    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 / (h * 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 / (h * 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 / (h * 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 / (h * 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 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 / (h * 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 / (h * 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 / (h * 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 / (h * 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 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 * (h * 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 * (h * 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 * (h * 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 * (h * 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
     
     
    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 * (h * 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 * (h * 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 * (h * 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 * (h * 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)
     
     
    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 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 / (h * 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 / (h * 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 / (h * 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 / (h * 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 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 / (h * 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 / (h * 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 / (h * 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 / (h * 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 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 * (h * 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 * (h * 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 * (h * 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 * (h * 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
     
     
    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 * (h * xy)
    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 * (h * xy)
    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 * (h * xy)
    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 * (h * xy)
    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
     
     
    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
     
     
    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
     
     


3D Polyfunctional

    User-Selectable Polyfunctional 3D   z = user-selectable function
     
     


3D Polynomial

    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
     
     
    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
    Reciprocal User-Selectable Polynomial 3D  
z = user-selectable polynomial
z = 1.0 / z
     
     
    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
     
     


3D Power

    Power A With Exponential Decay And Offset 3D  
z = a * (xb + yc)
z = z / exp(xy) + Offset
    Power D With Exponential Decay And Offset 3D  
z = axb + cyd
z = z / (f * exp(xy)) + Offset
    Power E With Exponential Decay And Offset 3D  
z = a * xb * yc
z = z / exp(xy) + Offset
    Transform Power A With Exponential Decay And Offset 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z / exp(xy) + Offset
    Transform Power D With Exponential Decay And Offset 3D  
z = a(fx + g)b + c(hy + i)d
z = z / (j * exp(xy)) + Offset
    Transform Power E With Exponential Decay And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z / exp(xy) + Offset
     
     
    Power A With Exponential Decay 3D  
z = a * (xb + yc)
z = z / exp(xy)
    Power B With Exponential Decay 3D  
z = a + xb + yc
z = z / (d * exp(xy))
    Power C With Exponential Decay 3D  
z = a + xb * yc
z = z / (d * exp(xy))
    Power D With Exponential Decay 3D  
z = axb + cyd
z = z / (f * exp(xy))
    Power E With Exponential Decay 3D  
z = a * xb * yc
z = z / exp(xy)
    Transform Power A With Exponential Decay 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z / exp(xy)
    Transform Power B With Exponential Decay 3D  
z = a + (dx + f)b + (gy + h)c
z = z / (i * exp(xy))
    Transform Power C With Exponential Decay 3D  
z = a + (dx + f)b * (gy + h)c
z = z / (i * exp(xy))
    Transform Power D With Exponential Decay 3D  
z = a(fx + g)b + c(hy + i)d
z = z / (j * exp(xy))
    Transform Power E With Exponential Decay 3D  
z = a * (dx + f)b * (gy + h)c
z = z / exp(xy)
     
     
    Power A With Exponential Growth And Offset 3D  
z = a * (xb + yc)
z = z * exp(xy) + Offset
    Power D With Exponential Growth And Offset 3D  
z = axb + cyd
z = z * (f * exp(xy)) + Offset
    Power E With Exponential Growth And Offset 3D  
z = a * xb * yc
z = z * exp(xy) + Offset
    Transform Power A With Exponential Growth And Offset 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z * exp(xy) + Offset
    Transform Power D With Exponential Growth And Offset 3D  
z = a(fx + g)b + c(hy + i)d
z = z * (j * exp(xy)) + Offset
    Transform Power E With Exponential Growth And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z * exp(xy) + Offset
     
     
    Power A With Exponential Growth 3D  
z = a * (xb + yc)
z = z * exp(xy)
    Power B With Exponential Growth 3D  
z = a + xb + yc
z = z * (d * exp(xy))
    Power C With Exponential Growth 3D  
z = a + xb * yc
z = z * (d * exp(xy))
    Power D With Exponential Growth 3D  
z = axb + cyd
z = z * (f * exp(xy))
    Power E With Exponential Growth 3D  
z = a * xb * yc
z = z * exp(xy)
    Transform Power A With Exponential Growth 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z * exp(xy)
    Transform Power B With Exponential Growth 3D  
z = a + (dx + f)b + (gy + h)c
z = z * (i * exp(xy))
    Transform Power C With Exponential Growth 3D  
z = a + (dx + f)b * (gy + h)c
z = z * (i * exp(xy))
    Transform Power D With Exponential Growth 3D  
z = a(fx + g)b + c(hy + i)d
z = z * (j * exp(xy))
    Transform Power E With Exponential Growth 3D  
z = a * (dx + f)b * (gy + h)c
z = z * exp(xy)
     
     
    Inverse Power A 3D  
z = a * (xb + yc)
z = xy / z
    Inverse Power B 3D  
z = a + xb + yc
z = xy / z
    Inverse Power C 3D  
z = a + xb * yc
z = xy / z
    Inverse Power D 3D  
z = axb + cyd
z = xy / z
    Inverse Power E 3D  
z = a * xb * yc
z = xy / z
    Inverse Transform Power A 3D  
z = a * ((dx + f)b + (gy + h)c)
z = xy / z
    Inverse Transform Power B 3D  
z = a + (dx + f)b + (gy + h)c
z = xy / z
    Inverse Transform Power C 3D  
z = a + (dx + f)b * (gy + h)c
z = xy / z
    Inverse Transform Power D 3D  
z = a(fx + g)b + c(hy + i)d
z = xy / z
    Inverse Transform Power E 3D  
z = a * (dx + f)b * (gy + h)c
z = xy / z
     
     
    Inverse Power A With Offset 3D  
z = a * (xb + yc)
z = xy / (z + Offset
    Inverse Power D With Offset 3D  
z = axb + cyd
z = xy / (z + Offset
    Inverse Power E With Offset 3D  
z = a * xb * yc
z = xy / (z + Offset
    Inverse Transform Power A With Offset 3D  
z = a * ((dx + f)b + (gy + h)c)
z = xy / (z + Offset
    Inverse Transform Power D With Offset 3D  
z = a(fx + g)b + c(hy + i)d
z = xy / (z + Offset
    Inverse Transform Power E With Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = xy / (z + Offset
     
     
    Power A With Linear Decay And Offset 3D  
z = a * (xb + yc)
z = z / xy + Offset
    Power D With Linear Decay And Offset 3D  
z = axb + cyd
z = z / (f * xy) + Offset
    Power E With Linear Decay And Offset 3D  
z = a * xb * yc
z = z / xy + Offset
    Transform Power A With Linear Decay And Offset 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z / xy + Offset
    Transform Power D With Linear Decay And Offset 3D  
z = a(fx + g)b + c(hy + i)d
z = z / (j * xy) + Offset
    Transform Power E With Linear Decay And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z / xy + Offset
     
     
    Power A With Linear Decay 3D  
z = a * (xb + yc)
z = z / xy
    Power B With Linear Decay 3D  
z = a + xb + yc
z = z / (d * xy)
    Power C With Linear Decay 3D  
z = a + xb * yc
z = z / (d * xy)
    Power D With Linear Decay 3D  
z = axb + cyd
z = z / (f * xy)
    Power E With Linear Decay 3D  
z = a * xb * yc
z = z / xy
    Transform Power A With Linear Decay 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z / xy
    Transform Power B With Linear Decay 3D  
z = a + (dx + f)b + (gy + h)c
z = z / (i * xy)
    Transform Power C With Linear Decay 3D  
z = a + (dx + f)b * (gy + h)c
z = z / (i * xy)
    Transform Power D With Linear Decay 3D  
z = a(fx + g)b + c(hy + i)d
z = z / (j * xy)
    Transform Power E With Linear Decay 3D  
z = a * (dx + f)b * (gy + h)c
z = z / xy
     
     
    Power A With Linear Growth And Offset 3D  
z = a * (xb + yc)
z = z * xy + Offset
    Power D With Linear Growth And Offset 3D  
z = axb + cyd
z = z * (f * xy) + Offset
    Power E With Linear Growth And Offset 3D  
z = a * xb * yc
z = z * xy + Offset
    Transform Power A With Linear Growth And Offset 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z * xy + Offset
    Transform Power D With Linear Growth And Offset 3D  
z = a(fx + g)b + c(hy + i)d
z = z * (j * xy) + Offset
    Transform Power E With Linear Growth And Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = z * xy + Offset
     
     
    Power A With Linear Growth 3D  
z = a * (xb + yc)
z = z * xy
    Power B With Linear Growth 3D  
z = a + xb + yc
z = z * (d * xy)
    Power C With Linear Growth 3D  
z = a + xb * yc
z = z * (d * xy)
    Power D With Linear Growth 3D  
z = axb + cyd
z = z * (f * xy)
    Power E With Linear Growth 3D  
z = a * xb * yc
z = z * xy
    Transform Power A With Linear Growth 3D  
z = a * ((dx + f)b + (gy + h)c)
z = z * xy
    Transform Power B With Linear Growth 3D  
z = a + (dx + f)b + (gy + h)c
z = z * (i * xy)
    Transform Power C With Linear Growth 3D  
z = a + (dx + f)b * (gy + h)c
z = z * (i * xy)
    Transform Power D With Linear Growth 3D  
z = a(fx + g)b + c(hy + i)d
z = z * (j * xy)
    Transform Power E With Linear Growth 3D  
z = a * (dx + f)b * (gy + h)c
z = z * xy
     
     
    Reciprocal Power A 3D  
z = a * (xb + yc)
z = 1.0 / z
    Reciprocal Power B 3D  
z = a + xb + yc
z = 1.0 / z
    Reciprocal Power C 3D  
z = a + xb * yc
z = 1.0 / z
    Reciprocal Power D 3D  
z = axb + cyd
z = 1.0 / z
    Reciprocal Power E 3D  
z = a * xb * yc
z = 1.0 / z
    Reciprocal Transform Power A 3D  
z = a * ((dx + f)b + (gy + h)c)
z = 1.0 / z
    Reciprocal Transform Power B 3D  
z = a + (dx + f)b + (gy + h)c
z = 1.0 / z
    Reciprocal Transform Power C 3D  
z = a + (dx + f)b * (gy + h)c
z = 1.0 / z
    Reciprocal Transform Power D 3D  
z = a(fx + g)b + c(hy + i)d
z = 1.0 / z
    Reciprocal Transform Power E 3D  
z = a * (dx + f)b * (gy + h)c
z = 1.0 / z
     
     
    Reciprocal Power A With Offset 3D  
z = a * (xb + yc)
z = 1.0 / z + Offset
    Reciprocal Power D With Offset 3D  
z = axb + cyd
z = 1.0 / z + Offset
    Reciprocal Power E With Offset 3D  
z = a * xb * yc
z = 1.0 / z + Offset
    Reciprocal Transform Power A With Offset 3D  
z = a * ((dx + f)b + (gy + h)c)
z = 1.0 / z + Offset
    Reciprocal Transform Power D With Offset 3D  
z = a(fx + g)b + c(hy + i)d
z = 1.0 / z + Offset
    Reciprocal Transform Power E With Offset 3D  
z = a * (dx + f)b * (gy + h)c
z = 1.0 / z + Offset
     
     
    Power A 3D   z = a * (xb + yc)
    Power B 3D   z = a + xb + yc
    Power C 3D   z = a + xb * yc
    Power D 3D   z = axb + cyd
    Power E 3D   z = a * xb * yc
    Transform Power A 3D   z = a * ((dx + f)b + (gy + h)c)
    Transform Power B 3D   z = a + (dx + f)b + (gy + h)c
    Transform Power C 3D   z = a + (dx + f)b * (gy + h)c
    Transform Power D 3D   z = a(fx + g)b + c(hy + i)d
    Transform Power E 3D   z = a * (dx + f)b * (gy + h)c
     
     
    Power A With Offset 3D   z = a * (xb + yc) + Offset
    Power D With Offset 3D   z = axb + cyd + Offset
    Power E With Offset 3D   z = a * xb * yc + Offset
    Transform Power A With Offset 3D   z = a * ((dx + f)b + (gy + h)c) + Offset
    Transform Power D With Offset 3D   z = a(fx + g)b + c(hy + i)d + Offset
    Transform Power E With Offset 3D   z = a * (dx + f)b * (gy + h)c + Offset
     
     
    Power A Plus Plane 3D  
z = a * (xb + yc)
z = z + (d * x) + (f * y) + g
    Power E Plus Plane 3D  
z = a * xb * yc
z = z + (d * x) + (f * y) + g
     
     


3D Rational

    Rational A With Exponential Decay And Offset 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z / (g * exp(xy)) + Offset
    Rational B With Exponential Decay And Offset 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * exp(xy)) + Offset
    Rational C With Exponential Decay And Offset 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * exp(xy)) + Offset
    Rational D With Exponential Decay And Offset 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * exp(xy)) + Offset
    Rational E With Exponential Decay And Offset 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * exp(xy)) + Offset
    Rational F With Exponential Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z / (g * exp(xy)) + Offset
    Rational G With Exponential Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z / (g * exp(xy)) + Offset
    Rational H With Exponential Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z / (g * exp(xy)) + Offset
    Rational I With Exponential Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z / (g * 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 / (g * 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 / (g * 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 / (g * 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 / (g * exp(xy)) + Offset
    Rational N With Exponential Decay And Offset 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * exp(xy)) + Offset
     
     
    Rational A With Exponential Decay 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z / (g * exp(xy))
    Rational B With Exponential Decay 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * exp(xy))
    Rational C With Exponential Decay 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * exp(xy))
    Rational D With Exponential Decay 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * exp(xy))
    Rational E With Exponential Decay 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * exp(xy))
    Rational F With Exponential Decay 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z / (g * exp(xy))
    Rational G With Exponential Decay 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z / (g * exp(xy))
    Rational H With Exponential Decay 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z / (g * exp(xy))
    Rational I With Exponential Decay 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z / (g * 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 / (g * 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 / (g * 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 / (g * 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 / (g * exp(xy))
    Rational N With Exponential Decay 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * exp(xy))
     
     
    Rational A With Exponential Growth And Offset 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z * (g * exp(xy)) + Offset
    Rational B With Exponential Growth And Offset 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * exp(xy)) + Offset
    Rational C With Exponential Growth And Offset 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * exp(xy)) + Offset
    Rational D With Exponential Growth And Offset 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * exp(xy)) + Offset
    Rational E With Exponential Growth And Offset 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * exp(xy)) + Offset
    Rational F With Exponential Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z * (g * exp(xy)) + Offset
    Rational G With Exponential Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z * (g * exp(xy)) + Offset
    Rational H With Exponential Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z * (g * exp(xy)) + Offset
    Rational I With Exponential Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z * (g * 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 * (g * 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 * (g * 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 * (g * 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 * (g * exp(xy)) + Offset
    Rational N With Exponential Growth And Offset 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * exp(xy)) + Offset
     
     
    Rational A With Exponential Growth 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z * (g * exp(xy))
    Rational B With Exponential Growth 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * exp(xy))
    Rational C With Exponential Growth 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * exp(xy))
    Rational D With Exponential Growth 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * exp(xy))
    Rational E With Exponential Growth 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * exp(xy))
    Rational F With Exponential Growth 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z * (g * exp(xy))
    Rational G With Exponential Growth 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z * (g * exp(xy))
    Rational H With Exponential Growth 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z * (g * exp(xy))
    Rational I With Exponential Growth 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z * (g * 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 * (g * 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 * (g * 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 * (g * 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 * (g * exp(xy))
    Rational N With Exponential Growth 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * exp(xy))
     
     
    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 And Offset 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z / (g * xy) + Offset
    Rational B With Linear Decay And Offset 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * xy) + Offset
    Rational C With Linear Decay And Offset 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * xy) + Offset
    Rational D With Linear Decay And Offset 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * xy) + Offset
    Rational E With Linear Decay And Offset 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * xy) + Offset
    Rational F With Linear Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z / (g * xy) + Offset
    Rational G With Linear Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z / (g * xy) + Offset
    Rational H With Linear Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z / (g * xy) + Offset
    Rational I With Linear Decay And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z / (g * 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 / (g * 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 / (g * 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 / (g * 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 / (g * xy) + Offset
    Rational N With Linear Decay And Offset 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * xy) + Offset
     
     
    Rational A With Linear Decay 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z / (g * xy)
    Rational B With Linear Decay 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * xy)
    Rational C With Linear Decay 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z / (g * xy)
    Rational D With Linear Decay 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * xy)
    Rational E With Linear Decay 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z / (g * xy)
    Rational F With Linear Decay 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z / (g * xy)
    Rational G With Linear Decay 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z / (g * xy)
    Rational H With Linear Decay 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z / (g * xy)
    Rational I With Linear Decay 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z / (g * xy)
    Rational J With Linear Decay 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y))
z = z / (g * xy)
    Rational K With Linear Decay 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y))
z = z / (g * xy)
    Rational L With Linear Decay 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y))
z = z / (g * xy)
    Rational M With Linear Decay 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y))
z = z / (g * xy)
    Rational N With Linear Decay 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * 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 / (i * xy)
     
     
    Rational A With Linear Growth And Offset 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z * (g * xy) + Offset
    Rational B With Linear Growth And Offset 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * xy) + Offset
    Rational C With Linear Growth And Offset 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * xy) + Offset
    Rational D With Linear Growth And Offset 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * xy) + Offset
    Rational E With Linear Growth And Offset 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * xy) + Offset
    Rational F With Linear Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z * (g * xy) + Offset
    Rational G With Linear Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z * (g * xy) + Offset
    Rational H With Linear Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z * (g * xy) + Offset
    Rational I With Linear Growth And Offset 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z * (g * 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 * (g * 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 * (g * 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 * (g * 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 * (g * xy) + Offset
    Rational N With Linear Growth And Offset 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * 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 * (i * xy) + Offset
     
     
    Rational A With Linear Growth 3D  
z = (a + bx + cy)/(1 + dx + fy)
z = z * (g * xy)
    Rational B With Linear Growth 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * xy)
    Rational C With Linear Growth 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + dx + fy)
z = z * (g * xy)
    Rational D With Linear Growth 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * xy)
    Rational E With Linear Growth 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + dx + fy)
z = z * (g * xy)
    Rational F With Linear Growth 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*ln(y))
z = z * (g * xy)
    Rational G With Linear Growth 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*ln(y))
z = z * (g * xy)
    Rational H With Linear Growth 3D  
z = (a + bx + cy)/(1 + d*ln(x) + f*exp(y))
z = z * (g * xy)
    Rational I With Linear Growth 3D  
z = (a + bx + cy)/(1 + d*exp(x) + f*exp(y))
z = z * (g * xy)
    Rational J With Linear Growth 3D  
z = (a + b*ln(x) + c*ln(y))/(1 + d*ln(x) + f*ln(y))
z = z * (g * xy)
    Rational K With Linear Growth 3D  
z = (a + b*exp(x) + c*ln(y))/(1 + d*exp(x) + f*ln(y))
z = z * (g * xy)
    Rational L With Linear Growth 3D  
z = (a + b*ln(x) + c*exp(y))/(1 + d*ln(x) + f*exp(y))
z = z * (g * xy)
    Rational M With Linear Growth 3D  
z = (a + b*exp(x) + c*exp(y))/(1 + d*exp(x) + f*exp(y))
z = z * (g * xy)
    Rational N With Linear Growth 3D  
z = (a + bx + cy + dxy)/(1 + fx + gy + hxy)
z = z * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
    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 * (i * xy)
     
     
    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
     
     
    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
     
     


3D RomanSurfaces

    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 / (d * 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 / (g * 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 / (b * 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 / (d * 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 / (g * exp(xy)) + Offset
    Roman Surface (plus) Scaled With Exponential Decay And Offset 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (c * 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 / (b * exp(xy)) + 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 / (d * 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 / (g * exp(xy))
    Roman Surface (minus) With Exponential Decay 3D  
z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (b * 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 / (d * 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 / (g * exp(xy))
    Roman Surface (plus) Scaled With Exponential Decay 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (c * exp(xy))
    Roman Surface (plus) With Exponential Decay 3D  
z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (b * 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 * (d * 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 * (g * 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 * (b * 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 * (d * 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 * (g * exp(xy)) + Offset
    Roman Surface (plus) Scaled With Exponential Growth And Offset 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (c * 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 * (b * 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 * (d * 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 * (g * exp(xy))
    Roman Surface (minus) With Exponential Growth 3D  
z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (b * 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 * (d * 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 * (g * exp(xy))
    Roman Surface (plus) Scaled With Exponential Growth 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (c * exp(xy))
    Roman Surface (plus) With Exponential Growth 3D  
z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (b * exp(xy))
     
     
    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 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
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) Scaled With Offset 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
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 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 / (d * 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 / (g * 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 / (b * 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 / (d * 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 / (g * xy) + Offset
    Roman Surface (plus) Scaled With Linear Decay And Offset 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (c * 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 / (b * xy) + 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 / (d * 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 / (g * xy)
    Roman Surface (minus) With Linear Decay 3D  
z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (b * 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 / (d * 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 / (g * xy)
    Roman Surface (plus) Scaled With Linear Decay 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (c * xy)
    Roman Surface (plus) With Linear Decay 3D  
z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z / (b * xy)
     
     
    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 * (d * 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 * (g * 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 * (b * 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 * (d * 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 * (g * xy) + Offset
    Roman Surface (plus) Scaled With Linear Growth And Offset 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (c * 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 * (b * 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 * (d * xy)
    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 * (g * xy)
    Roman Surface (minus) With Linear Growth 3D  
z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (b * xy)
    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 * (d * xy)
    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 * (g * xy)
    Roman Surface (plus) Scaled With Linear Growth 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (c * xy)
    Roman Surface (plus) With Linear Growth 3D  
z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z * (b * xy)
     
     
    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 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
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) Scaled With Offset 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
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
     
     
    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 3D   z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
    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) Scaled With Offset 3D   z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2)) + 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 Plus Plane 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 + (d * x) + (f * y) + g
    Roman Surface (minus) Plus Plane 3D  
z = (k(y2-x2) - (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z + (b * x) + (c * y) + d
    Roman Surface (plus) Offset XY Plus Plane 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 + (d * x) + (f * y) + g
    Roman Surface (plus) Plus Plane 3D  
z = (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z + (b * x) + (c * y) + d
    Roman Surface (plus) Scaled Plus Plane 3D  
z = Scale * (k(y2-x2) + (x2-y2)sqrt(k2-x2-y2)) / (2(x2+y2))
z = z + (c * x) + (d * y) + f
     
     


3D Sigmoidal

    Fraser Smith Sigmoid Scaled With Exponential Decay And Offset 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / exp(xy) + Offset
    Fraser Smith Sigmoid With Exponential Decay And Offset 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / (f * 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 Decay 3D  
z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y))))
z = z / (h * 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 / (h * exp(xy))
    Fraser Smith Sigmoid Scaled With Exponential Decay 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / exp(xy)
    Fraser Smith Sigmoid With Exponential Decay 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / (f * 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 Scaled With Exponential Growth And Offset 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * exp(xy) + Offset
    Fraser Smith Sigmoid With Exponential Growth And Offset 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * (f * 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
     
     
    Andrea Prunotto Sigmoid A With Exponential Growth 3D  
z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y))))
z = z * (h * 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 * (h * exp(xy))
    Fraser Smith Sigmoid Scaled With Exponential Growth 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * exp(xy)
    Fraser Smith Sigmoid With Exponential Growth 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * (f * exp(xy))
    Sigmoid With Exponential Growth 3D  
z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy)))
z = z * exp(xy)
     
     
    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 + exp(c - dy)))
z = xy / z
    Inverse Fraser Smith Sigmoid Scaled 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(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 Scaled With Offset 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = xy / (z + Offset
    Inverse Fraser Smith Sigmoid With Offset 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(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
     
     
    Fraser Smith Sigmoid Scaled With Linear Decay And Offset 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / xy + Offset
    Fraser Smith Sigmoid With Linear Decay And Offset 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / (f * 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 Decay 3D  
z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y))))
z = z / (h * 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 / (h * xy)
    Fraser Smith Sigmoid Scaled With Linear Decay 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / xy
    Fraser Smith Sigmoid With Linear Decay 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z / (f * xy)
    Sigmoid With Linear Decay 3D  
z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy)))
z = z / xy
     
     
    Fraser Smith Sigmoid Scaled With Linear Growth And Offset 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * xy + Offset
    Fraser Smith Sigmoid With Linear Growth And Offset 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * (f * 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
     
     
    Andrea Prunotto Sigmoid A With Linear Growth 3D  
z = a0 + (a1 / (1.0 + exp(a2 * (x + a3 + a4 * y + a5 * x * y))))
z = z * (h * xy)
    Andrea Prunotto Sigmoid B With Linear Growth 3D  
z = a0 + (a1 / (1.0 + exp(a2 * (x * a3 + a4 * y + a5 * x * y))))
z = z * (h * xy)
    Fraser Smith Sigmoid Scaled With Linear Growth 3D  
z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * xy
    Fraser Smith Sigmoid With Linear Growth 3D  
z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
z = z * (f * xy)
    Sigmoid With Linear Growth 3D  
z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy)))
z = z * xy
     
     
    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
     
     
    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 + exp(c - dy)))
    Fraser Smith Sigmoid Scaled 3D   z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy)))
    Sigmoid 3D   z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy)))
     
     
    Fraser Smith Sigmoid Scaled With Offset 3D   z = Scale / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy))) + Offset
    Fraser Smith Sigmoid With Offset 3D   z = 1.0 / ((1.0 + exp(a - bx)) * (1.0 + exp(c - dy))) + Offset
    Sigmoid With Offset 3D   z = a / ((1.0 + exp(b - cx)) * (1.0 + exp(d - fy))) + Offset
     
     


3D Simple

    Simple Equation 01 With Exponential Decay And Offset 3D  
z = a*pow(x,b)*pow(y,c)
z = z / exp(xy) + Offset
    Simple Equation 02 With Exponential Decay And Offset 3D  
z = x/(a+b*y)
z = z / (c * exp(xy)) + Offset
    Simple Equation 03 With Exponential Decay And Offset 3D  
z = y/(a+b*x)
z = z / (c * exp(xy)) + Offset
    Simple Equation 04 With Exponential Decay And Offset 3D  
z = a*pow(x,b*y)
z = z / exp(xy) + Offset
    Simple Equation 05 With Exponential Decay And Offset 3D  
z = a*pow(y,b*x)
z = z / exp(xy) + Offset
    Simple Equation 06 With Exponential Decay And Offset 3D  
z = a*pow(x,b/y)
z = z / exp(xy) + Offset
    Simple Equation 07 With Exponential Decay And Offset 3D  
z = a*pow(y,b/x)
z = z / exp(xy) + Offset
    Simple Equation 08 With Exponential Decay And Offset 3D  
z = a*x+b*pow(y,2.0)
z = z / (c * exp(xy)) + Offset
    Simple Equation 09 With Exponential Decay And Offset 3D  
z = a*y+b*pow(x,2.0)
z = z / (c * exp(xy)) + Offset
    Simple Equation 10 With Exponential Decay And Offset 3D  
z = x/(a+b*pow(y,2.0))
z = z / (c * exp(xy)) + Offset
    Simple Equation 11 With Exponential Decay And Offset 3D  
z = y/(a+b*pow(x,2.0))
z = z / (c * exp(xy)) + Offset
    Simple Equation 12 With Exponential Decay And Offset 3D  
z = a*pow(b,x)*pow(y,c)
z = z / exp(xy) + Offset
    Simple Equation 13 With Exponential Decay And Offset 3D  
z = a*pow(b,y)*pow(x,c)
z = z / exp(xy) + Offset
    Simple Equation 14 With Exponential Decay And Offset 3D  
z = a*pow(x*y,b)
z = z / exp(xy) + Offset
    Simple Equation 15 With Exponential Decay And Offset 3D  
z = a*pow(x/y,b)
z = z / exp(xy) + Offset
    Simple Equation 16 With Exponential Decay And Offset 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z / exp(xy) + Offset
    Simple Equation 17 With Exponential Decay And Offset 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z / exp(xy) + Offset
    Simple Equation 18 With Exponential Decay And Offset 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z / exp(xy) + Offset
    Simple Equation 19 With Exponential Decay And Offset 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z / exp(xy) + Offset
    Simple Equation 20 With Exponential Decay And Offset 3D  
z = a*pow(x,b+c*y)
z = z / exp(xy) + Offset
    Simple Equation 21 With Exponential Decay And Offset 3D  
z = a*pow(y,b+c*x)
z = z / exp(xy) + Offset
    Simple Equation 22 With Exponential Decay And Offset 3D  
z = a*pow(x,b+c/y)
z = z / exp(xy) + Offset
    Simple Equation 23 With Exponential Decay And Offset 3D  
z = a*pow(y,b+c/x)
z = z / exp(xy) + Offset
    Simple Equation 24 With Exponential Decay And Offset 3D  
z = a*pow(x,b+c*ln(y))
z = z / exp(xy) + Offset
    Simple Equation 25 With Exponential Decay And Offset 3D  
z = a*pow(y,b+c*ln(x))
z = z / exp(xy) + Offset
    Simple Equation 26 With Exponential Decay And Offset 3D  
z = a*pow(y,b+c/ln(x))
z = z / exp(xy) + Offset
    Simple Equation 27 With Exponential Decay And Offset 3D  
z = a*pow(x,b+c/ln(y))
z = z / exp(xy) + Offset
    Simple Equation 28 With Exponential Decay And Offset 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z / exp(xy) + Offset
    Simple Equation 29 With Exponential Decay And Offset 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z / exp(xy) + Offset
    Simple Equation 30 With Exponential Decay And Offset 3D  
z = a*exp(b/x+c*y)
z = z / exp(xy) + Offset
    Simple Equation 31 With Exponential Decay And Offset 3D  
z = a*exp(b/y+c*x)
z = z / exp(xy) + Offset
    Simple Equation 32 With Exponential Decay And Offset 3D  
z = (a+x)/(b+c*y)
z = z / (d * exp(xy)) + Offset
    Simple Equation 33 With Exponential Decay And Offset 3D  
z = (a+y)/(b+c*x)
z = z / (d * exp(xy)) + Offset
    Simple Equation 34 With Exponential Decay And Offset 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z / (d * exp(xy)) + Offset
    Simple Equation 35 With Exponential Decay And Offset 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z / (d * exp(xy)) + Offset
    Simple Equation 36 With Exponential Decay And Offset 3D  
z = a*(exp(b*x)-exp(c*y))
z = z / exp(xy) + Offset
    Simple Equation 37 With Exponential Decay And Offset 3D  
z = a*pow(x,b*pow(y,c))
z = z / exp(xy) + Offset
    Simple Equation 38 With Exponential Decay And Offset 3D  
z = a*pow(y,b*pow(x,c))
z = z / exp(xy) + Offset
    Simple Equation 39 With Exponential Decay And Offset 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z / (d * exp(xy)) + Offset
    Simple Equation 40 With Exponential Decay And Offset 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z / (d * exp(xy)) + Offset
    Simple Equation 41 With Exponential Decay And Offset 3D  
z = exp(a+b/x+c*ln(y))
z = z / (d * exp(xy)) + Offset
    Simple Equation 42 With Exponential Decay And Offset 3D  
z = exp(a+b/y+c*ln(x))
z = z / (d * exp(xy)) + Offset
    Simple Equation 43 With Exponential Decay And Offset 3D  
z = a*pow(x,b)*ln(y+c)
z = z / exp(xy) + Offset
    Simple Equation 44 With Exponential Decay And Offset 3D  
z = a*pow(y,b)*ln(x+c)
z = z / exp(xy) + Offset
     
     
    Simple Equation 01 With Exponential Decay 3D  
z = a*pow(x,b)*pow(y,c)
z = z / exp(xy)
    Simple Equation 02 With Exponential Decay 3D  
z = x/(a+b*y)
z = z / (c * exp(xy))
    Simple Equation 03 With Exponential Decay 3D  
z = y/(a+b*x)
z = z / (c * exp(xy))
    Simple Equation 04 With Exponential Decay 3D  
z = a*pow(x,b*y)
z = z / exp(xy)
    Simple Equation 05 With Exponential Decay 3D  
z = a*pow(y,b*x)
z = z / exp(xy)
    Simple Equation 06 With Exponential Decay 3D  
z = a*pow(x,b/y)
z = z / exp(xy)
    Simple Equation 07 With Exponential Decay 3D  
z = a*pow(y,b/x)
z = z / exp(xy)
    Simple Equation 08 With Exponential Decay 3D  
z = a*x+b*pow(y,2.0)
z = z / (c * exp(xy))
    Simple Equation 09 With Exponential Decay 3D  
z = a*y+b*pow(x,2.0)
z = z / (c * exp(xy))
    Simple Equation 10 With Exponential Decay 3D  
z = x/(a+b*pow(y,2.0))
z = z / (c * exp(xy))
    Simple Equation 11 With Exponential Decay 3D  
z = y/(a+b*pow(x,2.0))
z = z / (c * exp(xy))
    Simple Equation 12 With Exponential Decay 3D  
z = a*pow(b,x)*pow(y,c)
z = z / exp(xy)
    Simple Equation 13 With Exponential Decay 3D  
z = a*pow(b,y)*pow(x,c)
z = z / exp(xy)
    Simple Equation 14 With Exponential Decay 3D  
z = a*pow(x*y,b)
z = z / exp(xy)
    Simple Equation 15 With Exponential Decay 3D  
z = a*pow(x/y,b)
z = z / exp(xy)
    Simple Equation 16 With Exponential Decay 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z / exp(xy)
    Simple Equation 17 With Exponential Decay 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z / exp(xy)
    Simple Equation 18 With Exponential Decay 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z / exp(xy)
    Simple Equation 19 With Exponential Decay 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z / exp(xy)
    Simple Equation 20 With Exponential Decay 3D  
z = a*pow(x,b+c*y)
z = z / exp(xy)
    Simple Equation 21 With Exponential Decay 3D  
z = a*pow(y,b+c*x)
z = z / exp(xy)
    Simple Equation 22 With Exponential Decay 3D  
z = a*pow(x,b+c/y)
z = z / exp(xy)
    Simple Equation 23 With Exponential Decay 3D  
z = a*pow(y,b+c/x)
z = z / exp(xy)
    Simple Equation 24 With Exponential Decay 3D  
z = a*pow(x,b+c*ln(y))
z = z / exp(xy)
    Simple Equation 25 With Exponential Decay 3D  
z = a*pow(y,b+c*ln(x))
z = z / exp(xy)
    Simple Equation 26 With Exponential Decay 3D  
z = a*pow(y,b+c/ln(x))
z = z / exp(xy)
    Simple Equation 27 With Exponential Decay 3D  
z = a*pow(x,b+c/ln(y))
z = z / exp(xy)
    Simple Equation 28 With Exponential Decay 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z / exp(xy)
    Simple Equation 29 With Exponential Decay 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z / exp(xy)
    Simple Equation 30 With Exponential Decay 3D  
z = a*exp(b/x+c*y)
z = z / exp(xy)
    Simple Equation 31 With Exponential Decay 3D  
z = a*exp(b/y+c*x)
z = z / exp(xy)
    Simple Equation 32 With Exponential Decay 3D  
z = (a+x)/(b+c*y)
z = z / (d * exp(xy))
    Simple Equation 33 With Exponential Decay 3D  
z = (a+y)/(b+c*x)
z = z / (d * exp(xy))
    Simple Equation 34 With Exponential Decay 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z / (d * exp(xy))
    Simple Equation 35 With Exponential Decay 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z / (d * exp(xy))
    Simple Equation 36 With Exponential Decay 3D  
z = a*(exp(b*x)-exp(c*y))
z = z / exp(xy)
    Simple Equation 37 With Exponential Decay 3D  
z = a*pow(x,b*pow(y,c))
z = z / exp(xy)
    Simple Equation 38 With Exponential Decay 3D  
z = a*pow(y,b*pow(x,c))
z = z / exp(xy)
    Simple Equation 39 With Exponential Decay 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z / (d * exp(xy))
    Simple Equation 40 With Exponential Decay 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z / (d * exp(xy))
    Simple Equation 41 With Exponential Decay 3D  
z = exp(a+b/x+c*ln(y))
z = z / (d * exp(xy))
    Simple Equation 42 With Exponential Decay 3D  
z = exp(a+b/y+c*ln(x))
z = z / (d * exp(xy))
    Simple Equation 43 With Exponential Decay 3D  
z = a*pow(x,b)*ln(y+c)
z = z / exp(xy)
    Simple Equation 44 With Exponential Decay 3D  
z = a*pow(y,b)*ln(x+c)
z = z / exp(xy)
     
     
    Simple Equation 01 With Exponential Growth And Offset 3D  
z = a*pow(x,b)*pow(y,c)
z = z * exp(xy) + Offset
    Simple Equation 02 With Exponential Growth And Offset 3D  
z = x/(a+b*y)
z = z * (c * exp(xy)) + Offset
    Simple Equation 03 With Exponential Growth And Offset 3D  
z = y/(a+b*x)
z = z * (c * exp(xy)) + Offset
    Simple Equation 04 With Exponential Growth And Offset 3D  
z = a*pow(x,b*y)
z = z * exp(xy) + Offset
    Simple Equation 05 With Exponential Growth And Offset 3D  
z = a*pow(y,b*x)
z = z * exp(xy) + Offset
    Simple Equation 06 With Exponential Growth And Offset 3D  
z = a*pow(x,b/y)
z = z * exp(xy) + Offset
    Simple Equation 07 With Exponential Growth And Offset 3D  
z = a*pow(y,b/x)
z = z * exp(xy) + Offset
    Simple Equation 08 With Exponential Growth And Offset 3D  
z = a*x+b*pow(y,2.0)
z = z * (c * exp(xy)) + Offset
    Simple Equation 09 With Exponential Growth And Offset 3D  
z = a*y+b*pow(x,2.0)
z = z * (c * exp(xy)) + Offset
    Simple Equation 10 With Exponential Growth And Offset 3D  
z = x/(a+b*pow(y,2.0))
z = z * (c * exp(xy)) + Offset
    Simple Equation 11 With Exponential Growth And Offset 3D  
z = y/(a+b*pow(x,2.0))
z = z * (c * exp(xy)) + Offset
    Simple Equation 12 With Exponential Growth And Offset 3D  
z = a*pow(b,x)*pow(y,c)
z = z * exp(xy) + Offset
    Simple Equation 13 With Exponential Growth And Offset 3D  
z = a*pow(b,y)*pow(x,c)
z = z * exp(xy) + Offset
    Simple Equation 14 With Exponential Growth And Offset 3D  
z = a*pow(x*y,b)
z = z * exp(xy) + Offset
    Simple Equation 15 With Exponential Growth And Offset 3D  
z = a*pow(x/y,b)
z = z * exp(xy) + Offset
    Simple Equation 16 With Exponential Growth And Offset 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z * exp(xy) + Offset
    Simple Equation 17 With Exponential Growth And Offset 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z * exp(xy) + Offset
    Simple Equation 18 With Exponential Growth And Offset 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z * exp(xy) + Offset
    Simple Equation 19 With Exponential Growth And Offset 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z * exp(xy) + Offset
    Simple Equation 20 With Exponential Growth And Offset 3D  
z = a*pow(x,b+c*y)
z = z * exp(xy) + Offset
    Simple Equation 21 With Exponential Growth And Offset 3D  
z = a*pow(y,b+c*x)
z = z * exp(xy) + Offset
    Simple Equation 22 With Exponential Growth And Offset 3D  
z = a*pow(x,b+c/y)
z = z * exp(xy) + Offset
    Simple Equation 23 With Exponential Growth And Offset 3D  
z = a*pow(y,b+c/x)
z = z * exp(xy) + Offset
    Simple Equation 24 With Exponential Growth And Offset 3D  
z = a*pow(x,b+c*ln(y))
z = z * exp(xy) + Offset
    Simple Equation 25 With Exponential Growth And Offset 3D  
z = a*pow(y,b+c*ln(x))
z = z * exp(xy) + Offset
    Simple Equation 26 With Exponential Growth And Offset 3D  
z = a*pow(y,b+c/ln(x))
z = z * exp(xy) + Offset
    Simple Equation 27 With Exponential Growth And Offset 3D  
z = a*pow(x,b+c/ln(y))
z = z * exp(xy) + Offset
    Simple Equation 28 With Exponential Growth And Offset 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z * exp(xy) + Offset
    Simple Equation 29 With Exponential Growth And Offset 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z * exp(xy) + Offset
    Simple Equation 30 With Exponential Growth And Offset 3D  
z = a*exp(b/x+c*y)
z = z * exp(xy) + Offset
    Simple Equation 31 With Exponential Growth And Offset 3D  
z = a*exp(b/y+c*x)
z = z * exp(xy) + Offset
    Simple Equation 32 With Exponential Growth And Offset 3D  
z = (a+x)/(b+c*y)
z = z * (d * exp(xy)) + Offset
    Simple Equation 33 With Exponential Growth And Offset 3D  
z = (a+y)/(b+c*x)
z = z * (d * exp(xy)) + Offset
    Simple Equation 34 With Exponential Growth And Offset 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z * (d * exp(xy)) + Offset
    Simple Equation 35 With Exponential Growth And Offset 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z * (d * exp(xy)) + Offset
    Simple Equation 36 With Exponential Growth And Offset 3D  
z = a*(exp(b*x)-exp(c*y))
z = z * exp(xy) + Offset
    Simple Equation 37 With Exponential Growth And Offset 3D  
z = a*pow(x,b*pow(y,c))
z = z * exp(xy) + Offset
    Simple Equation 38 With Exponential Growth And Offset 3D  
z = a*pow(y,b*pow(x,c))
z = z * exp(xy) + Offset
    Simple Equation 39 With Exponential Growth And Offset 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z * (d * exp(xy)) + Offset
    Simple Equation 40 With Exponential Growth And Offset 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z * (d * exp(xy)) + Offset
    Simple Equation 41 With Exponential Growth And Offset 3D  
z = exp(a+b/x+c*ln(y))
z = z * (d * exp(xy)) + Offset
    Simple Equation 42 With Exponential Growth And Offset 3D  
z = exp(a+b/y+c*ln(x))
z = z * (d * exp(xy)) + Offset
    Simple Equation 43 With Exponential Growth And Offset 3D  
z = a*pow(x,b)*ln(y+c)
z = z * exp(xy) + Offset
    Simple Equation 44 With Exponential Growth And Offset 3D  
z = a*pow(y,b)*ln(x+c)
z = z * exp(xy) + Offset
     
     
    Simple Equation 01 With Exponential Growth 3D  
z = a*pow(x,b)*pow(y,c)
z = z * exp(xy)
    Simple Equation 02 With Exponential Growth 3D  
z = x/(a+b*y)
z = z * (c * exp(xy))
    Simple Equation 03 With Exponential Growth 3D  
z = y/(a+b*x)
z = z * (c * exp(xy))
    Simple Equation 04 With Exponential Growth 3D  
z = a*pow(x,b*y)
z = z * exp(xy)
    Simple Equation 05 With Exponential Growth 3D  
z = a*pow(y,b*x)
z = z * exp(xy)
    Simple Equation 06 With Exponential Growth 3D  
z = a*pow(x,b/y)
z = z * exp(xy)
    Simple Equation 07 With Exponential Growth 3D  
z = a*pow(y,b/x)
z = z * exp(xy)
    Simple Equation 08 With Exponential Growth 3D  
z = a*x+b*pow(y,2.0)
z = z * (c * exp(xy))
    Simple Equation 09 With Exponential Growth 3D  
z = a*y+b*pow(x,2.0)
z = z * (c * exp(xy))
    Simple Equation 10 With Exponential Growth 3D  
z = x/(a+b*pow(y,2.0))
z = z * (c * exp(xy))
    Simple Equation 11 With Exponential Growth 3D  
z = y/(a+b*pow(x,2.0))
z = z * (c * exp(xy))
    Simple Equation 12 With Exponential Growth 3D  
z = a*pow(b,x)*pow(y,c)
z = z * exp(xy)
    Simple Equation 13 With Exponential Growth 3D  
z = a*pow(b,y)*pow(x,c)
z = z * exp(xy)
    Simple Equation 14 With Exponential Growth 3D  
z = a*pow(x*y,b)
z = z * exp(xy)
    Simple Equation 15 With Exponential Growth 3D  
z = a*pow(x/y,b)
z = z * exp(xy)
    Simple Equation 16 With Exponential Growth 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z * exp(xy)
    Simple Equation 17 With Exponential Growth 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z * exp(xy)
    Simple Equation 18 With Exponential Growth 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z * exp(xy)
    Simple Equation 19 With Exponential Growth 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z * exp(xy)
    Simple Equation 20 With Exponential Growth 3D  
z = a*pow(x,b+c*y)
z = z * exp(xy)
    Simple Equation 21 With Exponential Growth 3D  
z = a*pow(y,b+c*x)
z = z * exp(xy)
    Simple Equation 22 With Exponential Growth 3D  
z = a*pow(x,b+c/y)
z = z * exp(xy)
    Simple Equation 23 With Exponential Growth 3D  
z = a*pow(y,b+c/x)
z = z * exp(xy)
    Simple Equation 24 With Exponential Growth 3D  
z = a*pow(x,b+c*ln(y))
z = z * exp(xy)
    Simple Equation 25 With Exponential Growth 3D  
z = a*pow(y,b+c*ln(x))
z = z * exp(xy)
    Simple Equation 26 With Exponential Growth 3D  
z = a*pow(y,b+c/ln(x))
z = z * exp(xy)
    Simple Equation 27 With Exponential Growth 3D  
z = a*pow(x,b+c/ln(y))
z = z * exp(xy)
    Simple Equation 28 With Exponential Growth 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z * exp(xy)
    Simple Equation 29 With Exponential Growth 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z * exp(xy)
    Simple Equation 30 With Exponential Growth 3D  
z = a*exp(b/x+c*y)
z = z * exp(xy)
    Simple Equation 31 With Exponential Growth 3D  
z = a*exp(b/y+c*x)
z = z * exp(xy)
    Simple Equation 32 With Exponential Growth 3D  
z = (a+x)/(b+c*y)
z = z * (d * exp(xy))
    Simple Equation 33 With Exponential Growth 3D  
z = (a+y)/(b+c*x)
z = z * (d * exp(xy))
    Simple Equation 34 With Exponential Growth 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z * (d * exp(xy))
    Simple Equation 35 With Exponential Growth 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z * (d * exp(xy))
    Simple Equation 36 With Exponential Growth 3D  
z = a*(exp(b*x)-exp(c*y))
z = z * exp(xy)
    Simple Equation 37 With Exponential Growth 3D  
z = a*pow(x,b*pow(y,c))
z = z * exp(xy)
    Simple Equation 38 With Exponential Growth 3D  
z = a*pow(y,b*pow(x,c))
z = z * exp(xy)
    Simple Equation 39 With Exponential Growth 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z * (d * exp(xy))
    Simple Equation 40 With Exponential Growth 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z * (d * exp(xy))
    Simple Equation 41 With Exponential Growth 3D  
z = exp(a+b/x+c*ln(y))
z = z * (d * exp(xy))
    Simple Equation 42 With Exponential Growth 3D  
z = exp(a+b/y+c*ln(x))
z = z * (d * exp(xy))
    Simple Equation 43 With Exponential Growth 3D  
z = a*pow(x,b)*ln(y+c)
z = z * exp(xy)
    Simple Equation 44 With Exponential Growth 3D  
z = a*pow(y,b)*ln(x+c)
z = z * exp(xy)
     
     
    Inverse Simple Equation 01 3D  
z = a*pow(x,b)*pow(y,c)
z = xy / z
    Inverse Simple Equation 02 3D  
z = x/(a+b*y)
z = xy / z
    Inverse Simple Equation 03 3D  
z = y/(a+b*x)
z = xy / z
    Inverse Simple Equation 04 3D  
z = a*pow(x,b*y)
z = xy / z
    Inverse Simple Equation 05 3D  
z = a*pow(y,b*x)
z = xy / z
    Inverse Simple Equation 06 3D  
z = a*pow(x,b/y)
z = xy / z
    Inverse Simple Equation 07 3D  
z = a*pow(y,b/x)
z = xy / z
    Inverse Simple Equation 08 3D  
z = a*x+b*pow(y,2.0)
z = xy / z
    Inverse Simple Equation 09 3D  
z = a*y+b*pow(x,2.0)
z = xy / z
    Inverse Simple Equation 10 3D  
z = x/(a+b*pow(y,2.0))
z = xy / z
    Inverse Simple Equation 11 3D  
z = y/(a+b*pow(x,2.0))
z = xy / z
    Inverse Simple Equation 12 3D  
z = a*pow(b,x)*pow(y,c)
z = xy / z
    Inverse Simple Equation 13 3D  
z = a*pow(b,y)*pow(x,c)
z = xy / z
    Inverse Simple Equation 14 3D  
z = a*pow(x*y,b)
z = xy / z
    Inverse Simple Equation 15 3D  
z = a*pow(x/y,b)
z = xy / z
    Inverse Simple Equation 16 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = xy / z
    Inverse Simple Equation 17 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = xy / z
    Inverse Simple Equation 18 3D  
z = a*pow(x/b,c)*exp(y/b)
z = xy / z
    Inverse Simple Equation 19 3D  
z = a*pow(y/b,c)*exp(x/b)
z = xy / z
    Inverse Simple Equation 20 3D  
z = a*pow(x,b+c*y)
z = xy / z
    Inverse Simple Equation 21 3D  
z = a*pow(y,b+c*x)
z = xy / z
    Inverse Simple Equation 22 3D  
z = a*pow(x,b+c/y)
z = xy / z
    Inverse Simple Equation 23 3D  
z = a*pow(y,b+c/x)
z = xy / z
    Inverse Simple Equation 24 3D  
z = a*pow(x,b+c*ln(y))
z = xy / z
    Inverse Simple Equation 25 3D  
z = a*pow(y,b+c*ln(x))
z = xy / z
    Inverse Simple Equation 26 3D  
z = a*pow(y,b+c/ln(x))
z = xy / z
    Inverse Simple Equation 27 3D  
z = a*pow(x,b+c/ln(y))
z = xy / z
    Inverse Simple Equation 28 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = xy / z
    Inverse Simple Equation 29 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = xy / z
    Inverse Simple Equation 30 3D  
z = a*exp(b/x+c*y)
z = xy / z
    Inverse Simple Equation 31 3D  
z = a*exp(b/y+c*x)
z = xy / z
    Inverse Simple Equation 32 3D  
z = (a+x)/(b+c*y)
z = xy / z
    Inverse Simple Equation 33 3D  
z = (a+y)/(b+c*x)
z = xy / z
    Inverse Simple Equation 34 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = xy / z
    Inverse Simple Equation 35 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = xy / z
    Inverse Simple Equation 36 3D  
z = a*(exp(b*x)-exp(c*y))
z = xy / z
    Inverse Simple Equation 37 3D  
z = a*pow(x,b*pow(y,c))
z = xy / z
    Inverse Simple Equation 38 3D  
z = a*pow(y,b*pow(x,c))
z = xy / z
    Inverse Simple Equation 39 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = xy / z
    Inverse Simple Equation 40 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = xy / z
    Inverse Simple Equation 41 3D  
z = exp(a+b/x+c*ln(y))
z = xy / z
    Inverse Simple Equation 42 3D  
z = exp(a+b/y+c*ln(x))
z = xy / z
    Inverse Simple Equation 43 3D  
z = a*pow(x,b)*ln(y+c)
z = xy / z
    Inverse Simple Equation 44 3D  
z = a*pow(y,b)*ln(x+c)
z = xy / z
     
     
    Inverse Simple Equation 01 With Offset 3D  
z = a*pow(x,b)*pow(y,c)
z = xy / (z + Offset
    Inverse Simple Equation 02 With Offset 3D  
z = x/(a+b*y)
z = xy / (z + Offset
    Inverse Simple Equation 03 With Offset 3D  
z = y/(a+b*x)
z = xy / (z + Offset
    Inverse Simple Equation 04 With Offset 3D  
z = a*pow(x,b*y)
z = xy / (z + Offset
    Inverse Simple Equation 05 With Offset 3D  
z = a*pow(y,b*x)
z = xy / (z + Offset
    Inverse Simple Equation 06 With Offset 3D  
z = a*pow(x,b/y)
z = xy / (z + Offset
    Inverse Simple Equation 07 With Offset 3D  
z = a*pow(y,b/x)
z = xy / (z + Offset
    Inverse Simple Equation 08 With Offset 3D  
z = a*x+b*pow(y,2.0)
z = xy / (z + Offset
    Inverse Simple Equation 09 With Offset 3D  
z = a*y+b*pow(x,2.0)
z = xy / (z + Offset
    Inverse Simple Equation 10 With Offset 3D  
z = x/(a+b*pow(y,2.0))
z = xy / (z + Offset
    Inverse Simple Equation 11 With Offset 3D  
z = y/(a+b*pow(x,2.0))
z = xy / (z + Offset
    Inverse Simple Equation 12 With Offset 3D  
z = a*pow(b,x)*pow(y,c)
z = xy / (z + Offset
    Inverse Simple Equation 13 With Offset 3D  
z = a*pow(b,y)*pow(x,c)
z = xy / (z + Offset
    Inverse Simple Equation 14 With Offset 3D  
z = a*pow(x*y,b)
z = xy / (z + Offset
    Inverse Simple Equation 15 With Offset 3D  
z = a*pow(x/y,b)
z = xy / (z + Offset
    Inverse Simple Equation 16 With Offset 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = xy / (z + Offset
    Inverse Simple Equation 17 With Offset 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = xy / (z + Offset
    Inverse Simple Equation 18 With Offset 3D  
z = a*pow(x/b,c)*exp(y/b)
z = xy / (z + Offset
    Inverse Simple Equation 19 With Offset 3D  
z = a*pow(y/b,c)*exp(x/b)
z = xy / (z + Offset
    Inverse Simple Equation 20 With Offset 3D  
z = a*pow(x,b+c*y)
z = xy / (z + Offset
    Inverse Simple Equation 21 With Offset 3D  
z = a*pow(y,b+c*x)
z = xy / (z + Offset
    Inverse Simple Equation 22 With Offset 3D  
z = a*pow(x,b+c/y)
z = xy / (z + Offset
    Inverse Simple Equation 23 With Offset 3D  
z = a*pow(y,b+c/x)
z = xy / (z + Offset
    Inverse Simple Equation 24 With Offset 3D  
z = a*pow(x,b+c*ln(y))
z = xy / (z + Offset
    Inverse Simple Equation 25 With Offset 3D  
z = a*pow(y,b+c*ln(x))
z = xy / (z + Offset
    Inverse Simple Equation 26 With Offset 3D  
z = a*pow(y,b+c/ln(x))
z = xy / (z + Offset
    Inverse Simple Equation 27 With Offset 3D  
z = a*pow(x,b+c/ln(y))
z = xy / (z + Offset
    Inverse Simple Equation 28 With Offset 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = xy / (z + Offset
    Inverse Simple Equation 29 With Offset 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = xy / (z + Offset
    Inverse Simple Equation 30 With Offset 3D  
z = a*exp(b/x+c*y)
z = xy / (z + Offset
    Inverse Simple Equation 31 With Offset 3D  
z = a*exp(b/y+c*x)
z = xy / (z + Offset
    Inverse Simple Equation 32 With Offset 3D  
z = (a+x)/(b+c*y)
z = xy / (z + Offset
    Inverse Simple Equation 33 With Offset 3D  
z = (a+y)/(b+c*x)
z = xy / (z + Offset
    Inverse Simple Equation 34 With Offset 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = xy / (z + Offset
    Inverse Simple Equation 35 With Offset 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = xy / (z + Offset
    Inverse Simple Equation 36 With Offset 3D  
z = a*(exp(b*x)-exp(c*y))
z = xy / (z + Offset
    Inverse Simple Equation 37 With Offset 3D  
z = a*pow(x,b*pow(y,c))
z = xy / (z + Offset
    Inverse Simple Equation 38 With Offset 3D  
z = a*pow(y,b*pow(x,c))
z = xy / (z + Offset
    Inverse Simple Equation 39 With Offset 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = xy / (z + Offset
    Inverse Simple Equation 40 With Offset 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = xy / (z + Offset
    Inverse Simple Equation 41 With Offset 3D  
z = exp(a+b/x+c*ln(y))
z = xy / (z + Offset
    Inverse Simple Equation 42 With Offset 3D  
z = exp(a+b/y+c*ln(x))
z = xy / (z + Offset
    Inverse Simple Equation 43 With Offset 3D  
z = a*pow(x,b)*ln(y+c)
z = xy / (z + Offset
    Inverse Simple Equation 44 With Offset 3D  
z = a*pow(y,b)*ln(x+c)
z = xy / (z + Offset
     
     
    Simple Equation 01 With Linear Decay And Offset 3D  
z = a*pow(x,b)*pow(y,c)
z = z / xy + Offset
    Simple Equation 02 With Linear Decay And Offset 3D  
z = x/(a+b*y)
z = z / (c * xy) + Offset
    Simple Equation 03 With Linear Decay And Offset 3D  
z = y/(a+b*x)
z = z / (c * xy) + Offset
    Simple Equation 04 With Linear Decay And Offset 3D  
z = a*pow(x,b*y)
z = z / xy + Offset
    Simple Equation 05 With Linear Decay And Offset 3D  
z = a*pow(y,b*x)
z = z / xy + Offset
    Simple Equation 06 With Linear Decay And Offset 3D  
z = a*pow(x,b/y)
z = z / xy + Offset
    Simple Equation 07 With Linear Decay And Offset 3D  
z = a*pow(y,b/x)
z = z / xy + Offset
    Simple Equation 08 With Linear Decay And Offset 3D  
z = a*x+b*pow(y,2.0)
z = z / (c * xy) + Offset
    Simple Equation 09 With Linear Decay And Offset 3D  
z = a*y+b*pow(x,2.0)
z = z / (c * xy) + Offset
    Simple Equation 10 With Linear Decay And Offset 3D  
z = x/(a+b*pow(y,2.0))
z = z / (c * xy) + Offset
    Simple Equation 11 With Linear Decay And Offset 3D  
z = y/(a+b*pow(x,2.0))
z = z / (c * xy) + Offset
    Simple Equation 12 With Linear Decay And Offset 3D  
z = a*pow(b,x)*pow(y,c)
z = z / xy + Offset
    Simple Equation 13 With Linear Decay And Offset 3D  
z = a*pow(b,y)*pow(x,c)
z = z / xy + Offset
    Simple Equation 14 With Linear Decay And Offset 3D  
z = a*pow(x*y,b)
z = z / xy + Offset
    Simple Equation 15 With Linear Decay And Offset 3D  
z = a*pow(x/y,b)
z = z / xy + Offset
    Simple Equation 16 With Linear Decay And Offset 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z / xy + Offset
    Simple Equation 17 With Linear Decay And Offset 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z / xy + Offset
    Simple Equation 18 With Linear Decay And Offset 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z / xy + Offset
    Simple Equation 19 With Linear Decay And Offset 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z / xy + Offset
    Simple Equation 20 With Linear Decay And Offset 3D  
z = a*pow(x,b+c*y)
z = z / xy + Offset
    Simple Equation 21 With Linear Decay And Offset 3D  
z = a*pow(y,b+c*x)
z = z / xy + Offset
    Simple Equation 22 With Linear Decay And Offset 3D  
z = a*pow(x,b+c/y)
z = z / xy + Offset
    Simple Equation 23 With Linear Decay And Offset 3D  
z = a*pow(y,b+c/x)
z = z / xy + Offset
    Simple Equation 24 With Linear Decay And Offset 3D  
z = a*pow(x,b+c*ln(y))
z = z / xy + Offset
    Simple Equation 25 With Linear Decay And Offset 3D  
z = a*pow(y,b+c*ln(x))
z = z / xy + Offset
    Simple Equation 26 With Linear Decay And Offset 3D  
z = a*pow(y,b+c/ln(x))
z = z / xy + Offset
    Simple Equation 27 With Linear Decay And Offset 3D  
z = a*pow(x,b+c/ln(y))
z = z / xy + Offset
    Simple Equation 28 With Linear Decay And Offset 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z / xy + Offset
    Simple Equation 29 With Linear Decay And Offset 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z / xy + Offset
    Simple Equation 30 With Linear Decay And Offset 3D  
z = a*exp(b/x+c*y)
z = z / xy + Offset
    Simple Equation 31 With Linear Decay And Offset 3D  
z = a*exp(b/y+c*x)
z = z / xy + Offset
    Simple Equation 32 With Linear Decay And Offset 3D  
z = (a+x)/(b+c*y)
z = z / (d * xy) + Offset
    Simple Equation 33 With Linear Decay And Offset 3D  
z = (a+y)/(b+c*x)
z = z / (d * xy) + Offset
    Simple Equation 34 With Linear Decay And Offset 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z / (d * xy) + Offset
    Simple Equation 35 With Linear Decay And Offset 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z / (d * xy) + Offset
    Simple Equation 36 With Linear Decay And Offset 3D  
z = a*(exp(b*x)-exp(c*y))
z = z / xy + Offset
    Simple Equation 37 With Linear Decay And Offset 3D  
z = a*pow(x,b*pow(y,c))
z = z / xy + Offset
    Simple Equation 38 With Linear Decay And Offset 3D  
z = a*pow(y,b*pow(x,c))
z = z / xy + Offset
    Simple Equation 39 With Linear Decay And Offset 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z / (d * xy) + Offset
    Simple Equation 40 With Linear Decay And Offset 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z / (d * xy) + Offset
    Simple Equation 41 With Linear Decay And Offset 3D  
z = exp(a+b/x+c*ln(y))
z = z / (d * xy) + Offset
    Simple Equation 42 With Linear Decay And Offset 3D  
z = exp(a+b/y+c*ln(x))
z = z / (d * xy) + Offset
    Simple Equation 43 With Linear Decay And Offset 3D  
z = a*pow(x,b)*ln(y+c)
z = z / xy + Offset
    Simple Equation 44 With Linear Decay And Offset 3D  
z = a*pow(y,b)*ln(x+c)
z = z / xy + Offset
     
     
    Simple Equation 01 With Linear Decay 3D  
z = a*pow(x,b)*pow(y,c)
z = z / xy
    Simple Equation 02 With Linear Decay 3D  
z = x/(a+b*y)
z = z / (c * xy)
    Simple Equation 03 With Linear Decay 3D  
z = y/(a+b*x)
z = z / (c * xy)
    Simple Equation 04 With Linear Decay 3D  
z = a*pow(x,b*y)
z = z / xy
    Simple Equation 05 With Linear Decay 3D  
z = a*pow(y,b*x)
z = z / xy
    Simple Equation 06 With Linear Decay 3D  
z = a*pow(x,b/y)
z = z / xy
    Simple Equation 07 With Linear Decay 3D  
z = a*pow(y,b/x)
z = z / xy
    Simple Equation 08 With Linear Decay 3D  
z = a*x+b*pow(y,2.0)
z = z / (c * xy)
    Simple Equation 09 With Linear Decay 3D  
z = a*y+b*pow(x,2.0)
z = z / (c * xy)
    Simple Equation 10 With Linear Decay 3D  
z = x/(a+b*pow(y,2.0))
z = z / (c * xy)
    Simple Equation 11 With Linear Decay 3D  
z = y/(a+b*pow(x,2.0))
z = z / (c * xy)
    Simple Equation 12 With Linear Decay 3D  
z = a*pow(b,x)*pow(y,c)
z = z / xy
    Simple Equation 13 With Linear Decay 3D  
z = a*pow(b,y)*pow(x,c)
z = z / xy
    Simple Equation 14 With Linear Decay 3D  
z = a*pow(x*y,b)
z = z / xy
    Simple Equation 15 With Linear Decay 3D  
z = a*pow(x/y,b)
z = z / xy
    Simple Equation 16 With Linear Decay 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z / xy
    Simple Equation 17 With Linear Decay 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z / xy
    Simple Equation 18 With Linear Decay 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z / xy
    Simple Equation 19 With Linear Decay 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z / xy
    Simple Equation 20 With Linear Decay 3D  
z = a*pow(x,b+c*y)
z = z / xy
    Simple Equation 21 With Linear Decay 3D  
z = a*pow(y,b+c*x)
z = z / xy
    Simple Equation 22 With Linear Decay 3D  
z = a*pow(x,b+c/y)
z = z / xy
    Simple Equation 23 With Linear Decay 3D  
z = a*pow(y,b+c/x)
z = z / xy
    Simple Equation 24 With Linear Decay 3D  
z = a*pow(x,b+c*ln(y))
z = z / xy
    Simple Equation 25 With Linear Decay 3D  
z = a*pow(y,b+c*ln(x))
z = z / xy
    Simple Equation 26 With Linear Decay 3D  
z = a*pow(y,b+c/ln(x))
z = z / xy
    Simple Equation 27 With Linear Decay 3D  
z = a*pow(x,b+c/ln(y))
z = z / xy
    Simple Equation 28 With Linear Decay 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z / xy
    Simple Equation 29 With Linear Decay 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z / xy
    Simple Equation 30 With Linear Decay 3D  
z = a*exp(b/x+c*y)
z = z / xy
    Simple Equation 31 With Linear Decay 3D  
z = a*exp(b/y+c*x)
z = z / xy
    Simple Equation 32 With Linear Decay 3D  
z = (a+x)/(b+c*y)
z = z / (d * xy)
    Simple Equation 33 With Linear Decay 3D  
z = (a+y)/(b+c*x)
z = z / (d * xy)
    Simple Equation 34 With Linear Decay 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z / (d * xy)
    Simple Equation 35 With Linear Decay 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z / (d * xy)
    Simple Equation 36 With Linear Decay 3D  
z = a*(exp(b*x)-exp(c*y))
z = z / xy
    Simple Equation 37 With Linear Decay 3D  
z = a*pow(x,b*pow(y,c))
z = z / xy
    Simple Equation 38 With Linear Decay 3D  
z = a*pow(y,b*pow(x,c))
z = z / xy
    Simple Equation 39 With Linear Decay 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z / (d * xy)
    Simple Equation 40 With Linear Decay 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z / (d * xy)
    Simple Equation 41 With Linear Decay 3D  
z = exp(a+b/x+c*ln(y))
z = z / (d * xy)
    Simple Equation 42 With Linear Decay 3D  
z = exp(a+b/y+c*ln(x))
z = z / (d * xy)
    Simple Equation 43 With Linear Decay 3D  
z = a*pow(x,b)*ln(y+c)
z = z / xy
    Simple Equation 44 With Linear Decay 3D  
z = a*pow(y,b)*ln(x+c)
z = z / xy
     
     
    Simple Equation 01 With Linear Growth And Offset 3D  
z = a*pow(x,b)*pow(y,c)
z = z * xy + Offset
    Simple Equation 02 With Linear Growth And Offset 3D  
z = x/(a+b*y)
z = z * (c * xy) + Offset
    Simple Equation 03 With Linear Growth And Offset 3D  
z = y/(a+b*x)
z = z * (c * xy) + Offset
    Simple Equation 04 With Linear Growth And Offset 3D  
z = a*pow(x,b*y)
z = z * xy + Offset
    Simple Equation 05 With Linear Growth And Offset 3D  
z = a*pow(y,b*x)
z = z * xy + Offset
    Simple Equation 06 With Linear Growth And Offset 3D  
z = a*pow(x,b/y)
z = z * xy + Offset
    Simple Equation 07 With Linear Growth And Offset 3D  
z = a*pow(y,b/x)
z = z * xy + Offset
    Simple Equation 08 With Linear Growth And Offset 3D  
z = a*x+b*pow(y,2.0)
z = z * (c * xy) + Offset
    Simple Equation 09 With Linear Growth And Offset 3D  
z = a*y+b*pow(x,2.0)
z = z * (c * xy) + Offset
    Simple Equation 10 With Linear Growth And Offset 3D  
z = x/(a+b*pow(y,2.0))
z = z * (c * xy) + Offset
    Simple Equation 11 With Linear Growth And Offset 3D  
z = y/(a+b*pow(x,2.0))
z = z * (c * xy) + Offset
    Simple Equation 12 With Linear Growth And Offset 3D  
z = a*pow(b,x)*pow(y,c)
z = z * xy + Offset
    Simple Equation 13 With Linear Growth And Offset 3D  
z = a*pow(b,y)*pow(x,c)
z = z * xy + Offset
    Simple Equation 14 With Linear Growth And Offset 3D  
z = a*pow(x*y,b)
z = z * xy + Offset
    Simple Equation 15 With Linear Growth And Offset 3D  
z = a*pow(x/y,b)
z = z * xy + Offset
    Simple Equation 16 With Linear Growth And Offset 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z * xy + Offset
    Simple Equation 17 With Linear Growth And Offset 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z * xy + Offset
    Simple Equation 18 With Linear Growth And Offset 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z * xy + Offset
    Simple Equation 19 With Linear Growth And Offset 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z * xy + Offset
    Simple Equation 20 With Linear Growth And Offset 3D  
z = a*pow(x,b+c*y)
z = z * xy + Offset
    Simple Equation 21 With Linear Growth And Offset 3D  
z = a*pow(y,b+c*x)
z = z * xy + Offset
    Simple Equation 22 With Linear Growth And Offset 3D  
z = a*pow(x,b+c/y)
z = z * xy + Offset
    Simple Equation 23 With Linear Growth And Offset 3D  
z = a*pow(y,b+c/x)
z = z * xy + Offset
    Simple Equation 24 With Linear Growth And Offset 3D  
z = a*pow(x,b+c*ln(y))
z = z * xy + Offset
    Simple Equation 25 With Linear Growth And Offset 3D  
z = a*pow(y,b+c*ln(x))
z = z * xy + Offset
    Simple Equation 26 With Linear Growth And Offset 3D  
z = a*pow(y,b+c/ln(x))
z = z * xy + Offset
    Simple Equation 27 With Linear Growth And Offset 3D  
z = a*pow(x,b+c/ln(y))
z = z * xy + Offset
    Simple Equation 28 With Linear Growth And Offset 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z * xy + Offset
    Simple Equation 29 With Linear Growth And Offset 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z * xy + Offset
    Simple Equation 30 With Linear Growth And Offset 3D  
z = a*exp(b/x+c*y)
z = z * xy + Offset
    Simple Equation 31 With Linear Growth And Offset 3D  
z = a*exp(b/y+c*x)
z = z * xy + Offset
    Simple Equation 32 With Linear Growth And Offset 3D  
z = (a+x)/(b+c*y)
z = z * (d * xy) + Offset
    Simple Equation 33 With Linear Growth And Offset 3D  
z = (a+y)/(b+c*x)
z = z * (d * xy) + Offset
    Simple Equation 34 With Linear Growth And Offset 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z * (d * xy) + Offset
    Simple Equation 35 With Linear Growth And Offset 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z * (d * xy) + Offset
    Simple Equation 36 With Linear Growth And Offset 3D  
z = a*(exp(b*x)-exp(c*y))
z = z * xy + Offset
    Simple Equation 37 With Linear Growth And Offset 3D  
z = a*pow(x,b*pow(y,c))
z = z * xy + Offset
    Simple Equation 38 With Linear Growth And Offset 3D  
z = a*pow(y,b*pow(x,c))
z = z * xy + Offset
    Simple Equation 39 With Linear Growth And Offset 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z * (d * xy) + Offset
    Simple Equation 40 With Linear Growth And Offset 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z * (d * xy) + Offset
    Simple Equation 41 With Linear Growth And Offset 3D  
z = exp(a+b/x+c*ln(y))
z = z * (d * xy) + Offset
    Simple Equation 42 With Linear Growth And Offset 3D  
z = exp(a+b/y+c*ln(x))
z = z * (d * xy) + Offset
    Simple Equation 43 With Linear Growth And Offset 3D  
z = a*pow(x,b)*ln(y+c)
z = z * xy + Offset
    Simple Equation 44 With Linear Growth And Offset 3D  
z = a*pow(y,b)*ln(x+c)
z = z * xy + Offset
     
     
    Simple Equation 01 With Linear Growth 3D  
z = a*pow(x,b)*pow(y,c)
z = z * xy
    Simple Equation 02 With Linear Growth 3D  
z = x/(a+b*y)
z = z * (c * xy)
    Simple Equation 03 With Linear Growth 3D  
z = y/(a+b*x)
z = z * (c * xy)
    Simple Equation 04 With Linear Growth 3D  
z = a*pow(x,b*y)
z = z * xy
    Simple Equation 05 With Linear Growth 3D  
z = a*pow(y,b*x)
z = z * xy
    Simple Equation 06 With Linear Growth 3D  
z = a*pow(x,b/y)
z = z * xy
    Simple Equation 07 With Linear Growth 3D  
z = a*pow(y,b/x)
z = z * xy
    Simple Equation 08 With Linear Growth 3D  
z = a*x+b*pow(y,2.0)
z = z * (c * xy)
    Simple Equation 09 With Linear Growth 3D  
z = a*y+b*pow(x,2.0)
z = z * (c * xy)
    Simple Equation 10 With Linear Growth 3D  
z = x/(a+b*pow(y,2.0))
z = z * (c * xy)
    Simple Equation 11 With Linear Growth 3D  
z = y/(a+b*pow(x,2.0))
z = z * (c * xy)
    Simple Equation 12 With Linear Growth 3D  
z = a*pow(b,x)*pow(y,c)
z = z * xy
    Simple Equation 13 With Linear Growth 3D  
z = a*pow(b,y)*pow(x,c)
z = z * xy
    Simple Equation 14 With Linear Growth 3D  
z = a*pow(x*y,b)
z = z * xy
    Simple Equation 15 With Linear Growth 3D  
z = a*pow(x/y,b)
z = z * xy
    Simple Equation 16 With Linear Growth 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z * xy
    Simple Equation 17 With Linear Growth 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z * xy
    Simple Equation 18 With Linear Growth 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z * xy
    Simple Equation 19 With Linear Growth 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z * xy
    Simple Equation 20 With Linear Growth 3D  
z = a*pow(x,b+c*y)
z = z * xy
    Simple Equation 21 With Linear Growth 3D  
z = a*pow(y,b+c*x)
z = z * xy
    Simple Equation 22 With Linear Growth 3D  
z = a*pow(x,b+c/y)
z = z * xy
    Simple Equation 23 With Linear Growth 3D  
z = a*pow(y,b+c/x)
z = z * xy
    Simple Equation 24 With Linear Growth 3D  
z = a*pow(x,b+c*ln(y))
z = z * xy
    Simple Equation 25 With Linear Growth 3D  
z = a*pow(y,b+c*ln(x))
z = z * xy
    Simple Equation 26 With Linear Growth 3D  
z = a*pow(y,b+c/ln(x))
z = z * xy
    Simple Equation 27 With Linear Growth 3D  
z = a*pow(x,b+c/ln(y))
z = z * xy
    Simple Equation 28 With Linear Growth 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z * xy
    Simple Equation 29 With Linear Growth 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z * xy
    Simple Equation 30 With Linear Growth 3D  
z = a*exp(b/x+c*y)
z = z * xy
    Simple Equation 31 With Linear Growth 3D  
z = a*exp(b/y+c*x)
z = z * xy
    Simple Equation 32 With Linear Growth 3D  
z = (a+x)/(b+c*y)
z = z * (d * xy)
    Simple Equation 33 With Linear Growth 3D  
z = (a+y)/(b+c*x)
z = z * (d * xy)
    Simple Equation 34 With Linear Growth 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z * (d * xy)
    Simple Equation 35 With Linear Growth 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z * (d * xy)
    Simple Equation 36 With Linear Growth 3D  
z = a*(exp(b*x)-exp(c*y))
z = z * xy
    Simple Equation 37 With Linear Growth 3D  
z = a*pow(x,b*pow(y,c))
z = z * xy
    Simple Equation 38 With Linear Growth 3D  
z = a*pow(y,b*pow(x,c))
z = z * xy
    Simple Equation 39 With Linear Growth 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z * (d * xy)
    Simple Equation 40 With Linear Growth 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z * (d * xy)
    Simple Equation 41 With Linear Growth 3D  
z = exp(a+b/x+c*ln(y))
z = z * (d * xy)
    Simple Equation 42 With Linear Growth 3D  
z = exp(a+b/y+c*ln(x))
z = z * (d * xy)
    Simple Equation 43 With Linear Growth 3D  
z = a*pow(x,b)*ln(y+c)
z = z * xy
    Simple Equation 44 With Linear Growth 3D  
z = a*pow(y,b)*ln(x+c)
z = z * xy
     
     
    Reciprocal Simple Equation 01 3D  
z = a*pow(x,b)*pow(y,c)
z = 1.0 / z
    Reciprocal Simple Equation 02 3D  
z = x/(a+b*y)
z = 1.0 / z
    Reciprocal Simple Equation 03 3D  
z = y/(a+b*x)
z = 1.0 / z
    Reciprocal Simple Equation 04 3D  
z = a*pow(x,b*y)
z = 1.0 / z
    Reciprocal Simple Equation 05 3D  
z = a*pow(y,b*x)
z = 1.0 / z
    Reciprocal Simple Equation 06 3D  
z = a*pow(x,b/y)
z = 1.0 / z
    Reciprocal Simple Equation 07 3D  
z = a*pow(y,b/x)
z = 1.0 / z
    Reciprocal Simple Equation 08 3D  
z = a*x+b*pow(y,2.0)
z = 1.0 / z
    Reciprocal Simple Equation 09 3D  
z = a*y+b*pow(x,2.0)
z = 1.0 / z
    Reciprocal Simple Equation 10 3D  
z = x/(a+b*pow(y,2.0))
z = 1.0 / z
    Reciprocal Simple Equation 11 3D  
z = y/(a+b*pow(x,2.0))
z = 1.0 / z
    Reciprocal Simple Equation 12 3D  
z = a*pow(b,x)*pow(y,c)
z = 1.0 / z
    Reciprocal Simple Equation 13 3D  
z = a*pow(b,y)*pow(x,c)
z = 1.0 / z
    Reciprocal Simple Equation 14 3D  
z = a*pow(x*y,b)
z = 1.0 / z
    Reciprocal Simple Equation 15 3D  
z = a*pow(x/y,b)
z = 1.0 / z
    Reciprocal Simple Equation 16 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = 1.0 / z
    Reciprocal Simple Equation 17 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = 1.0 / z
    Reciprocal Simple Equation 18 3D  
z = a*pow(x/b,c)*exp(y/b)
z = 1.0 / z
    Reciprocal Simple Equation 19 3D  
z = a*pow(y/b,c)*exp(x/b)
z = 1.0 / z
    Reciprocal Simple Equation 20 3D  
z = a*pow(x,b+c*y)
z = 1.0 / z
    Reciprocal Simple Equation 21 3D  
z = a*pow(y,b+c*x)
z = 1.0 / z
    Reciprocal Simple Equation 22 3D  
z = a*pow(x,b+c/y)
z = 1.0 / z
    Reciprocal Simple Equation 23 3D  
z = a*pow(y,b+c/x)
z = 1.0 / z
    Reciprocal Simple Equation 24 3D  
z = a*pow(x,b+c*ln(y))
z = 1.0 / z
    Reciprocal Simple Equation 25 3D  
z = a*pow(y,b+c*ln(x))
z = 1.0 / z
    Reciprocal Simple Equation 26 3D  
z = a*pow(y,b+c/ln(x))
z = 1.0 / z
    Reciprocal Simple Equation 27 3D  
z = a*pow(x,b+c/ln(y))
z = 1.0 / z
    Reciprocal Simple Equation 28 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = 1.0 / z
    Reciprocal Simple Equation 29 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = 1.0 / z
    Reciprocal Simple Equation 30 3D  
z = a*exp(b/x+c*y)
z = 1.0 / z
    Reciprocal Simple Equation 31 3D  
z = a*exp(b/y+c*x)
z = 1.0 / z
    Reciprocal Simple Equation 32 3D  
z = (a+x)/(b+c*y)
z = 1.0 / z
    Reciprocal Simple Equation 33 3D  
z = (a+y)/(b+c*x)
z = 1.0 / z
    Reciprocal Simple Equation 34 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = 1.0 / z
    Reciprocal Simple Equation 35 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = 1.0 / z
    Reciprocal Simple Equation 36 3D  
z = a*(exp(b*x)-exp(c*y))
z = 1.0 / z
    Reciprocal Simple Equation 37 3D  
z = a*pow(x,b*pow(y,c))
z = 1.0 / z
    Reciprocal Simple Equation 38 3D  
z = a*pow(y,b*pow(x,c))
z = 1.0 / z
    Reciprocal Simple Equation 39 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = 1.0 / z
    Reciprocal Simple Equation 40 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = 1.0 / z
    Reciprocal Simple Equation 41 3D  
z = exp(a+b/x+c*ln(y))
z = 1.0 / z
    Reciprocal Simple Equation 42 3D  
z = exp(a+b/y+c*ln(x))
z = 1.0 / z
    Reciprocal Simple Equation 43 3D  
z = a*pow(x,b)*ln(y+c)
z = 1.0 / z
    Reciprocal Simple Equation 44 3D  
z = a*pow(y,b)*ln(x+c)
z = 1.0 / z
     
     
    Reciprocal Simple Equation 01 With Offset 3D  
z = a*pow(x,b)*pow(y,c)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 02 With Offset 3D  
z = x/(a+b*y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 03 With Offset 3D  
z = y/(a+b*x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 04 With Offset 3D  
z = a*pow(x,b*y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 05 With Offset 3D  
z = a*pow(y,b*x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 06 With Offset 3D  
z = a*pow(x,b/y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 07 With Offset 3D  
z = a*pow(y,b/x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 08 With Offset 3D  
z = a*x+b*pow(y,2.0)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 09 With Offset 3D  
z = a*y+b*pow(x,2.0)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 10 With Offset 3D  
z = x/(a+b*pow(y,2.0))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 11 With Offset 3D  
z = y/(a+b*pow(x,2.0))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 12 With Offset 3D  
z = a*pow(b,x)*pow(y,c)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 13 With Offset 3D  
z = a*pow(b,y)*pow(x,c)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 14 With Offset 3D  
z = a*pow(x*y,b)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 15 With Offset 3D  
z = a*pow(x/y,b)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 16 With Offset 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 17 With Offset 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 18 With Offset 3D  
z = a*pow(x/b,c)*exp(y/b)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 19 With Offset 3D  
z = a*pow(y/b,c)*exp(x/b)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 20 With Offset 3D  
z = a*pow(x,b+c*y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 21 With Offset 3D  
z = a*pow(y,b+c*x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 22 With Offset 3D  
z = a*pow(x,b+c/y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 23 With Offset 3D  
z = a*pow(y,b+c/x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 24 With Offset 3D  
z = a*pow(x,b+c*ln(y))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 25 With Offset 3D  
z = a*pow(y,b+c*ln(x))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 26 With Offset 3D  
z = a*pow(y,b+c/ln(x))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 27 With Offset 3D  
z = a*pow(x,b+c/ln(y))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 28 With Offset 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 29 With Offset 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 30 With Offset 3D  
z = a*exp(b/x+c*y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 31 With Offset 3D  
z = a*exp(b/y+c*x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 32 With Offset 3D  
z = (a+x)/(b+c*y)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 33 With Offset 3D  
z = (a+y)/(b+c*x)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 34 With Offset 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 35 With Offset 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 36 With Offset 3D  
z = a*(exp(b*x)-exp(c*y))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 37 With Offset 3D  
z = a*pow(x,b*pow(y,c))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 38 With Offset 3D  
z = a*pow(y,b*pow(x,c))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 39 With Offset 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 40 With Offset 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 41 With Offset 3D  
z = exp(a+b/x+c*ln(y))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 42 With Offset 3D  
z = exp(a+b/y+c*ln(x))
z = 1.0 / z + Offset
    Reciprocal Simple Equation 43 With Offset 3D  
z = a*pow(x,b)*ln(y+c)
z = 1.0 / z + Offset
    Reciprocal Simple Equation 44 With Offset 3D  
z = a*pow(y,b)*ln(x+c)
z = 1.0 / z + Offset
     
     
    Simple Equation 01 3D   z = a*pow(x,b)*pow(y,c)
    Simple Equation 02 3D   z = x/(a+b*y)
    Simple Equation 03 3D   z = y/(a+b*x)
    Simple Equation 04 3D   z = a*pow(x,b*y)
    Simple Equation 05 3D   z = a*pow(y,b*x)
    Simple Equation 06 3D   z = a*pow(x,b/y)
    Simple Equation 07 3D   z = a*pow(y,b/x)
    Simple Equation 08 3D   z = a*x+b*pow(y,2.0)
    Simple Equation 09 3D   z = a*y+b*pow(x,2.0)
    Simple Equation 10 3D   z = x/(a+b*pow(y,2.0))
    Simple Equation 11 3D   z = y/(a+b*pow(x,2.0))
    Simple Equation 12 3D   z = a*pow(b,x)*pow(y,c)
    Simple Equation 13 3D   z = a*pow(b,y)*pow(x,c)
    Simple Equation 14 3D   z = a*pow(x*y,b)
    Simple Equation 15 3D   z = a*pow(x/y,b)
    Simple Equation 16 3D   z = a*(pow(b,1.0/x))*pow(y,c)
    Simple Equation 17 3D   z = a*pow(b,1.0/y)*pow(x,c)
    Simple Equation 18 3D   z = a*pow(x/b,c)*exp(y/b)
    Simple Equation 19 3D   z = a*pow(y/b,c)*exp(x/b)
    Simple Equation 20 3D   z = a*pow(x,b+c*y)
    Simple Equation 21 3D   z = a*pow(y,b+c*x)
    Simple Equation 22 3D   z = a*pow(x,b+c/y)
    Simple Equation 23 3D   z = a*pow(y,b+c/x)
    Simple Equation 24 3D   z = a*pow(x,b+c*ln(y))
    Simple Equation 25 3D   z = a*pow(y,b+c*ln(x))
    Simple Equation 26 3D   z = a*pow(y,b+c/ln(x))
    Simple Equation 27 3D   z = a*pow(x,b+c/ln(y))
    Simple Equation 28 3D   z = a*exp(b*x+c*pow(y,2.0))
    Simple Equation 29 3D   z = a*exp(b*y+c*pow(x,2.0))
    Simple Equation 30 3D   z = a*exp(b/x+c*y)
    Simple Equation 31 3D   z = a*exp(b/y+c*x)
    Simple Equation 32 3D   z = (a+x)/(b+c*y)
    Simple Equation 33 3D   z = (a+y)/(b+c*x)
    Simple Equation 34 3D   z = (a+x)/(b+c*pow(y,2.0))
    Simple Equation 35 3D   z = (a+y)/(b+c*pow(x,2.0))
    Simple Equation 36 3D   z = a*(exp(b*x)-exp(c*y))
    Simple Equation 37 3D   z = a*pow(x,b*pow(y,c))
    Simple Equation 38 3D   z = a*pow(y,b*pow(x,c))
    Simple Equation 39 3D   z = x/(a+b*y+c*pow(y,0.5))
    Simple Equation 40 3D   z = y/(a+b*x+c*pow(x,0.5))
    Simple Equation 41 3D   z = exp(a+b/x+c*ln(y))
    Simple Equation 42 3D   z = exp(a+b/y+c*ln(x))
    Simple Equation 43 3D   z = a*pow(x,b)*ln(y+c)
    Simple Equation 44 3D   z = a*pow(y,b)*ln(x+c)
     
     
    Simple Equation 01 With Offset 3D   z = a*pow(x,b)*pow(y,c) + Offset
    Simple Equation 02 With Offset 3D   z = x/(a+b*y) + Offset
    Simple Equation 03 With Offset 3D   z = y/(a+b*x) + Offset
    Simple Equation 04 With Offset 3D   z = a*pow(x,b*y) + Offset
    Simple Equation 05 With Offset 3D   z = a*pow(y,b*x) + Offset
    Simple Equation 06 With Offset 3D   z = a*pow(x,b/y) + Offset
    Simple Equation 07 With Offset 3D   z = a*pow(y,b/x) + Offset
    Simple Equation 08 With Offset 3D   z = a*x+b*pow(y,2.0) + Offset
    Simple Equation 09 With Offset 3D   z = a*y+b*pow(x,2.0) + Offset
    Simple Equation 10 With Offset 3D   z = x/(a+b*pow(y,2.0)) + Offset
    Simple Equation 11 With Offset 3D   z = y/(a+b*pow(x,2.0)) + Offset
    Simple Equation 12 With Offset 3D   z = a*pow(b,x)*pow(y,c) + Offset
    Simple Equation 13 With Offset 3D   z = a*pow(b,y)*pow(x,c) + Offset
    Simple Equation 14 With Offset 3D   z = a*pow(x*y,b) + Offset
    Simple Equation 15 With Offset 3D   z = a*pow(x/y,b) + Offset
    Simple Equation 16 With Offset 3D   z = a*(pow(b,1.0/x))*pow(y,c) + Offset
    Simple Equation 17 With Offset 3D   z = a*pow(b,1.0/y)*pow(x,c) + Offset
    Simple Equation 18 With Offset 3D   z = a*pow(x/b,c)*exp(y/b) + Offset
    Simple Equation 19 With Offset 3D   z = a*pow(y/b,c)*exp(x/b) + Offset
    Simple Equation 20 With Offset 3D   z = a*pow(x,b+c*y) + Offset
    Simple Equation 21 With Offset 3D   z = a*pow(y,b+c*x) + Offset
    Simple Equation 22 With Offset 3D   z = a*pow(x,b+c/y) + Offset
    Simple Equation 23 With Offset 3D   z = a*pow(y,b+c/x) + Offset
    Simple Equation 24 With Offset 3D   z = a*pow(x,b+c*ln(y)) + Offset
    Simple Equation 25 With Offset 3D   z = a*pow(y,b+c*ln(x)) + Offset
    Simple Equation 26 With Offset 3D   z = a*pow(y,b+c/ln(x)) + Offset
    Simple Equation 27 With Offset 3D   z = a*pow(x,b+c/ln(y)) + Offset
    Simple Equation 28 With Offset 3D   z = a*exp(b*x+c*pow(y,2.0)) + Offset
    Simple Equation 29 With Offset 3D   z = a*exp(b*y+c*pow(x,2.0)) + Offset
    Simple Equation 30 With Offset 3D   z = a*exp(b/x+c*y) + Offset
    Simple Equation 31 With Offset 3D   z = a*exp(b/y+c*x) + Offset
    Simple Equation 32 With Offset 3D   z = (a+x)/(b+c*y) + Offset
    Simple Equation 33 With Offset 3D   z = (a+y)/(b+c*x) + Offset
    Simple Equation 34 With Offset 3D   z = (a+x)/(b+c*pow(y,2.0)) + Offset
    Simple Equation 35 With Offset 3D   z = (a+y)/(b+c*pow(x,2.0)) + Offset
    Simple Equation 36 With Offset 3D   z = a*(exp(b*x)-exp(c*y)) + Offset
    Simple Equation 37 With Offset 3D   z = a*pow(x,b*pow(y,c)) + Offset
    Simple Equation 38 With Offset 3D   z = a*pow(y,b*pow(x,c)) + Offset
    Simple Equation 39 With Offset 3D   z = x/(a+b*y+c*pow(y,0.5)) + Offset
    Simple Equation 40 With Offset 3D   z = y/(a+b*x+c*pow(x,0.5)) + Offset
    Simple Equation 41 With Offset 3D   z = exp(a+b/x+c*ln(y)) + Offset
    Simple Equation 42 With Offset 3D   z = exp(a+b/y+c*ln(x)) + Offset
    Simple Equation 43 With Offset 3D   z = a*pow(x,b)*ln(y+c) + Offset
    Simple Equation 44 With Offset 3D   z = a*pow(y,b)*ln(x+c) + Offset
     
     
    Simple Equation 01 Plus Plane 3D  
z = a*pow(x,b)*pow(y,c)
z = z + (d * x) + (f * y) + g
    Simple Equation 02 Plus Plane 3D  
z = x/(a+b*y)
z = z + (c * x) + (d * y) + f
    Simple Equation 03 Plus Plane 3D  
z = y/(a+b*x)
z = z + (c * x) + (d * y) + f
    Simple Equation 04 Plus Plane 3D  
z = a*pow(x,b*y)
z = z + (c * x) + (d * y) + f
    Simple Equation 05 Plus Plane 3D  
z = a*pow(y,b*x)
z = z + (c * x) + (d * y) + f
    Simple Equation 06 Plus Plane 3D  
z = a*pow(x,b/y)
z = z + (c * x) + (d * y) + f
    Simple Equation 07 Plus Plane 3D  
z = a*pow(y,b/x)
z = z + (c * x) + (d * y) + f
    Simple Equation 08 Plus Plane 3D  
z = a*x+b*pow(y,2.0)
z = z + (c * x) + (d * y) + f
    Simple Equation 09 Plus Plane 3D  
z = a*y+b*pow(x,2.0)
z = z + (c * x) + (d * y) + f
    Simple Equation 10 Plus Plane 3D  
z = x/(a+b*pow(y,2.0))
z = z + (c * x) + (d * y) + f
    Simple Equation 11 Plus Plane 3D  
z = y/(a+b*pow(x,2.0))
z = z + (c * x) + (d * y) + f
    Simple Equation 12 Plus Plane 3D  
z = a*pow(b,x)*pow(y,c)
z = z + (d * x) + (f * y) + g
    Simple Equation 13 Plus Plane 3D  
z = a*pow(b,y)*pow(x,c)
z = z + (d * x) + (f * y) + g
    Simple Equation 14 Plus Plane 3D  
z = a*pow(x*y,b)
z = z + (c * x) + (d * y) + f
    Simple Equation 15 Plus Plane 3D  
z = a*pow(x/y,b)
z = z + (c * x) + (d * y) + f
    Simple Equation 16 Plus Plane 3D  
z = a*(pow(b,1.0/x))*pow(y,c)
z = z + (d * x) + (f * y) + g
    Simple Equation 17 Plus Plane 3D  
z = a*pow(b,1.0/y)*pow(x,c)
z = z + (d * x) + (f * y) + g
    Simple Equation 18 Plus Plane 3D  
z = a*pow(x/b,c)*exp(y/b)
z = z + (d * x) + (f * y) + g
    Simple Equation 19 Plus Plane 3D  
z = a*pow(y/b,c)*exp(x/b)
z = z + (d * x) + (f * y) + g
    Simple Equation 20 Plus Plane 3D  
z = a*pow(x,b+c*y)
z = z + (d * x) + (f * y) + g
    Simple Equation 21 Plus Plane 3D  
z = a*pow(y,b+c*x)
z = z + (d * x) + (f * y) + g
    Simple Equation 22 Plus Plane 3D  
z = a*pow(x,b+c/y)
z = z + (d * x) + (f * y) + g
    Simple Equation 23 Plus Plane 3D  
z = a*pow(y,b+c/x)
z = z + (d * x) + (f * y) + g
    Simple Equation 24 Plus Plane 3D  
z = a*pow(x,b+c*ln(y))
z = z + (d * x) + (f * y) + g
    Simple Equation 25 Plus Plane 3D  
z = a*pow(y,b+c*ln(x))
z = z + (d * x) + (f * y) + g
    Simple Equation 26 Plus Plane 3D  
z = a*pow(y,b+c/ln(x))
z = z + (d * x) + (f * y) + g
    Simple Equation 27 Plus Plane 3D  
z = a*pow(x,b+c/ln(y))
z = z + (d * x) + (f * y) + g
    Simple Equation 28 Plus Plane 3D  
z = a*exp(b*x+c*pow(y,2.0))
z = z + (d * x) + (f * y) + g
    Simple Equation 29 Plus Plane 3D  
z = a*exp(b*y+c*pow(x,2.0))
z = z + (d * x) + (f * y) + g
    Simple Equation 30 Plus Plane 3D  
z = a*exp(b/x+c*y)
z = z + (d * x) + (f * y) + g
    Simple Equation 31 Plus Plane 3D  
z = a*exp(b/y+c*x)
z = z + (d * x) + (f * y) + g
    Simple Equation 32 Plus Plane 3D  
z = (a+x)/(b+c*y)
z = z + (d * x) + (f * y) + g
    Simple Equation 33 Plus Plane 3D  
z = (a+y)/(b+c*x)
z = z + (d * x) + (f * y) + g
    Simple Equation 34 Plus Plane 3D  
z = (a+x)/(b+c*pow(y,2.0))
z = z + (d * x) + (f * y) + g
    Simple Equation 35 Plus Plane 3D  
z = (a+y)/(b+c*pow(x,2.0))
z = z + (d * x) + (f * y) + g
    Simple Equation 36 Plus Plane 3D  
z = a*(exp(b*x)-exp(c*y))
z = z + (d * x) + (f * y) + g
    Simple Equation 37 Plus Plane 3D  
z = a*pow(x,b*pow(y,c))
z = z + (d * x) + (f * y) + g
    Simple Equation 38 Plus Plane 3D  
z = a*pow(y,b*pow(x,c))
z = z + (d * x) + (f * y) + g
    Simple Equation 39 Plus Plane 3D  
z = x/(a+b*y+c*pow(y,0.5))
z = z + (d * x) + (f * y) + g
    Simple Equation 40 Plus Plane 3D  
z = y/(a+b*x+c*pow(x,0.5))
z = z + (d * x) + (f * y) + g
    Simple Equation 41 Plus Plane 3D  
z = exp(a+b/x+c*ln(y))
z = z + (d * x) + (f * y) + g
    Simple Equation 42 Plus Plane 3D  
z = exp(a+b/y+c*ln(x))
z = z + (d * x) + (f * y) + g
    Simple Equation 43 Plus Plane 3D  
z = a*pow(x,b)*ln(y+c)
z = z + (d * x) + (f * y) + g
    Simple Equation 44 Plus Plane 3D  
z = a*pow(y,b)*ln(x+c)
z = z + (d * x) + (f * y) + g
     
     


3D TaylorSeries

    Taylor Series A With Exponential Decay 3D  
z = a + bx + cy + dx2 + fy2 + gxy
z = z / (h * 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 / (h * 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 / (h * 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 / (h * exp(xy))
    Taylor Series E With Exponential Decay 3D  
z = a + b/x + cy + d/x2 + fy2 + gy/x
z = z / (h * 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 / (h * 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 / (h * 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 / (h * exp(xy))
    Taylor Series I With Exponential Decay 3D  
z = a + bx + c/y + dx2 + f/y2 + gx/y
z = z / (h * 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 / (h * 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 / (h * 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 / (h * exp(xy))
    Taylor Series M With Exponential Decay 3D  
z = a + b/x + c/y + d/x2 + f/y2 + g/(xy)
z = z / (h * 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 / (h * 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 / (h * 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 / (h * exp(xy))
     
     
    Taylor Series A With Exponential Growth 3D  
z = a + bx + cy + dx2 + fy2 + gxy
z = z * (h * 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 * (h * 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 * (h * 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 * (h * exp(xy))
    Taylor Series E With Exponential Growth 3D  
z = a + b/x + cy + d/x2 + fy2 + gy/x
z = z * (h * 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 * (h * 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 * (h * 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 * (h * exp(xy))
    Taylor Series I With Exponential Growth 3D  
z = a + bx + c/y + dx2 + f/y2 + gx/y
z = z * (h * 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 * (h * 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 * (h * 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 * (h * exp(xy))
    Taylor Series M With Exponential Growth 3D  
z = a + b/x + c/y + d/x2 + f/y2 + g/(xy)
z = z * (h * 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 * (h * 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 * (h * 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 * (h * 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 / (h * 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 / (h * 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 / (h * 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 / (h * xy)
    Taylor Series E With Linear Decay 3D  
z = a + b/x + cy + d/x2 + fy2 + gy/x
z = z / (h * xy)
    Taylor Series F With Linear Decay 3D  
z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x)
z = z / (h * 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 / (h * 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 / (h * xy)
    Taylor Series I With Linear Decay 3D  
z = a + bx + c/y + dx2 + f/y2 + gx/y
z = z / (h * 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 / (h * xy)
    Taylor Series K With Linear Decay 3D  
z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y)
z = z / (h * 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 / (h * xy)
    Taylor Series M With Linear Decay 3D  
z = a + b/x + c/y + d/x2 + f/y2 + g/(xy)
z = z / (h * 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 / (h * 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 / (h * 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 / (h * xy)
     
     
    Taylor Series A With Linear Growth 3D  
z = a + bx + cy + dx2 + fy2 + gxy
z = z * (h * xy)
    Taylor Series B With Linear Growth 3D  
z = a + b*ln(x) + cy + d*ln(x)2 + fy2 + g*ln(x)*y
z = z * (h * xy)
    Taylor Series C With Linear Growth 3D  
z = a + bx + c*ln(y) + dx2 + f*ln(y)2 + g*x*ln(y)
z = z * (h * xy)
    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 * (h * xy)
    Taylor Series E With Linear Growth 3D  
z = a + b/x + cy + d/x2 + fy2 + gy/x
z = z * (h * xy)
    Taylor Series F With Linear Growth 3D  
z = a + b/ln(x) + cy + d/ln(x)2 + fy2 + gy/ln(x)
z = z * (h * xy)
    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 * (h * xy)
    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 * (h * xy)
    Taylor Series I With Linear Growth 3D  
z = a + bx + c/y + dx2 + f/y2 + gx/y
z = z * (h * xy)
    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 * (h * xy)
    Taylor Series K With Linear Growth 3D  
z = a + bx + c/ln(y) + dx2 + f/ln(y)2 + gx/ln(y)
z = z * (h * xy)
    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 * (h * xy)
    Taylor Series M With Linear Growth 3D  
z = a + b/x + c/y + d/x2 + f/y2 + g/(xy)
z = z * (h * xy)
    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 * (h * xy)
    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 * (h * xy)
    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 * (h * xy)
     
     
    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
     
     
    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))
     
     


3D Trigonometric

    Cosh X Plus Cosh Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Cosh X Plus Sine Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Cosh X Plus Tangent Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Cosh X Times Cosh Y[radians] With Exponential Decay And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Cosh X Times Sine Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Cosh X Times Tangent Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Cosh XY [radians] With Exponential Decay And Offset 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z / (d * 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 / (k * 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 / (i * exp(xy)) + Offset
    Sine X Plus Cosh Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Sine X Plus Sine Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Sine X Plus Tangent Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Sine X Times Cosh Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Sine X Times Sine Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Sine X Times Tangent Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Sine XY [radians] With Exponential Decay And Offset 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z / (d * exp(xy)) + Offset
    Tangent X Plus Cosh Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Tangent X Plus Sine Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Tangent X Plus Tangent Y [radians] With Exponential Decay And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * exp(xy)) + Offset
    Tangent X Times Cosh Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Tangent X Times Sine Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Tangent X Times Tangent Y [radians] With Exponential Decay And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * exp(xy)) + Offset
    Tangent XY [radians] With Exponential Decay And Offset 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z / (d * exp(xy)) + Offset
     
     
    Cosh X Plus Cosh Y [radians] With Exponential Decay 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Cosh X Plus Sine Y [radians] With Exponential Decay 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Cosh X Plus Tangent Y [radians] With Exponential Decay 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Cosh X Times Cosh Y[radians] With Exponential Decay 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Cosh X Times Sine Y [radians] With Exponential Decay 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Cosh X Times Tangent Y [radians] With Exponential Decay 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Cosh XY [radians] With Exponential Decay 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z / (d * 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 / (k * 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 / (i * exp(xy))
    Sine X Plus Cosh Y [radians] With Exponential Decay 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Sine X Plus Sine Y [radians] With Exponential Decay 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Sine X Plus Tangent Y [radians] With Exponential Decay 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Sine X Times Cosh Y [radians] With Exponential Decay 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Sine X Times Sine Y [radians] With Exponential Decay 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Sine X Times Tangent Y [radians] With Exponential Decay 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Sine XY [radians] With Exponential Decay 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z / (d * exp(xy))
    Tangent X Plus Cosh Y [radians] With Exponential Decay 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Tangent X Plus Sine Y [radians] With Exponential Decay 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Tangent X Plus Tangent Y [radians] With Exponential Decay 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * exp(xy))
    Tangent X Times Cosh Y [radians] With Exponential Decay 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Tangent X Times Sine Y [radians] With Exponential Decay 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Tangent X Times Tangent Y [radians] With Exponential Decay 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * exp(xy))
    Tangent XY [radians] With Exponential Decay 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z / (d * exp(xy))
     
     
    Cosh X Plus Cosh Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Cosh X Plus Sine Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Cosh X Plus Tangent Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Cosh X Times Cosh Y[radians] With Exponential Growth And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Cosh X Times Sine Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Cosh X Times Tangent Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Cosh XY [radians] With Exponential Growth And Offset 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z * (d * 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 * (k * 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 * (i * exp(xy)) + Offset
    Sine X Plus Cosh Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Sine X Plus Sine Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Sine X Plus Tangent Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Sine X Times Cosh Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Sine X Times Sine Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Sine X Times Tangent Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Sine XY [radians] With Exponential Growth And Offset 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z * (d * exp(xy)) + Offset
    Tangent X Plus Cosh Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Tangent X Plus Sine Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Tangent X Plus Tangent Y [radians] With Exponential Growth And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * exp(xy)) + Offset
    Tangent X Times Cosh Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Tangent X Times Sine Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Tangent X Times Tangent Y [radians] With Exponential Growth And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * exp(xy)) + Offset
    Tangent XY [radians] With Exponential Growth And Offset 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z * (d * exp(xy)) + Offset
     
     
    Cosh X Plus Cosh Y [radians] With Exponential Growth 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Cosh X Plus Sine Y [radians] With Exponential Growth 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Cosh X Plus Tangent Y [radians] With Exponential Growth 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Cosh X Times Cosh Y[radians] With Exponential Growth 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Cosh X Times Sine Y [radians] With Exponential Growth 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Cosh X Times Tangent Y [radians] With Exponential Growth 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Cosh XY [radians] With Exponential Growth 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z * (d * 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 * (k * 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 * (i * exp(xy))
    Sine X Plus Cosh Y [radians] With Exponential Growth 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Sine X Plus Sine Y [radians] With Exponential Growth 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Sine X Plus Tangent Y [radians] With Exponential Growth 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Sine X Times Cosh Y [radians] With Exponential Growth 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Sine X Times Sine Y [radians] With Exponential Growth 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Sine X Times Tangent Y [radians] With Exponential Growth 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Sine XY [radians] With Exponential Growth 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z * (d * exp(xy))
    Tangent X Plus Cosh Y [radians] With Exponential Growth 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Tangent X Plus Sine Y [radians] With Exponential Growth 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Tangent X Plus Tangent Y [radians] With Exponential Growth 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * exp(xy))
    Tangent X Times Cosh Y [radians] With Exponential Growth 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Tangent X Times Sine Y [radians] With Exponential Growth 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Tangent X Times Tangent Y [radians] With Exponential Growth 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * exp(xy))
    Tangent XY [radians] With Exponential Growth 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z * (d * exp(xy))
     
     
    Inverse Cosh X Plus Cosh Y [radians] 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Cosh X Plus Sine Y [radians] 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Cosh X Plus Tangent Y [radians] 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Cosh X Times Cosh Y[radians] 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Cosh X Times Sine Y [radians] 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Cosh X Times Tangent Y [radians] 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Cosh XY [radians] 3D  
z = amplitude * cosh(pi * (xy - center) / width)
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 X Plus Cosh Y [radians] 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Sine X Plus Sine Y [radians] 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Sine X Plus Tangent Y [radians] 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Sine X Times Cosh Y [radians] 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Sine X Times Sine Y [radians] 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Sine X Times Tangent Y [radians] 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Sine XY [radians] 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = xy / z
    Inverse Tangent X Plus Cosh Y [radians] 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Tangent X Plus Sine Y [radians] 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Tangent X Plus Tangent Y [radians] 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Tangent X Times Cosh Y [radians] 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Tangent X Times Sine Y [radians] 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Tangent X Times Tangent Y [radians] 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = xy / z
    Inverse Tangent XY [radians] 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = xy / z
     
     
    Inverse Cosh X Plus Cosh Y [radians] With Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Cosh X Plus Sine Y [radians] With Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Cosh X Plus Tangent Y [radians] With Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Cosh X Times Cosh Y[radians] With Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Cosh X Times Sine Y [radians] With Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Cosh X Times Tangent Y [radians] With Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Cosh XY [radians] With Offset 3D  
z = amplitude * cosh(pi * (xy - center) / width)
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 X Plus Cosh Y [radians] With Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Sine X Plus Sine Y [radians] With Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Sine X Plus Tangent Y [radians] With Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Sine X Times Cosh Y [radians] With Offset 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Sine X Times Sine Y [radians] With Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Sine X Times Tangent Y [radians] With Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Sine XY [radians] With Offset 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = xy / (z + Offset
    Inverse Tangent X Plus Cosh Y [radians] With Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Tangent X Plus Sine Y [radians] With Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Tangent X Plus Tangent Y [radians] With Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Tangent X Times Cosh Y [radians] With Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Tangent X Times Sine Y [radians] With Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Tangent X Times Tangent Y [radians] With Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = xy / (z + Offset
    Inverse Tangent XY [radians] With Offset 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = xy / (z + Offset
     
     
    Cosh X Plus Cosh Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Cosh X Plus Sine Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Cosh X Plus Tangent Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Cosh X Times Cosh Y[radians] With Linear Decay And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Cosh X Times Sine Y [radians] With Linear Decay And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Cosh X Times Tangent Y [radians] With Linear Decay And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Cosh XY [radians] With Linear Decay And Offset 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z / (d * 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 / (k * 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 / (i * xy) + Offset
    Sine X Plus Cosh Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Sine X Plus Sine Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Sine X Plus Tangent Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Sine X Times Cosh Y [radians] With Linear Decay And Offset 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Sine X Times Sine Y [radians] With Linear Decay And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Sine X Times Tangent Y [radians] With Linear Decay And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Sine XY [radians] With Linear Decay And Offset 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z / (d * xy) + Offset
    Tangent X Plus Cosh Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Tangent X Plus Sine Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Tangent X Plus Tangent Y [radians] With Linear Decay And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * xy) + Offset
    Tangent X Times Cosh Y [radians] With Linear Decay And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Tangent X Times Sine Y [radians] With Linear Decay And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Tangent X Times Tangent Y [radians] With Linear Decay And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * xy) + Offset
    Tangent XY [radians] With Linear Decay And Offset 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z / (d * xy) + Offset
     
     
    Cosh X Plus Cosh Y [radians] With Linear Decay 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Cosh X Plus Sine Y [radians] With Linear Decay 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Cosh X Plus Tangent Y [radians] With Linear Decay 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Cosh X Times Cosh Y[radians] With Linear Decay 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Cosh X Times Sine Y [radians] With Linear Decay 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Cosh X Times Tangent Y [radians] With Linear Decay 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Cosh XY [radians] With Linear Decay 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z / (d * 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 / (k * 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 / (i * xy)
    Sine X Plus Cosh Y [radians] With Linear Decay 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Sine X Plus Sine Y [radians] With Linear Decay 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Sine X Plus Tangent Y [radians] With Linear Decay 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Sine X Times Cosh Y [radians] With Linear Decay 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Sine X Times Sine Y [radians] With Linear Decay 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Sine X Times Tangent Y [radians] With Linear Decay 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Sine XY [radians] With Linear Decay 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z / (d * xy)
    Tangent X Plus Cosh Y [radians] With Linear Decay 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Tangent X Plus Sine Y [radians] With Linear Decay 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Tangent X Plus Tangent Y [radians] With Linear Decay 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z / (h * xy)
    Tangent X Times Cosh Y [radians] With Linear Decay 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Tangent X Times Sine Y [radians] With Linear Decay 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Tangent X Times Tangent Y [radians] With Linear Decay 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z / (g * xy)
    Tangent XY [radians] With Linear Decay 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z / (d * xy)
     
     
    Cosh X Plus Cosh Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Cosh X Plus Sine Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Cosh X Plus Tangent Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Cosh X Times Cosh Y[radians] With Linear Growth And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Cosh X Times Sine Y [radians] With Linear Growth And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Cosh X Times Tangent Y [radians] With Linear Growth And Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Cosh XY [radians] With Linear Growth And Offset 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z * (d * 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 * (k * 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 * (i * xy) + Offset
    Sine X Plus Cosh Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Sine X Plus Sine Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Sine X Plus Tangent Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Sine X Times Cosh Y [radians] With Linear Growth And Offset 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Sine X Times Sine Y [radians] With Linear Growth And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Sine X Times Tangent Y [radians] With Linear Growth And Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Sine XY [radians] With Linear Growth And Offset 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z * (d * xy) + Offset
    Tangent X Plus Cosh Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Tangent X Plus Sine Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Tangent X Plus Tangent Y [radians] With Linear Growth And Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * xy) + Offset
    Tangent X Times Cosh Y [radians] With Linear Growth And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Tangent X Times Sine Y [radians] With Linear Growth And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Tangent X Times Tangent Y [radians] With Linear Growth And Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * xy) + Offset
    Tangent XY [radians] With Linear Growth And Offset 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z * (d * xy) + Offset
     
     
    Cosh X Plus Cosh Y [radians] With Linear Growth 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Cosh X Plus Sine Y [radians] With Linear Growth 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Cosh X Plus Tangent Y [radians] With Linear Growth 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Cosh X Times Cosh Y[radians] With Linear Growth 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Cosh X Times Sine Y [radians] With Linear Growth 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Cosh X Times Tangent Y [radians] With Linear Growth 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Cosh XY [radians] With Linear Growth 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z * (d * 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 * (k * xy)
    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 * (i * xy)
    Sine X Plus Cosh Y [radians] With Linear Growth 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Sine X Plus Sine Y [radians] With Linear Growth 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Sine X Plus Tangent Y [radians] With Linear Growth 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Sine X Times Cosh Y [radians] With Linear Growth 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Sine X Times Sine Y [radians] With Linear Growth 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Sine X Times Tangent Y [radians] With Linear Growth 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Sine XY [radians] With Linear Growth 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z * (d * xy)
    Tangent X Plus Cosh Y [radians] With Linear Growth 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Tangent X Plus Sine Y [radians] With Linear Growth 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Tangent X Plus Tangent Y [radians] With Linear Growth 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = z * (h * xy)
    Tangent X Times Cosh Y [radians] With Linear Growth 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Tangent X Times Sine Y [radians] With Linear Growth 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Tangent X Times Tangent Y [radians] With Linear Growth 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = z * (g * xy)
    Tangent XY [radians] With Linear Growth 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z * (d * xy)
     
     
    Reciprocal Cosh X Plus Cosh Y [radians] 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Cosh X Plus Sine Y [radians] 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Cosh X Plus Tangent Y [radians] 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Cosh X Times Cosh Y[radians] 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Cosh X Times Sine Y [radians] 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Cosh X Times Tangent Y [radians] 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Cosh XY [radians] 3D  
z = amplitude * cosh(pi * (xy - center) / width)
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 X Plus Cosh Y [radians] 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Sine X Plus Sine Y [radians] 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Sine X Plus Tangent Y [radians] 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Sine X Times Cosh Y [radians] 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Sine X Times Sine Y [radians] 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Sine X Times Tangent Y [radians] 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Sine XY [radians] 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = 1.0 / z
    Reciprocal Tangent X Plus Cosh Y [radians] 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Tangent X Plus Sine Y [radians] 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Tangent X Plus Tangent Y [radians] 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Tangent X Times Cosh Y [radians] 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Tangent X Times Sine Y [radians] 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Tangent X Times Tangent Y [radians] 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = 1.0 / z
    Reciprocal Tangent XY [radians] 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = 1.0 / z
     
     
    Reciprocal Cosh X Plus Cosh Y [radians] With Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Cosh X Plus Sine Y [radians] With Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Cosh X Plus Tangent Y [radians] With Offset 3D  
z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Cosh X Times Cosh Y[radians] With Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Cosh X Times Sine Y [radians] With Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Cosh X Times Tangent Y [radians] With Offset 3D  
z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Cosh XY [radians] With Offset 3D  
z = amplitude * cosh(pi * (xy - center) / width)
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 X Plus Cosh Y [radians] With Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Sine X Plus Sine Y [radians] With Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Sine X Plus Tangent Y [radians] With Offset 3D  
z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Sine X Times Cosh Y [radians] With Offset 3D  
z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Sine X Times Sine Y [radians] With Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Sine X Times Tangent Y [radians] With Offset 3D  
z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Sine XY [radians] With Offset 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = 1.0 / z + Offset
    Reciprocal Tangent X Plus Cosh Y [radians] With Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Tangent X Plus Sine Y [radians] With Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Tangent X Plus Tangent Y [radians] With Offset 3D  
z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Tangent X Times Cosh Y [radians] With Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Tangent X Times Sine Y [radians] With Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Tangent X Times Tangent Y [radians] With Offset 3D  
z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
z = 1.0 / z + Offset
    Reciprocal Tangent XY [radians] With Offset 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = 1.0 / z + Offset
     
     
    Cosh X Plus Cosh Y [radians] 3D   z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
    Cosh X Plus Sine Y [radians] 3D   z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
    Cosh X Plus Tangent Y [radians] 3D   z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
    Cosh X Times Cosh Y[radians] 3D   z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
    Cosh X Times Sine Y [radians] 3D   z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
    Cosh X Times Tangent Y [radians] 3D   z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
    Cosh XY [radians] 3D   z = amplitude * cosh(pi * (xy - center) / width)
    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 X Plus Cosh Y [radians] 3D   z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
    Sine X Plus Sine Y [radians] 3D   z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
    Sine X Plus Tangent Y [radians] 3D   z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
    Sine X Times Cosh Y [radians] 3D   z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
    Sine X Times Sine Y [radians] 3D   z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
    Sine X Times Tangent Y [radians] 3D   z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
    Sine XY [radians] 3D   z = amplitude * sin(pi * (xy - center) / width)
    Tangent X Plus Cosh Y [radians] 3D   z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y)
    Tangent X Plus Sine Y [radians] 3D   z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y)
    Tangent X Plus Tangent Y [radians] 3D   z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y)
    Tangent X Times Cosh Y [radians] 3D   z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y)
    Tangent X Times Sine Y [radians] 3D   z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y)
    Tangent X Times Tangent Y [radians] 3D   z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y)
    Tangent XY [radians] 3D   z = amplitude * tan(pi * (xy - center) / width)
     
     
    Cosh X Plus Cosh Y [radians] With Offset 3D   z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y) + Offset
    Cosh X Plus Sine Y [radians] With Offset 3D   z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y) + Offset
    Cosh X Plus Tangent Y [radians] With Offset 3D   z = amplitude_x * cosh(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y) + Offset
    Cosh X Times Cosh Y[radians] With Offset 3D   z = amplitude * cosh(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y) + Offset
    Cosh X Times Sine Y [radians] With Offset 3D   z = amplitude * cosh(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y) + Offset
    Cosh X Times Tangent Y [radians] With Offset 3D   z = amplitude * cosh(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y) + Offset
    Cosh XY [radians] With Offset 3D   z = amplitude * cosh(pi * (xy - center) / width) + 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 X Plus Cosh Y [radians] With Offset 3D   z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y) + Offset
    Sine X Plus Sine Y [radians] With Offset 3D   z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y) + Offset
    Sine X Plus Tangent Y [radians] With Offset 3D   z = amplitude_x * sin(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y) + Offset
    Sine X Times Cosh Y [radians] With Offset 3D   z = amplitude * sine(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y) + Offset
    Sine X Times Sine Y [radians] With Offset 3D   z = amplitude * sin(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y) + Offset
    Sine X Times Tangent Y [radians] With Offset 3D   z = amplitude * sin(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y) + Offset
    Sine XY [radians] With Offset 3D   z = amplitude * sin(pi * (xy - center) / width) + Offset
    Tangent X Plus Cosh Y [radians] With Offset 3D   z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * cosh(pi * (y - center_y) / width_y) + Offset
    Tangent X Plus Sine Y [radians] With Offset 3D   z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * sin(pi * (y - center_y) / width_y) + Offset
    Tangent X Plus Tangent Y [radians] With Offset 3D   z = amplitude_x * tan(pi * (x - center_x) / width_x) + amplitude_y * tan(pi * (y - center_y) / width_y) + Offset
    Tangent X Times Cosh Y [radians] With Offset 3D   z = amplitude * tan(pi * (x - center_x) / width_x) * cosh(pi * (y - center_y) / width_y) + Offset
    Tangent X Times Sine Y [radians] With Offset 3D   z = amplitude * tan(pi * (x - center_x) / width_x) * sin(pi * (y - center_y) / width_y) + Offset
    Tangent X Times Tangent Y [radians] With Offset 3D   z = amplitude * tan(pi * (x - center_x) / width_x) * tan(pi * (y - center_y) / width_y) + Offset
    Tangent XY [radians] With Offset 3D   z = amplitude * tan(pi * (xy - center) / width) + Offset
     
     
    Cosh XY [radians] Plus Plane 3D  
z = amplitude * cosh(pi * (xy - center) / width)
z = z + (d * x) + (f * y) + g
    Sine XY [radians] Plus Plane 3D  
z = amplitude * sin(pi * (xy - center) / width)
z = z + (d * x) + (f * y) + g
    Tangent XY [radians] Plus Plane 3D  
z = amplitude * tan(pi * (xy - center) / width)
z = z + (d * x) + (f * y) + g
     
     










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

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

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

Core fitting library source code
pyeq2 (Python 2)   pyeq3


Link to additional information and history