ZunZun.com List Of All 2D Equations

2D BioScience

Aphid Population Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2   [web citation]
Beverton-Holt A 2D		y = r / (1 + ((r-1)/K) * x)
Beverton-Holt B 2D		y = rx / (1 + ((r-1)/K) * x)
BioScience A 2D		y = a * (1.0 - (b * cx))
BioScience B 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d)
Cellular Conductance 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5)   [web citation]
Derek Duncan Custom Equation 2D		y = a / (1 + exp(-1/b*(x-c)))d
Dose-Response A 2D		y = b + (a-b) / (1 + 10x-c)
Dose-Response B 2D		y = b + (a-b) / (1 + 10c-x)
Dose-Response C 2D		y = b + (a-b) / (1 + 10d*(x-c))
Dose-Response D 2D		y = b + (a-b) / (1 + 10d*(c-x))
Dose-Response E 2D		y = b + (a-b) / (1 + (x/c)d)
Generalized Negative Exponential 2D		y = a * (1.0 - exp(-bx))c
Generalized Product Accumulation 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f
Generalized Substrate Depletion 2D		y = ax / (b + x) - cx - d
High-Low Affinity 2D		y = abx / (1+bx)
High-Low Affinity Double 2D		y = abx / (1+bx) + cdx / (1+dx)
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) + cd / (1+dx)
High-Low Affinity Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx)
Hyperbolic A 2D		y = (a + x) / (b + x)
Hyperbolic B 2D		y = (a + bx) / (c + x)
Hyperbolic C 2D		y = (a + x) / (b + cx)
Hyperbolic D 2D		y = (a + bx) / (c + dx)
Hyperbolic E 2D		y = ax / (b + x)
Hyperbolic F 2D		y = ax / (b + x) + cx
Hyperbolic G 2D		y = ax / (b + x) + cx / (d + x)
Hyperbolic H 2D		y = ax / (b + x) + cx / (d + x) + fx
Hyperbolic I 2D		y = ab / (b + x)
Hyperbolic J 2D		y = x / (a + bx)
Hyperbolic Logistic 2D		y = axb / (c + xb)
Membrane Transport 2D		y = a(x-b) / (x2 + cx + d)
Michaelis-Menten 2D		y = ax / (b + x)
Michaelis-Menten Double 2D		y = ax / (b + x) + cx / (d + x)
Michaelis-Menten Isotope Displacement ([Hot] subsumed) 2D		y = a / (b + x)
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) 2D		y = a / (b + x) + c / (d + x)
Michaelis-Menten Product Accumulation 2D		y = a(b-x) / (c + (b-x))
Negative Exponential 2D		y = a * (1.0 - exp(-bx))
New Zealand Ecology Logistic 1 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3)))
New Zealand Ecology Logistic 2 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3)))
Plant Disease Exponential Model 2D		Incidence = y0 * exp(r * time)   [web citation]
Plant Disease Gompertz Model 2D		Incidence = exp(ln(y0) * exp(-r * time))   [web citation]
Plant Disease Logistic Model 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time)))   [web citation]
Plant Disease Monomolecular Model 2D		Incidence = 1 - ((1 - y0) * exp(-r * time))   [web citation]
Plant Disease Weibull Model 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c)   [web citation]
Preece And Baines Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d)))
Scaled Log 2D		y = a * log(x)
Scaled Log Transform 2D		y = a * log(bx + c)
Scaled Power 2D		y = a * xb
Scaled Power Transform 2D		y = a * (cx + d)b
Toby Barrus 3-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c))
Toby Barrus 4-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)b)
Toby Barrus 5-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)b )f
Weibull 2D		y = a * (1.0 - exp(-b * (x - c)d))
Xiaogang Peng Immunoassay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx)))
von Bertalanffy Growth 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero)))
Aphid Population Growth With Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 + Offset   [web citation]
Beverton-Holt A With Offset 2D		y = r / (1 + ((r-1)/K) * x) + Offset
Beverton-Holt B With Offset 2D		y = rx / (1 + ((r-1)/K) * x) + Offset
BioScience A With Offset 2D		y = a * (1.0 - (b * cx)) + Offset
BioScience B With Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) + Offset
Cellular Conductance With Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) + Offset   [web citation]
Derek Duncan Custom Equation With Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d + Offset
Generalized Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx))c + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + cd / (1+dx) + Offset
High-Low Affinity Double With Offset 2D		y = abx / (1+bx) + cdx / (1+dx) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + Offset
High-Low Affinity With Offset 2D		y = abx / (1+bx) + Offset
Hyperbolic A With Offset 2D		y = (a + x) / (b + x) + Offset
Hyperbolic B With Offset 2D		y = (a + bx) / (c + x) + Offset
Hyperbolic C With Offset 2D		y = (a + x) / (b + cx) + Offset
Hyperbolic D With Offset 2D		y = (a + bx) / (c + dx) + Offset
Hyperbolic E With Offset 2D		y = ax / (b + x) + Offset
Hyperbolic F With Offset 2D		y = ax / (b + x) + cx + Offset
Hyperbolic G With Offset 2D		y = ax / (b + x) + cx / (d + x) + Offset
Hyperbolic H With Offset 2D		y = ax / (b + x) + cx / (d + x) + fx + Offset
Hyperbolic I With Offset 2D		y = ab / (b + x) + Offset
Hyperbolic J With Offset 2D		y = x / (a + bx) + Offset
Hyperbolic Logistic With Offset 2D		y = axb / (c + xb) + Offset
Membrane Transport With Offset 2D		y = a(x-b) / (x2 + cx + d) + Offset
Michaelis-Menten Double With Offset 2D		y = ax / (b + x) + cx / (d + x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Offset 2D		y = a / (b + x) + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Offset 2D		y = a / (b + x) + c / (d + x) + Offset
Michaelis-Menten Product Accumulation With Offset 2D		y = a(b-x) / (c + (b-x)) + Offset
Michaelis-Menten With Offset 2D		y = ax / (b + x) + Offset
Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx)) + Offset
Plant Disease Exponential Model With Offset 2D		Incidence = y0 * exp(r * time) + Offset   [web citation]
Plant Disease Gompertz Model With Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) + Offset   [web citation]
Plant Disease Logistic Model With Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) + Offset   [web citation]
Plant Disease Monomolecular Model With Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) + Offset   [web citation]
Plant Disease Weibull Model With Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) + Offset   [web citation]
Scaled Log Transform With Offset 2D		y = a * log(bx + c) + Offset
Scaled Log With Offset 2D		y = a * log(x) + Offset
Scaled Power Transform With Offset 2D		y = a * (cx + d)b + Offset
Scaled Power With Offset 2D		y = a * xb + Offset
Weibull With Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) + Offset
Xiaogang Peng Immunoassay With Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) + Offset
von Bertalanffy Growth With Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) + Offset
Aphid Population Growth With Exponential Decay 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) / exp(x)   [web citation]
Beverton-Holt A With Exponential Decay 2D		y = r / (1 + ((r-1)/K) * x) y = y / exp(x)
Beverton-Holt B With Exponential Decay 2D		y = rx / (1 + ((r-1)/K) * x) y = y / exp(x)
BioScience A With Exponential Decay 2D		y = a * (1.0 - (b * cx)) y = y / exp(x)
BioScience B With Exponential Decay 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y / exp(x)
Cellular Conductance With Exponential Decay 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g / (h * exp(x))   [web citation]
Derek Duncan Custom Equation With Exponential Decay 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y / exp(x)
Dose-Response A With Exponential Decay 2D		y = b + (a-b) / (1 + 10x-c) y = y / (f * exp(x))
Dose-Response B With Exponential Decay 2D		y = b + (a-b) / (1 + 10c-x) y = y / (f * exp(x))
Dose-Response C With Exponential Decay 2D		y = b + (a-b) / (1 + 10d*(x-c)) y = y / (g * exp(x))
Dose-Response D With Exponential Decay 2D		y = b + (a-b) / (1 + 10d*(c-x)) y = y / (g * exp(x))
Dose-Response E With Exponential Decay 2D		y = b + (a-b) / (1 + (x/c)d) y = y / (g * exp(x))
Generalized Negative Exponential With Exponential Decay 2D		y = a * (1.0 - exp(-bx))c y = y / exp(x)
Generalized Product Accumulation With Exponential Decay 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y / (h * exp(x))
Generalized Substrate Depletion With Exponential Decay 2D		y = ax / (b + x) - cx - d y = y / (g * exp(x))
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Decay 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (g * exp(x))
High-Low Affinity Double With Exponential Decay 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (g * exp(x))
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Decay 2D		y = ab / (1+bx) y = y / exp(x)
High-Low Affinity With Exponential Decay 2D		y = abx / (1+bx) y = y / exp(x)
Hyperbolic A With Exponential Decay 2D		y = (a + x) / (b + x) y = y / (d * exp(x))
Hyperbolic B With Exponential Decay 2D		y = (a + bx) / (c + x) y = y / (f * exp(x))
Hyperbolic C With Exponential Decay 2D		y = (a + x) / (b + cx) y = y / (f * exp(x))
Hyperbolic D With Exponential Decay 2D		y = (a + bx) / (c + dx) y = y / (g * exp(x))
Hyperbolic E With Exponential Decay 2D		y = ax / (b + x) y = y / exp(x)
Hyperbolic F With Exponential Decay 2D		y = ax / (b + x) + cx y = y / (f * exp(x))
Hyperbolic G With Exponential Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (g * exp(x))
Hyperbolic H With Exponential Decay 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (h * exp(x))
Hyperbolic I With Exponential Decay 2D		y = ab / (b + x) y = y / exp(x)
Hyperbolic J With Exponential Decay 2D		y = x / (a + bx) y = y / (d * exp(x))
Hyperbolic Logistic With Exponential Decay 2D		y = axb / (c + xb) y = y / exp(x)
Membrane Transport With Exponential Decay 2D		y = a(x-b) / (x2 + cx + d) y = y / exp(x)
Michaelis-Menten Double With Exponential Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (g * exp(x))
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Decay 2D		y = a / (b + x) y = y / exp(x)
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Decay 2D		y = a / (b + x) + c / (d + x) y = y / (g * exp(x))
Michaelis-Menten Product Accumulation With Exponential Decay 2D		y = a(b-x) / (c + (b-x)) y = y / exp(x)
Michaelis-Menten With Exponential Decay 2D		y = ax / (b + x) y = y / exp(x)
Negative Exponential With Exponential Decay 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x)
New Zealand Ecology Logistic 1 With Exponential Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3))) n = n / (g * exp(x))
New Zealand Ecology Logistic 2 With Exponential Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3))) n = n / (h * exp(x))
Plant Disease Exponential Model With Exponential Decay 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / exp(x)   [web citation]
Plant Disease Gompertz Model With Exponential Decay 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (d * exp(x))   [web citation]
Plant Disease Logistic Model With Exponential Decay 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (d * exp(x))   [web citation]
Plant Disease Monomolecular Model With Exponential Decay 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (d * exp(x))   [web citation]
Plant Disease Weibull Model With Exponential Decay 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence / (f * exp(x))   [web citation]
Preece And Baines Growth With Exponential Decay 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y / (h * exp(x))
Scaled Log Transform With Exponential Decay 2D		y = a * log(bx + c) y = y / exp(x)
Scaled Log With Exponential Decay 2D		y = a * log(x) y = y / exp(x)
Scaled Power Transform With Exponential Decay 2D		y = a * (cx + d)b y = y / exp(x)
Scaled Power With Exponential Decay 2D		y = a * xb y = y / exp(x)
Toby Barrus 3-Parameter Custom Logistic Equation With Exponential Decay 2D		y = d + (a - d) / (1 + (x / c)) y = y / (f * exp(x))
Toby Barrus 4-Parameter Custom Logistic Equation With Exponential Decay 2D		y = d + (a - d) / (1 + (x / c)b) y = y / (g * exp(x))
Toby Barrus 5-Parameter Custom Logistic Equation With Exponential Decay 2D		y = d + (a - d) / (1 + (x / c)b )f y = y / (h * exp(x))
Weibull With Exponential Decay 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y / exp(x)
Xiaogang Peng Immunoassay With Exponential Decay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / exp(x)
von Bertalanffy Growth With Exponential Decay 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) / exp(x)
Aphid Population Growth With Exponential Decay And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) / exp(x) + Offset   [web citation]
Beverton-Holt A With Exponential Decay And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y / exp(x) + Offset
Beverton-Holt B With Exponential Decay And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y / exp(x) + Offset
BioScience A With Exponential Decay And Offset 2D		y = a * (1.0 - (b * cx)) y = y / exp(x) + Offset
BioScience B With Exponential Decay And Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y / exp(x) + Offset
Cellular Conductance With Exponential Decay And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g / (i * exp(x)) + Offset   [web citation]
Derek Duncan Custom Equation With Exponential Decay And Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y / exp(x) + Offset
Generalized Negative Exponential With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx))c y = y / exp(x) + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Decay And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (h * exp(x)) + Offset
High-Low Affinity Double With Exponential Decay And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (h * exp(x)) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Decay And Offset 2D		y = ab / (1+bx) y = y / exp(x) + Offset
High-Low Affinity With Exponential Decay And Offset 2D		y = abx / (1+bx) y = y / exp(x) + Offset
Hyperbolic A With Exponential Decay And Offset 2D		y = (a + x) / (b + x) y = y / (f * exp(x)) + Offset
Hyperbolic B With Exponential Decay And Offset 2D		y = (a + bx) / (c + x) y = y / (g * exp(x)) + Offset
Hyperbolic C With Exponential Decay And Offset 2D		y = (a + x) / (b + cx) y = y / (g * exp(x)) + Offset
Hyperbolic D With Exponential Decay And Offset 2D		y = (a + bx) / (c + dx) y = y / (h * exp(x)) + Offset
Hyperbolic E With Exponential Decay And Offset 2D		y = ax / (b + x) y = y / exp(x) + Offset
Hyperbolic F With Exponential Decay And Offset 2D		y = ax / (b + x) + cx y = y / (g * exp(x)) + Offset
Hyperbolic G With Exponential Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (h * exp(x)) + Offset
Hyperbolic H With Exponential Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (i * exp(x)) + Offset
Hyperbolic I With Exponential Decay And Offset 2D		y = ab / (b + x) y = y / exp(x) + Offset
Hyperbolic J With Exponential Decay And Offset 2D		y = x / (a + bx) y = y / (f * exp(x)) + Offset
Hyperbolic Logistic With Exponential Decay And Offset 2D		y = axb / (c + xb) y = y / exp(x) + Offset
Membrane Transport With Exponential Decay And Offset 2D		y = a(x-b) / (x2 + cx + d) y = y / exp(x) + Offset
Michaelis-Menten Double With Exponential Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (h * exp(x)) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Decay And Offset 2D		y = a / (b + x) y = y / exp(x) + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Decay And Offset 2D		y = a / (b + x) + c / (d + x) y = y / (h * exp(x)) + Offset
Michaelis-Menten Product Accumulation With Exponential Decay And Offset 2D		y = a(b-x) / (c + (b-x)) y = y / exp(x) + Offset
Michaelis-Menten With Exponential Decay And Offset 2D		y = ax / (b + x) y = y / exp(x) + Offset
Negative Exponential With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x) + Offset
Plant Disease Exponential Model With Exponential Decay And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / exp(x) + Offset   [web citation]
Plant Disease Gompertz Model With Exponential Decay And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (f * exp(x)) + Offset   [web citation]
Plant Disease Logistic Model With Exponential Decay And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (f * exp(x)) + Offset   [web citation]
Plant Disease Monomolecular Model With Exponential Decay And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (f * exp(x)) + Offset   [web citation]
Plant Disease Weibull Model With Exponential Decay And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence / (g * exp(x)) + Offset   [web citation]
Scaled Log Transform With Exponential Decay And Offset 2D		y = a * log(bx + c) y = y / exp(x) + Offset
Scaled Log With Exponential Decay And Offset 2D		y = a * log(x) y = y / exp(x) + Offset
Scaled Power Transform With Exponential Decay And Offset 2D		y = a * (cx + d)b y = y / exp(x) + Offset
Scaled Power With Exponential Decay And Offset 2D		y = a * xb y = y / exp(x) + Offset
Weibull With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y / exp(x) + Offset
Xiaogang Peng Immunoassay With Exponential Decay And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / exp(x) + Offset
von Bertalanffy Growth With Exponential Decay And Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) / exp(x) + Offset
Aphid Population Growth With Exponential Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) * exp(x)   [web citation]
Beverton-Holt A With Exponential Growth 2D		y = r / (1 + ((r-1)/K) * x) y = y * exp(x)
Beverton-Holt B With Exponential Growth 2D		y = rx / (1 + ((r-1)/K) * x) y = y * exp(x)
BioScience A With Exponential Growth 2D		y = a * (1.0 - (b * cx)) y = y * exp(x)
BioScience B With Exponential Growth 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y * exp(x)
Cellular Conductance With Exponential Growth 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g * (h * exp(x))   [web citation]
Derek Duncan Custom Equation With Exponential Growth 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y * exp(x)
Dose-Response A With Exponential Growth 2D		y = b + (a-b) / (1 + 10x-c) y = y * (f * exp(x))
Dose-Response B With Exponential Growth 2D		y = b + (a-b) / (1 + 10c-x) y = y * (f * exp(x))
Dose-Response C With Exponential Growth 2D		y = b + (a-b) / (1 + 10d*(x-c)) y = y * (g * exp(x))
Dose-Response D With Exponential Growth 2D		y = b + (a-b) / (1 + 10d*(c-x)) y = y * (g * exp(x))
Dose-Response E With Exponential Growth 2D		y = b + (a-b) / (1 + (x/c)d) y = y * (g * exp(x))
Generalized Negative Exponential With Exponential Growth 2D		y = a * (1.0 - exp(-bx))c y = y * exp(x)
Generalized Product Accumulation With Exponential Growth 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y * (h * exp(x))
Generalized Substrate Depletion With Exponential Growth 2D		y = ax / (b + x) - cx - d y = y * (g * exp(x))
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Growth 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (g * exp(x))
High-Low Affinity Double With Exponential Growth 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (g * exp(x))
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Growth 2D		y = ab / (1+bx) y = y * exp(x)
High-Low Affinity With Exponential Growth 2D		y = abx / (1+bx) y = y * exp(x)
Hyperbolic A With Exponential Growth 2D		y = (a + x) / (b + x) y = y * (d * exp(x))
Hyperbolic B With Exponential Growth 2D		y = (a + bx) / (c + x) y = y * (f * exp(x))
Hyperbolic C With Exponential Growth 2D		y = (a + x) / (b + cx) y = y * (f * exp(x))
Hyperbolic D With Exponential Growth 2D		y = (a + bx) / (c + dx) y = y * (g * exp(x))
Hyperbolic E With Exponential Growth 2D		y = ax / (b + x) y = y * exp(x)
Hyperbolic F With Exponential Growth 2D		y = ax / (b + x) + cx y = y * (f * exp(x))
Hyperbolic G With Exponential Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (g * exp(x))
Hyperbolic H With Exponential Growth 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (h * exp(x))
Hyperbolic I With Exponential Growth 2D		y = ab / (b + x) y = y * exp(x)
Hyperbolic J With Exponential Growth 2D		y = x / (a + bx) y = y * (d * exp(x))
Hyperbolic Logistic With Exponential Growth 2D		y = axb / (c + xb) y = y * exp(x)
Membrane Transport With Exponential Growth 2D		y = a(x-b) / (x2 + cx + d) y = y * exp(x)
Michaelis-Menten Double With Exponential Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (g * exp(x))
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Growth 2D		y = a / (b + x) y = y * exp(x)
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Growth 2D		y = a / (b + x) + c / (d + x) y = y * (g * exp(x))
Michaelis-Menten Product Accumulation With Exponential Growth 2D		y = a(b-x) / (c + (b-x)) y = y * exp(x)
Michaelis-Menten With Exponential Growth 2D		y = ax / (b + x) y = y * exp(x)
Negative Exponential With Exponential Growth 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x)
New Zealand Ecology Logistic 1 With Exponential Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3))) n = n * (g * exp(x))
New Zealand Ecology Logistic 2 With Exponential Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3))) n = n * (h * exp(x))
Plant Disease Exponential Model With Exponential Growth 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * exp(x)   [web citation]
Plant Disease Gompertz Model With Exponential Growth 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (d * exp(x))   [web citation]
Plant Disease Logistic Model With Exponential Growth 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (d * exp(x))   [web citation]
Plant Disease Monomolecular Model With Exponential Growth 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (d * exp(x))   [web citation]
Plant Disease Weibull Model With Exponential Growth 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence * (f * exp(x))   [web citation]
Preece And Baines Growth With Exponential Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y * (h * exp(x))
Scaled Log Transform With Exponential Growth 2D		y = a * log(bx + c) y = y * exp(x)
Scaled Log With Exponential Growth 2D		y = a * log(x) y = y * exp(x)
Scaled Power Transform With Exponential Growth 2D		y = a * (cx + d)b y = y * exp(x)
Scaled Power With Exponential Growth 2D		y = a * xb y = y * exp(x)
Toby Barrus 3-Parameter Custom Logistic Equation With Exponential Growth 2D		y = d + (a - d) / (1 + (x / c)) y = y * (f * exp(x))
Toby Barrus 4-Parameter Custom Logistic Equation With Exponential Growth 2D		y = d + (a - d) / (1 + (x / c)b) y = y * (g * exp(x))
Toby Barrus 5-Parameter Custom Logistic Equation With Exponential Growth 2D		y = d + (a - d) / (1 + (x / c)b )f y = y * (h * exp(x))
Weibull With Exponential Growth 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y * exp(x)
Xiaogang Peng Immunoassay With Exponential Growth 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * exp(x)
von Bertalanffy Growth With Exponential Growth 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) * exp(x)
Aphid Population Growth With Exponential Growth And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) * exp(x) + Offset   [web citation]
Beverton-Holt A With Exponential Growth And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y * exp(x) + Offset
Beverton-Holt B With Exponential Growth And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y * exp(x) + Offset
BioScience A With Exponential Growth And Offset 2D		y = a * (1.0 - (b * cx)) y = y * exp(x) + Offset
BioScience B With Exponential Growth And Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y * exp(x) + Offset
Cellular Conductance With Exponential Growth And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g * (i * exp(x)) + Offset   [web citation]
Derek Duncan Custom Equation With Exponential Growth And Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y * exp(x) + Offset
Generalized Negative Exponential With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx))c y = y * exp(x) + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Exponential Growth And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (h * exp(x)) + Offset
High-Low Affinity Double With Exponential Growth And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (h * exp(x)) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Exponential Growth And Offset 2D		y = ab / (1+bx) y = y * exp(x) + Offset
High-Low Affinity With Exponential Growth And Offset 2D		y = abx / (1+bx) y = y * exp(x) + Offset
Hyperbolic A With Exponential Growth And Offset 2D		y = (a + x) / (b + x) y = y * (f * exp(x)) + Offset
Hyperbolic B With Exponential Growth And Offset 2D		y = (a + bx) / (c + x) y = y * (g * exp(x)) + Offset
Hyperbolic C With Exponential Growth And Offset 2D		y = (a + x) / (b + cx) y = y * (g * exp(x)) + Offset
Hyperbolic D With Exponential Growth And Offset 2D		y = (a + bx) / (c + dx) y = y * (h * exp(x)) + Offset
Hyperbolic E With Exponential Growth And Offset 2D		y = ax / (b + x) y = y * exp(x) + Offset
Hyperbolic F With Exponential Growth And Offset 2D		y = ax / (b + x) + cx y = y * (g * exp(x)) + Offset
Hyperbolic G With Exponential Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (h * exp(x)) + Offset
Hyperbolic H With Exponential Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (i * exp(x)) + Offset
Hyperbolic I With Exponential Growth And Offset 2D		y = ab / (b + x) y = y * exp(x) + Offset
Hyperbolic J With Exponential Growth And Offset 2D		y = x / (a + bx) y = y * (f * exp(x)) + Offset
Hyperbolic Logistic With Exponential Growth And Offset 2D		y = axb / (c + xb) y = y * exp(x) + Offset
Membrane Transport With Exponential Growth And Offset 2D		y = a(x-b) / (x2 + cx + d) y = y * exp(x) + Offset
Michaelis-Menten Double With Exponential Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (h * exp(x)) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Exponential Growth And Offset 2D		y = a / (b + x) y = y * exp(x) + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Exponential Growth And Offset 2D		y = a / (b + x) + c / (d + x) y = y * (h * exp(x)) + Offset
Michaelis-Menten Product Accumulation With Exponential Growth And Offset 2D		y = a(b-x) / (c + (b-x)) y = y * exp(x) + Offset
Michaelis-Menten With Exponential Growth And Offset 2D		y = ax / (b + x) y = y * exp(x) + Offset
Negative Exponential With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x) + Offset
Plant Disease Exponential Model With Exponential Growth And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * exp(x) + Offset   [web citation]
Plant Disease Gompertz Model With Exponential Growth And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (f * exp(x)) + Offset   [web citation]
Plant Disease Logistic Model With Exponential Growth And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (f * exp(x)) + Offset   [web citation]
Plant Disease Monomolecular Model With Exponential Growth And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (f * exp(x)) + Offset   [web citation]
Plant Disease Weibull Model With Exponential Growth And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence * (g * exp(x)) + Offset   [web citation]
Scaled Log Transform With Exponential Growth And Offset 2D		y = a * log(bx + c) y = y * exp(x) + Offset
Scaled Log With Exponential Growth And Offset 2D		y = a * log(x) y = y * exp(x) + Offset
Scaled Power Transform With Exponential Growth And Offset 2D		y = a * (cx + d)b y = y * exp(x) + Offset
Scaled Power With Exponential Growth And Offset 2D		y = a * xb y = y * exp(x) + Offset
Weibull With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y * exp(x) + Offset
Xiaogang Peng Immunoassay With Exponential Growth And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * exp(x) + Offset
von Bertalanffy Growth With Exponential Growth And Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) * exp(x) + Offset
Inverse Aphid Population Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = x / N(t)   [web citation]
Inverse Beverton-Holt A 2D		y = r / (1 + ((r-1)/K) * x) y = x / y
Inverse BioScience A 2D		y = a * (1.0 - (b * cx)) y = x / y
Inverse BioScience B 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = x / y
Inverse Cellular Conductance 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = x / g   [web citation]
Inverse Derek Duncan Custom Equation 2D		y = a / (1 + exp(-1/b*(x-c)))d y = x / y
Inverse Dose-Response A 2D		y = b + (a-b) / (1 + 10x-c) y = x / y
Inverse Dose-Response B 2D		y = b + (a-b) / (1 + 10c-x) y = x / y
Inverse Dose-Response C 2D		y = b + (a-b) / (1 + 10d*(x-c)) y = x / y
Inverse Dose-Response D 2D		y = b + (a-b) / (1 + 10d*(c-x)) y = x / y
Inverse Dose-Response E 2D		y = b + (a-b) / (1 + (x/c)d) y = x / y
Inverse Generalized Negative Exponential 2D		y = a * (1.0 - exp(-bx))c y = x / y
Inverse Generalized Product Accumulation 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = x / y
Inverse Generalized Substrate Depletion 2D		y = ax / (b + x) - cx - d y = x / y
Inverse High-Low Affinity 2D		y = abx / (1+bx) y = x / y
Inverse High-Low Affinity Double 2D		y = abx / (1+bx) + cdx / (1+dx) y = x / y
Inverse High-Low Affinity Double Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) + cd / (1+dx) y = x / y
Inverse High-Low Affinity Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) y = x / y
Inverse Hyperbolic A 2D		y = (a + x) / (b + x) y = x / y
Inverse Hyperbolic B 2D		y = (a + bx) / (c + x) y = x / y
Inverse Hyperbolic C 2D		y = (a + x) / (b + cx) y = x / y
Inverse Hyperbolic D 2D		y = (a + bx) / (c + dx) y = x / y
Inverse Hyperbolic E 2D		y = ax / (b + x) y = x / y
Inverse Hyperbolic F 2D		y = ax / (b + x) + cx y = x / y
Inverse Hyperbolic G 2D		y = ax / (b + x) + cx / (d + x) y = x / y
Inverse Hyperbolic H 2D		y = ax / (b + x) + cx / (d + x) + fx y = x / y
Inverse Hyperbolic I 2D		y = ab / (b + x) y = x / y
Inverse Hyperbolic Logistic 2D		y = axb / (c + xb) y = x / y
Inverse Membrane Transport 2D		y = a(x-b) / (x2 + cx + d) y = x / y
Inverse Michaelis-Menten 2D		y = ax / (b + x) y = x / y
Inverse Michaelis-Menten Double 2D		y = ax / (b + x) + cx / (d + x) y = x / y
Inverse Michaelis-Menten Isotope Displacement ([Hot] subsumed) 2D		y = a / (b + x) y = x / y
Inverse Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) 2D		y = a / (b + x) + c / (d + x) y = x / y
Inverse Michaelis-Menten Product Accumulation 2D		y = a(b-x) / (c + (b-x)) y = x / y
Inverse Negative Exponential 2D		y = a * (1.0 - exp(-bx)) y = x / y
Inverse New Zealand Ecology Logistic 1 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3))) n = x / n
Inverse New Zealand Ecology Logistic 2 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3))) n = x / n
Inverse Plant Disease Exponential Model 2D		Incidence = y0 * exp(r * time) Incidence = x / Incidence   [web citation]
Inverse Plant Disease Gompertz Model 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = x / Incidence   [web citation]
Inverse Plant Disease Logistic Model 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = x / Incidence   [web citation]
Inverse Plant Disease Monomolecular Model 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = x / Incidence   [web citation]
Inverse Plant Disease Weibull Model 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = x / Incidence   [web citation]
Inverse Preece And Baines Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = x / y
Inverse Scaled Log 2D		y = a * log(x) y = x / y
Inverse Scaled Log Transform 2D		y = a * log(bx + c) y = x / y
Inverse Scaled Power Transform 2D		y = a * (cx + d)b y = x / y
Inverse Toby Barrus 3-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)) y = x / y
Inverse Toby Barrus 4-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)b) y = x / y
Inverse Toby Barrus 5-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)b )f y = x / y
Inverse Weibull 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = x / y
Inverse Xiaogang Peng Immunoassay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = x / y
Inverse von Bertalanffy Growth 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = x / L(t)
Inverse Aphid Population Growth With Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = x / N(t) + Offset   [web citation]
Inverse Beverton-Holt A With Offset 2D		y = r / (1 + ((r-1)/K) * x) y = x / y + Offset
Inverse BioScience A With Offset 2D		y = a * (1.0 - (b * cx)) y = x / y + Offset
Inverse BioScience B With Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = x / y + Offset
Inverse Cellular Conductance With Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = x / g + Offset   [web citation]
Inverse Derek Duncan Custom Equation With Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d y = x / y + Offset
Inverse Generalized Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx))c y = x / y + Offset
Inverse High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = x / y + Offset
Inverse High-Low Affinity Double With Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = x / y + Offset
Inverse High-Low Affinity Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) y = x / y + Offset
Inverse High-Low Affinity With Offset 2D		y = abx / (1+bx) y = x / y + Offset
Inverse Hyperbolic A With Offset 2D		y = (a + x) / (b + x) y = x / y + Offset
Inverse Hyperbolic B With Offset 2D		y = (a + bx) / (c + x) y = x / y + Offset
Inverse Hyperbolic C With Offset 2D		y = (a + x) / (b + cx) y = x / y + Offset
Inverse Hyperbolic D With Offset 2D		y = (a + bx) / (c + dx) y = x / y + Offset
Inverse Hyperbolic E With Offset 2D		y = ax / (b + x) y = x / y + Offset
Inverse Hyperbolic F With Offset 2D		y = ax / (b + x) + cx y = x / y + Offset
Inverse Hyperbolic G With Offset 2D		y = ax / (b + x) + cx / (d + x) y = x / y + Offset
Inverse Hyperbolic H With Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = x / y + Offset
Inverse Hyperbolic I With Offset 2D		y = ab / (b + x) y = x / y + Offset
Inverse Hyperbolic Logistic With Offset 2D		y = axb / (c + xb) y = x / y + Offset
Inverse Membrane Transport With Offset 2D		y = a(x-b) / (x2 + cx + d) y = x / y + Offset
Inverse Michaelis-Menten Double With Offset 2D		y = ax / (b + x) + cx / (d + x) y = x / y + Offset
Inverse Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Offset 2D		y = a / (b + x) y = x / y + Offset
Inverse Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Offset 2D		y = a / (b + x) + c / (d + x) y = x / y + Offset
Inverse Michaelis-Menten Product Accumulation With Offset 2D		y = a(b-x) / (c + (b-x)) y = x / y + Offset
Inverse Michaelis-Menten With Offset 2D		y = ax / (b + x) y = x / y + Offset
Inverse Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx)) y = x / y + Offset
Inverse Plant Disease Exponential Model With Offset 2D		Incidence = y0 * exp(r * time) Incidence = x / Incidence + Offset   [web citation]
Inverse Plant Disease Gompertz Model With Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = x / Incidence + Offset   [web citation]
Inverse Plant Disease Logistic Model With Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = x / Incidence + Offset   [web citation]
Inverse Plant Disease Monomolecular Model With Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = x / Incidence + Offset   [web citation]
Inverse Plant Disease Weibull Model With Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = x / Incidence + Offset   [web citation]
Inverse Scaled Log Transform With Offset 2D		y = a * log(bx + c) y = x / y + Offset
Inverse Scaled Log With Offset 2D		y = a * log(x) y = x / y + Offset
Inverse Scaled Power Transform With Offset 2D		y = a * (cx + d)b y = x / y + Offset
Inverse Weibull With Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = x / y + Offset
Inverse Xiaogang Peng Immunoassay With Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = x / y + Offset
Inverse von Bertalanffy Growth With Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = x / L(t) + Offset
Aphid Population Growth With Linear Decay 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) / x   [web citation]
Beverton-Holt A With Linear Decay 2D		y = r / (1 + ((r-1)/K) * x) y = y / x
Beverton-Holt B With Linear Decay 2D		y = rx / (1 + ((r-1)/K) * x) y = y / x
BioScience A With Linear Decay 2D		y = a * (1.0 - (b * cx)) y = y / x
BioScience B With Linear Decay 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y / x
Cellular Conductance With Linear Decay 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g / (h * x)   [web citation]
Derek Duncan Custom Equation With Linear Decay 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y / x
Dose-Response A With Linear Decay 2D		y = b + (a-b) / (1 + 10x-c) y = y / (f * x)
Dose-Response B With Linear Decay 2D		y = b + (a-b) / (1 + 10c-x) y = y / (f * x)
Dose-Response C With Linear Decay 2D		y = b + (a-b) / (1 + 10d*(x-c)) y = y / (g * x)
Dose-Response D With Linear Decay 2D		y = b + (a-b) / (1 + 10d*(c-x)) y = y / (g * x)
Dose-Response E With Linear Decay 2D		y = b + (a-b) / (1 + (x/c)d) y = y / (g * x)
Generalized Negative Exponential With Linear Decay 2D		y = a * (1.0 - exp(-bx))c y = y / x
Generalized Product Accumulation With Linear Decay 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y / (h * x)
Generalized Substrate Depletion With Linear Decay 2D		y = ax / (b + x) - cx - d y = y / (g * x)
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Decay 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (g * x)
High-Low Affinity Double With Linear Decay 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (g * x)
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Decay 2D		y = ab / (1+bx) y = y / x
High-Low Affinity With Linear Decay 2D		y = abx / (1+bx) y = y / x
Hyperbolic A With Linear Decay 2D		y = (a + x) / (b + x) y = y / (d * x)
Hyperbolic B With Linear Decay 2D		y = (a + bx) / (c + x) y = y / (f * x)
Hyperbolic C With Linear Decay 2D		y = (a + x) / (b + cx) y = y / (f * x)
Hyperbolic D With Linear Decay 2D		y = (a + bx) / (c + dx) y = y / (g * x)
Hyperbolic E With Linear Decay 2D		y = ax / (b + x) y = y / x
Hyperbolic F With Linear Decay 2D		y = ax / (b + x) + cx y = y / (f * x)
Hyperbolic G With Linear Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (g * x)
Hyperbolic H With Linear Decay 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (h * x)
Hyperbolic I With Linear Decay 2D		y = ab / (b + x) y = y / x
Hyperbolic J With Linear Decay 2D		y = x / (a + bx) y = y / (d * x)
Hyperbolic Logistic With Linear Decay 2D		y = axb / (c + xb) y = y / x
Membrane Transport With Linear Decay 2D		y = a(x-b) / (x2 + cx + d) y = y / x
Michaelis-Menten Double With Linear Decay 2D		y = ax / (b + x) + cx / (d + x) y = y / (g * x)
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Decay 2D		y = a / (b + x) y = y / x
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Decay 2D		y = a / (b + x) + c / (d + x) y = y / (g * x)
Michaelis-Menten Product Accumulation With Linear Decay 2D		y = a(b-x) / (c + (b-x)) y = y / x
Michaelis-Menten With Linear Decay 2D		y = ax / (b + x) y = y / x
Negative Exponential With Linear Decay 2D		y = a * (1.0 - exp(-bx)) y = y / x
New Zealand Ecology Logistic 1 With Linear Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3))) n = n / (g * x)
New Zealand Ecology Logistic 2 With Linear Decay 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3))) n = n / (h * x)
Plant Disease Exponential Model With Linear Decay 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / x   [web citation]
Plant Disease Gompertz Model With Linear Decay 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (d * x)   [web citation]
Plant Disease Logistic Model With Linear Decay 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (d * x)   [web citation]
Plant Disease Monomolecular Model With Linear Decay 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (d * x)   [web citation]
Plant Disease Weibull Model With Linear Decay 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence / (f * x)   [web citation]
Preece And Baines Growth With Linear Decay 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y / (h * x)
Scaled Log Transform With Linear Decay 2D		y = a * log(bx + c) y = y / x
Scaled Log With Linear Decay 2D		y = a * log(x) y = y / x
Scaled Power Transform With Linear Decay 2D		y = a * (cx + d)b y = y / x
Scaled Power With Linear Decay 2D		y = a * xb y = y / x
Toby Barrus 3-Parameter Custom Logistic Equation With Linear Decay 2D		y = d + (a - d) / (1 + (x / c)) y = y / (f * x)
Toby Barrus 4-Parameter Custom Logistic Equation With Linear Decay 2D		y = d + (a - d) / (1 + (x / c)b) y = y / (g * x)
Toby Barrus 5-Parameter Custom Logistic Equation With Linear Decay 2D		y = d + (a - d) / (1 + (x / c)b )f y = y / (h * x)
Weibull With Linear Decay 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y / x
Xiaogang Peng Immunoassay With Linear Decay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / x
von Bertalanffy Growth With Linear Decay 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) / x
Aphid Population Growth With Linear Decay And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) / x + Offset   [web citation]
Beverton-Holt A With Linear Decay And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y / x + Offset
Beverton-Holt B With Linear Decay And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y / x + Offset
BioScience A With Linear Decay And Offset 2D		y = a * (1.0 - (b * cx)) y = y / x + Offset
BioScience B With Linear Decay And Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y / x + Offset
Cellular Conductance With Linear Decay And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g / (i * x) + Offset   [web citation]
Derek Duncan Custom Equation With Linear Decay And Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y / x + Offset
Generalized Negative Exponential With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx))c y = y / x + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Decay And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y / (h * x) + Offset
High-Low Affinity Double With Linear Decay And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y / (h * x) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Decay And Offset 2D		y = ab / (1+bx) y = y / x + Offset
High-Low Affinity With Linear Decay And Offset 2D		y = abx / (1+bx) y = y / x + Offset
Hyperbolic A With Linear Decay And Offset 2D		y = (a + x) / (b + x) y = y / (f * x) + Offset
Hyperbolic B With Linear Decay And Offset 2D		y = (a + bx) / (c + x) y = y / (g * x) + Offset
Hyperbolic C With Linear Decay And Offset 2D		y = (a + x) / (b + cx) y = y / (g * x) + Offset
Hyperbolic D With Linear Decay And Offset 2D		y = (a + bx) / (c + dx) y = y / (h * x) + Offset
Hyperbolic E With Linear Decay And Offset 2D		y = ax / (b + x) y = y / x + Offset
Hyperbolic F With Linear Decay And Offset 2D		y = ax / (b + x) + cx y = y / (g * x) + Offset
Hyperbolic G With Linear Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (h * x) + Offset
Hyperbolic H With Linear Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y / (i * x) + Offset
Hyperbolic I With Linear Decay And Offset 2D		y = ab / (b + x) y = y / x + Offset
Hyperbolic J With Linear Decay And Offset 2D		y = x / (a + bx) y = y / (f * x) + Offset
Hyperbolic Logistic With Linear Decay And Offset 2D		y = axb / (c + xb) y = y / x + Offset
Membrane Transport With Linear Decay And Offset 2D		y = a(x-b) / (x2 + cx + d) y = y / x + Offset
Michaelis-Menten Double With Linear Decay And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y / (h * x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Decay And Offset 2D		y = a / (b + x) y = y / x + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Decay And Offset 2D		y = a / (b + x) + c / (d + x) y = y / (h * x) + Offset
Michaelis-Menten Product Accumulation With Linear Decay And Offset 2D		y = a(b-x) / (c + (b-x)) y = y / x + Offset
Michaelis-Menten With Linear Decay And Offset 2D		y = ax / (b + x) y = y / x + Offset
Negative Exponential With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / x + Offset
Plant Disease Exponential Model With Linear Decay And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence / x + Offset   [web citation]
Plant Disease Gompertz Model With Linear Decay And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence / (f * x) + Offset   [web citation]
Plant Disease Logistic Model With Linear Decay And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence / (f * x) + Offset   [web citation]
Plant Disease Monomolecular Model With Linear Decay And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence / (f * x) + Offset   [web citation]
Plant Disease Weibull Model With Linear Decay And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence / (g * x) + Offset   [web citation]
Scaled Log Transform With Linear Decay And Offset 2D		y = a * log(bx + c) y = y / x + Offset
Scaled Log With Linear Decay And Offset 2D		y = a * log(x) y = y / x + Offset
Scaled Power Transform With Linear Decay And Offset 2D		y = a * (cx + d)b y = y / x + Offset
Scaled Power With Linear Decay And Offset 2D		y = a * xb y = y / x + Offset
Weibull With Linear Decay And Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y / x + Offset
Xiaogang Peng Immunoassay With Linear Decay And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y / x + Offset
von Bertalanffy Growth With Linear Decay And Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) / x + Offset
Aphid Population Growth With Linear Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) * x   [web citation]
Beverton-Holt A With Linear Growth 2D		y = r / (1 + ((r-1)/K) * x) y = y * x
Beverton-Holt B With Linear Growth 2D		y = rx / (1 + ((r-1)/K) * x) y = y * x
BioScience A With Linear Growth 2D		y = a * (1.0 - (b * cx)) y = y * x
BioScience B With Linear Growth 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y * x
Cellular Conductance With Linear Growth 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g * (h * x) + Offset   [web citation]
Derek Duncan Custom Equation With Linear Growth 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y * x
Dose-Response A With Linear Growth 2D		y = b + (a-b) / (1 + 10x-c) y = y * (f * x) + Offset
Dose-Response B With Linear Growth 2D		y = b + (a-b) / (1 + 10c-x) y = y * (f * x) + Offset
Dose-Response C With Linear Growth 2D		y = b + (a-b) / (1 + 10d*(x-c)) y = y * (g * x) + Offset
Dose-Response D With Linear Growth 2D		y = b + (a-b) / (1 + 10d*(c-x)) y = y * (g * x) + Offset
Dose-Response E With Linear Growth 2D		y = b + (a-b) / (1 + (x/c)d) y = y * (g * x) + Offset
Generalized Negative Exponential With Linear Growth 2D		y = a * (1.0 - exp(-bx))c y = y * x
Generalized Product Accumulation With Linear Growth 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = y * (h * x) + Offset
Generalized Substrate Depletion With Linear Growth 2D		y = ax / (b + x) - cx - d y = y * (g * x) + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Growth 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (g * x) + Offset
High-Low Affinity Double With Linear Growth 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (g * x) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Growth 2D		y = ab / (1+bx) y = y * x
High-Low Affinity With Linear Growth 2D		y = abx / (1+bx) y = y * x
Hyperbolic A With Linear Growth 2D		y = (a + x) / (b + x) y = y * (d * x) + Offset
Hyperbolic B With Linear Growth 2D		y = (a + bx) / (c + x) y = y * (f * x) + Offset
Hyperbolic C With Linear Growth 2D		y = (a + x) / (b + cx) y = y * (f * x) + Offset
Hyperbolic D With Linear Growth 2D		y = (a + bx) / (c + dx) y = y * (g * x) + Offset
Hyperbolic E With Linear Growth 2D		y = ax / (b + x) y = y * x
Hyperbolic F With Linear Growth 2D		y = ax / (b + x) + cx y = y * (f * x) + Offset
Hyperbolic G With Linear Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (g * x) + Offset
Hyperbolic H With Linear Growth 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (h * x) + Offset
Hyperbolic I With Linear Growth 2D		y = ab / (b + x) y = y * x
Hyperbolic J With Linear Growth 2D		y = x / (a + bx) y = y * (d * x) + Offset
Hyperbolic Logistic With Linear Growth 2D		y = axb / (c + xb) y = y * x
Membrane Transport With Linear Growth 2D		y = a(x-b) / (x2 + cx + d) y = y * x
Michaelis-Menten Double With Linear Growth 2D		y = ax / (b + x) + cx / (d + x) y = y * (g * x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Growth 2D		y = a / (b + x) y = y * x
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Growth 2D		y = a / (b + x) + c / (d + x) y = y * (g * x) + Offset
Michaelis-Menten Product Accumulation With Linear Growth 2D		y = a(b-x) / (c + (b-x)) y = y * x
Michaelis-Menten With Linear Growth 2D		y = ax / (b + x) y = y * x
Negative Exponential With Linear Growth 2D		y = a * (1.0 - exp(-bx)) y = y * x
New Zealand Ecology Logistic 1 With Linear Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3))) n = n * (g * x) + Offset
New Zealand Ecology Logistic 2 With Linear Growth 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3))) n = n * (h * x) + Offset
Plant Disease Exponential Model With Linear Growth 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * x   [web citation]
Plant Disease Gompertz Model With Linear Growth 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (d * x) + Offset   [web citation]
Plant Disease Logistic Model With Linear Growth 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (d * x) + Offset   [web citation]
Plant Disease Monomolecular Model With Linear Growth 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (d * x) + Offset   [web citation]
Plant Disease Weibull Model With Linear Growth 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence * (f * x) + Offset   [web citation]
Preece And Baines Growth With Linear Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = y * (h * x) + Offset
Scaled Log Transform With Linear Growth 2D		y = a * log(bx + c) y = y * x
Scaled Log With Linear Growth 2D		y = a * log(x) y = y * x
Scaled Power Transform With Linear Growth 2D		y = a * (cx + d)b y = y * x
Scaled Power With Linear Growth 2D		y = a * xb y = y * x
Toby Barrus 3-Parameter Custom Logistic Equation With Linear Growth 2D		y = d + (a - d) / (1 + (x / c)) y = y * (f * x) + Offset
Toby Barrus 4-Parameter Custom Logistic Equation With Linear Growth 2D		y = d + (a - d) / (1 + (x / c)b) y = y * (g * x) + Offset
Toby Barrus 5-Parameter Custom Logistic Equation With Linear Growth 2D		y = d + (a - d) / (1 + (x / c)b )f y = y * (h * x) + Offset
Weibull With Linear Growth 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y * x
Xiaogang Peng Immunoassay With Linear Growth 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * x
von Bertalanffy Growth With Linear Growth 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) * x
Aphid Population Growth With Linear Growth And Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = N(t) * x + Offset   [web citation]
Beverton-Holt A With Linear Growth And Offset 2D		y = r / (1 + ((r-1)/K) * x) y = y * x + Offset
Beverton-Holt B With Linear Growth And Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = y * x + Offset
BioScience A With Linear Growth And Offset 2D		y = a * (1.0 - (b * cx)) y = y * x + Offset
BioScience B With Linear Growth And Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = y * x + Offset
Cellular Conductance With Linear Growth And Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = g * (i * x) + Offset   [web citation]
Derek Duncan Custom Equation With Linear Growth And Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d y = y * x + Offset
Generalized Negative Exponential With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx))c y = y * x + Offset
High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Linear Growth And Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = y * (h * x) + Offset
High-Low Affinity Double With Linear Growth And Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = y * (h * x) + Offset
High-Low Affinity Isotope Displacement ([Hot] subsumed) With Linear Growth And Offset 2D		y = ab / (1+bx) y = y * x + Offset
High-Low Affinity With Linear Growth And Offset 2D		y = abx / (1+bx) y = y * x + Offset
Hyperbolic A With Linear Growth And Offset 2D		y = (a + x) / (b + x) y = y * (f * x) + Offset
Hyperbolic B With Linear Growth And Offset 2D		y = (a + bx) / (c + x) y = y * (g * x) + Offset
Hyperbolic C With Linear Growth And Offset 2D		y = (a + x) / (b + cx) y = y * (g * x) + Offset
Hyperbolic D With Linear Growth And Offset 2D		y = (a + bx) / (c + dx) y = y * (h * x) + Offset
Hyperbolic E With Linear Growth And Offset 2D		y = ax / (b + x) y = y * x + Offset
Hyperbolic F With Linear Growth And Offset 2D		y = ax / (b + x) + cx y = y * (g * x) + Offset
Hyperbolic G With Linear Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (h * x) + Offset
Hyperbolic H With Linear Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = y * (i * x) + Offset
Hyperbolic I With Linear Growth And Offset 2D		y = ab / (b + x) y = y * x + Offset
Hyperbolic J With Linear Growth And Offset 2D		y = x / (a + bx) y = y * (f * x) + Offset
Hyperbolic Logistic With Linear Growth And Offset 2D		y = axb / (c + xb) y = y * x + Offset
Membrane Transport With Linear Growth And Offset 2D		y = a(x-b) / (x2 + cx + d) y = y * x + Offset
Michaelis-Menten Double With Linear Growth And Offset 2D		y = ax / (b + x) + cx / (d + x) y = y * (h * x) + Offset
Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Linear Growth And Offset 2D		y = a / (b + x) y = y * x + Offset
Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Linear Growth And Offset 2D		y = a / (b + x) + c / (d + x) y = y * (h * x) + Offset
Michaelis-Menten Product Accumulation With Linear Growth And Offset 2D		y = a(b-x) / (c + (b-x)) y = y * x + Offset
Michaelis-Menten With Linear Growth And Offset 2D		y = ax / (b + x) y = y * x + Offset
Negative Exponential With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * x + Offset
Plant Disease Exponential Model With Linear Growth And Offset 2D		Incidence = y0 * exp(r * time) Incidence = Incidence * x + Offset   [web citation]
Plant Disease Gompertz Model With Linear Growth And Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = Incidence * (f * x) + Offset   [web citation]
Plant Disease Logistic Model With Linear Growth And Offset 2D		Incidence = 1 / (1 + (1 - y0) / (y0 * exp(-r * time))) Incidence = Incidence * (f * x) + Offset   [web citation]
Plant Disease Monomolecular Model With Linear Growth And Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = Incidence * (f * x) + Offset   [web citation]
Plant Disease Weibull Model With Linear Growth And Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = Incidence * (g * x) + Offset   [web citation]
Scaled Log Transform With Linear Growth And Offset 2D		y = a * log(bx + c) y = y * x + Offset
Scaled Log With Linear Growth And Offset 2D		y = a * log(x) y = y * x + Offset
Scaled Power Transform With Linear Growth And Offset 2D		y = a * (cx + d)b y = y * x + Offset
Scaled Power With Linear Growth And Offset 2D		y = a * xb y = y * x + Offset
Weibull With Linear Growth And Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = y * x + Offset
Xiaogang Peng Immunoassay With Linear Growth And Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = y * x + Offset
von Bertalanffy Growth With Linear Growth And Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = L(t) * x + Offset
Reciprocal Aphid Population Growth 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = 1.0 / N(t)   [web citation]
Reciprocal Beverton-Holt A 2D		y = r / (1 + ((r-1)/K) * x) y = 1.0 / y
Reciprocal Beverton-Holt B 2D		y = rx / (1 + ((r-1)/K) * x) y = 1.0 / y
Reciprocal BioScience A 2D		y = a * (1.0 - (b * cx)) y = 1.0 / y
Reciprocal BioScience B 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = 1.0 / y
Reciprocal Cellular Conductance 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = 1.0 / g   [web citation]
Reciprocal Derek Duncan Custom Equation 2D		y = a / (1 + exp(-1/b*(x-c)))d y = 1.0 / y
Reciprocal Dose-Response A 2D		y = b + (a-b) / (1 + 10x-c) y = 1.0 / y
Reciprocal Dose-Response B 2D		y = b + (a-b) / (1 + 10c-x) y = 1.0 / y
Reciprocal Dose-Response C 2D		y = b + (a-b) / (1 + 10d*(x-c)) y = 1.0 / y
Reciprocal Dose-Response D 2D		y = b + (a-b) / (1 + 10d*(c-x)) y = 1.0 / y
Reciprocal Dose-Response E 2D		y = b + (a-b) / (1 + (x/c)d) y = 1.0 / y
Reciprocal Generalized Negative Exponential 2D		y = a * (1.0 - exp(-bx))c y = 1.0 / y
Reciprocal Generalized Product Accumulation 2D		y = a(b-x) / (c + (b-x)) + d(b-x) + f y = 1.0 / y
Reciprocal Generalized Substrate Depletion 2D		y = ax / (b + x) - cx - d y = 1.0 / y
Reciprocal High-Low Affinity 2D		y = abx / (1+bx) y = 1.0 / y
Reciprocal High-Low Affinity Double 2D		y = abx / (1+bx) + cdx / (1+dx) y = 1.0 / y
Reciprocal High-Low Affinity Double Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) + cd / (1+dx) y = 1.0 / y
Reciprocal High-Low Affinity Isotope Displacement ([Hot] subsumed) 2D		y = ab / (1+bx) y = 1.0 / y
Reciprocal Hyperbolic B 2D		y = (a + bx) / (c + x) y = 1.0 / y
Reciprocal Hyperbolic C 2D		y = (a + x) / (b + cx) y = 1.0 / y
Reciprocal Hyperbolic E 2D		y = ax / (b + x) y = 1.0 / y
Reciprocal Hyperbolic F 2D		y = ax / (b + x) + cx y = 1.0 / y
Reciprocal Hyperbolic G 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y
Reciprocal Hyperbolic H 2D		y = ax / (b + x) + cx / (d + x) + fx y = 1.0 / y
Reciprocal Hyperbolic I 2D		y = ab / (b + x) y = 1.0 / y
Reciprocal Hyperbolic J 2D		y = x / (a + bx) y = 1.0 / y
Reciprocal Hyperbolic Logistic 2D		y = axb / (c + xb) y = 1.0 / y
Reciprocal Membrane Transport 2D		y = a(x-b) / (x2 + cx + d) y = 1.0 / y
Reciprocal Michaelis-Menten 2D		y = ax / (b + x) y = 1.0 / y
Reciprocal Michaelis-Menten Double 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y
Reciprocal Michaelis-Menten Isotope Displacement ([Hot] subsumed) 2D		y = a / (b + x) y = 1.0 / y
Reciprocal Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) 2D		y = a / (b + x) + c / (d + x) y = 1.0 / y
Reciprocal Michaelis-Menten Product Accumulation 2D		y = a(b-x) / (c + (b-x)) y = 1.0 / y
Reciprocal Negative Exponential 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y
Reciprocal New Zealand Ecology Logistic 1 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D) * B3))) n = 1.0 / n
Reciprocal New Zealand Ecology Logistic 2 2D		n = B0 + ((B1 - B0) / (1.0 + exp((B2 - D + (B4*D2)) * B3))) n = 1.0 / n
Reciprocal Plant Disease Exponential Model 2D		Incidence = y0 * exp(r * time) Incidence = 1.0 / Incidence   [web citation]
Reciprocal Plant Disease Gompertz Model 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = 1.0 / Incidence   [web citation]
Reciprocal Plant Disease Monomolecular Model 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = 1.0 / Incidence   [web citation]
Reciprocal Plant Disease Weibull Model 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = 1.0 / Incidence   [web citation]
Reciprocal Preece And Baines Growth 2D		y = a - 2(a-b) / (exp(c(x-d)) + exp(f(x-d))) y = 1.0 / y
Reciprocal Scaled Log 2D		y = a * log(x) y = 1.0 / y
Reciprocal Scaled Log Transform 2D		y = a * log(bx + c) y = 1.0 / y
Reciprocal Scaled Power 2D		y = a * xb y = 1.0 / y
Reciprocal Scaled Power Transform 2D		y = a * (cx + d)b y = 1.0 / y
Reciprocal Toby Barrus 3-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)) y = 1.0 / y
Reciprocal Toby Barrus 4-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)b) y = 1.0 / y
Reciprocal Toby Barrus 5-Parameter Custom Logistic Equation 2D		y = d + (a - d) / (1 + (x / c)b )f y = 1.0 / y
Reciprocal Weibull 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = 1.0 / y
Reciprocal Xiaogang Peng Immunoassay 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = 1.0 / y
Reciprocal von Bertalanffy Growth 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = 1.0 / L(t)
Reciprocal Aphid Population Growth With Offset 2D		N(t) = a * exp(bt) * (1 + c * exp(bt))-2 N(t) = 1.0 / N(t) + Offset   [web citation]
Reciprocal Beverton-Holt A With Offset 2D		y = r / (1 + ((r-1)/K) * x) y = 1.0 / y + Offset
Reciprocal Beverton-Holt B With Offset 2D		y = rx / (1 + ((r-1)/K) * x) y = 1.0 / y + Offset
Reciprocal BioScience A With Offset 2D		y = a * (1.0 - (b * cx)) y = 1.0 / y + Offset
Reciprocal BioScience B With Offset 2D		y = a * (1.0 -(1.0 + (x/b)c)-1.0 * d) y = 1.0 / y + Offset
Reciprocal Cellular Conductance With Offset 2D		g = p3/(1+exp((v-p1)/p2)) + p4*exp((v-45)/p5) g = 1.0 / g + Offset   [web citation]
Reciprocal Derek Duncan Custom Equation With Offset 2D		y = a / (1 + exp(-1/b*(x-c)))d y = 1.0 / y + Offset
Reciprocal Generalized Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx))c y = 1.0 / y + Offset
Reciprocal High-Low Affinity Double Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) + cd / (1+dx) y = 1.0 / y + Offset
Reciprocal High-Low Affinity Double With Offset 2D		y = abx / (1+bx) + cdx / (1+dx) y = 1.0 / y + Offset
Reciprocal High-Low Affinity Isotope Displacement ([Hot] subsumed) With Offset 2D		y = ab / (1+bx) y = 1.0 / y + Offset
Reciprocal High-Low Affinity With Offset 2D		y = abx / (1+bx) y = 1.0 / y + Offset
Reciprocal Hyperbolic B With Offset 2D		y = (a + bx) / (c + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic C With Offset 2D		y = (a + x) / (b + cx) y = 1.0 / y + Offset
Reciprocal Hyperbolic E With Offset 2D		y = ax / (b + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic F With Offset 2D		y = ax / (b + x) + cx y = 1.0 / y + Offset
Reciprocal Hyperbolic G With Offset 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic H With Offset 2D		y = ax / (b + x) + cx / (d + x) + fx y = 1.0 / y + Offset
Reciprocal Hyperbolic I With Offset 2D		y = ab / (b + x) y = 1.0 / y + Offset
Reciprocal Hyperbolic J With Offset 2D		y = x / (a + bx) y = 1.0 / y + Offset
Reciprocal Hyperbolic Logistic With Offset 2D		y = axb / (c + xb) y = 1.0 / y + Offset
Reciprocal Membrane Transport With Offset 2D		y = a(x-b) / (x2 + cx + d) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Double With Offset 2D		y = ax / (b + x) + cx / (d + x) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Isotope Displacement ([Hot] subsumed) With Offset 2D		y = a / (b + x) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Isotope Displacement Double ([Hot] subsumed) With Offset 2D		y = a / (b + x) + c / (d + x) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten Product Accumulation With Offset 2D		y = a(b-x) / (c + (b-x)) y = 1.0 / y + Offset
Reciprocal Michaelis-Menten With Offset 2D		y = ax / (b + x) y = 1.0 / y + Offset
Reciprocal Negative Exponential With Offset 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y + Offset
Reciprocal Plant Disease Exponential Model With Offset 2D		Incidence = y0 * exp(r * time) Incidence = 1.0 / Incidence + Offset   [web citation]
Reciprocal Plant Disease Gompertz Model With Offset 2D		Incidence = exp(ln(y0) * exp(-r * time)) Incidence = 1.0 / Incidence + Offset   [web citation]
Reciprocal Plant Disease Monomolecular Model With Offset 2D		Incidence = 1 - ((1 - y0) * exp(-r * time)) Incidence = 1.0 / Incidence + Offset   [web citation]
Reciprocal Plant Disease Weibull Model With Offset 2D		Incidence = 1 - exp(-1.0 * ((time - a) / b)c) Incidence = 1.0 / Incidence + Offset   [web citation]
Reciprocal Scaled Log Transform With Offset 2D		y = a * log(bx + c) y = 1.0 / y + Offset
Reciprocal Scaled Log With Offset 2D		y = a * log(x) y = 1.0 / y + Offset
Reciprocal Scaled Power Transform With Offset 2D		y = a * (cx + d)b y = 1.0 / y + Offset
Reciprocal Scaled Power With Offset 2D		y = a * xb y = 1.0 / y + Offset
Reciprocal Weibull With Offset 2D		y = a * (1.0 - exp(-b * (x - c)d)) y = 1.0 / y + Offset
Reciprocal Xiaogang Peng Immunoassay With Offset 2D		y = K / (1.0 + exp(-1.0 * (a + blog(x) + cx))) y = 1.0 / y + Offset
Reciprocal von Bertalanffy Growth With Offset 2D		L(t) = Linf * (1.0 - exp(-K * (t-tzero))) L(t) = 1.0 / L(t) + Offset

2D Engineering

Dispersion Optical 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4
Dispersion Optical Square Root 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5
Extended Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3
Ramberg-Osgood 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n)
Reciprocal Extended Steinhart-Hart 2D		T = 1.0 / (A + Bln(R) + C(ln(R))2 + D(ln(R))3)
Reciprocal Steinhart-Hart 2D		T = 1.0 / (A + Bln(R) + C(ln(R))3)
Sellmeier Optical 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3)
Sellmeier Optical Square Root 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5
Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))3
VanDeemter Chromatography 2D		y = a + b/x + cx
Ramberg-Osgood With Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) + Offset
Reciprocal Extended Steinhart-Hart With Offset 2D		T = 1.0 / (A + Bln(R) + C(ln(R))2 + D(ln(R))3) + Offset
Reciprocal Steinhart-Hart With Offset 2D		T = 1.0 / (A + Bln(R) + C(ln(R))3) + Offset
Sellmeier Optical Square Root With Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 + Offset
Sellmeier Optical With Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) + Offset
Dispersion Optical Square Root With Exponential Decay 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5 n = n / (g * exp(x))
Dispersion Optical With Exponential Decay 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4 n2(x) = n2(x) / (g * exp(x))
Extended Steinhart-Hart With Exponential Decay 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3 1/T = 1/T / (g * exp(x))
Ramberg-Osgood With Exponential Decay 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y / (f * exp(x))
Sellmeier Optical Square Root With Exponential Decay 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n / (i * exp(x))
Sellmeier Optical With Exponential Decay 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) / (i * exp(x))
VanDeemter Chromatography With Exponential Decay 2D		y = a + b/x + cx y = y / (f * exp(x))
Ramberg-Osgood With Exponential Decay And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y / (g * exp(x)) + Offset
Sellmeier Optical Square Root With Exponential Decay And Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n / (j * exp(x)) + Offset
Sellmeier Optical With Exponential Decay And Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) / (j * exp(x)) + Offset
Dispersion Optical Square Root With Exponential Growth 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5 n = n * (g * exp(x))
Dispersion Optical With Exponential Growth 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4 n2(x) = n2(x) * (g * exp(x))
Extended Steinhart-Hart With Exponential Growth 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3 1/T = 1/T * (g * exp(x))
Ramberg-Osgood With Exponential Growth 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y * (f * exp(x))
Sellmeier Optical Square Root With Exponential Growth 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n * (i * exp(x))
Sellmeier Optical With Exponential Growth 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) * (i * exp(x))
VanDeemter Chromatography With Exponential Growth 2D		y = a + b/x + cx y = y * (f * exp(x))
Ramberg-Osgood With Exponential Growth And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y * (g * exp(x)) + Offset
Sellmeier Optical Square Root With Exponential Growth And Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n * (j * exp(x)) + Offset
Sellmeier Optical With Exponential Growth And Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) * (j * exp(x)) + Offset
Inverse Dispersion Optical 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4 n2(x) = x / n2(x)
Inverse Dispersion Optical Square Root 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5 n = x / n
Inverse Extended Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3 1/T = x / 1/T
Inverse Ramberg-Osgood 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = x / y
Inverse Sellmeier Optical 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = x / n2(x)
Inverse Sellmeier Optical Square Root 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = x / n
Inverse VanDeemter Chromatography 2D		y = a + b/x + cx y = x / y
Inverse Ramberg-Osgood With Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = x / y + Offset
Inverse Sellmeier Optical Square Root With Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = x / n + Offset
Inverse Sellmeier Optical With Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = x / n2(x) + Offset
Dispersion Optical Square Root With Linear Decay 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5 n = n / (g * x)
Dispersion Optical With Linear Decay 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4 n2(x) = n2(x) / (g * x)
Extended Steinhart-Hart With Linear Decay 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3 1/T = 1/T / (g * x)
Ramberg-Osgood With Linear Decay 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y / (f * x)
Sellmeier Optical Square Root With Linear Decay 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n / (i * x)
Sellmeier Optical With Linear Decay 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) / (i * x)
VanDeemter Chromatography With Linear Decay 2D		y = a + b/x + cx y = y / (f * x)
Ramberg-Osgood With Linear Decay And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y / (g * x) + Offset
Sellmeier Optical Square Root With Linear Decay And Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n / (j * x) + Offset
Sellmeier Optical With Linear Decay And Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) / (j * x) + Offset
Dispersion Optical Square Root With Linear Growth 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5 n = n * (g * x) + Offset
Dispersion Optical With Linear Growth 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4 n2(x) = n2(x) * (g * x) + Offset
Extended Steinhart-Hart With Linear Growth 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3 1/T = 1/T * (g * x) + Offset
Ramberg-Osgood With Linear Growth 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y * (f * x) + Offset
Sellmeier Optical Square Root With Linear Growth 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n * (i * x) + Offset
Sellmeier Optical With Linear Growth 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) * (i * x) + Offset
VanDeemter Chromatography With Linear Growth 2D		y = a + b/x + cx y = y * (f * x) + Offset
Ramberg-Osgood With Linear Growth And Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = y * (g * x) + Offset
Sellmeier Optical Square Root With Linear Growth And Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = n * (j * x) + Offset
Sellmeier Optical With Linear Growth And Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = n2(x) * (j * x) + Offset
Reciprocal Dispersion Optical 2D		n2(x) = A1 + A2*x2 + A3/x2 + A4/x4 n2(x) = 1.0 / n2(x)
Reciprocal Dispersion Optical Square Root 2D		n = (A1 + A2*x2 + A3/x2 + A4/x4)0.5 n = 1.0 / n
Reciprocal Extended Steinhart-Hart 2D		1/T = A + Bln(R) + C(ln(R))2 + D(ln(R))3 1/T = 1.0 / 1/T
Reciprocal Ramberg-Osgood 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = 1.0 / y
Reciprocal Sellmeier Optical 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = 1.0 / n2(x)
Reciprocal Sellmeier Optical Square Root 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = 1.0 / n
Reciprocal VanDeemter Chromatography 2D		y = a + b/x + cx y = 1.0 / y
Reciprocal Ramberg-Osgood With Offset 2D		y = (Stress / Youngs_Modulus) + (Stress/K)(1.0/n) y = 1.0 / y + Offset
Reciprocal Sellmeier Optical Square Root With Offset 2D		n = (1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3))0.5 n = 1.0 / n + Offset
Reciprocal Sellmeier Optical With Offset 2D		n2(x) = 1 + (B1 x2)/(x2-C1) + (B2 x2)/(x2-C2) + (B3 x2)/(x2-C3) n2(x) = 1.0 / n2(x) + Offset

2D Exponential

Asymptotic Exponential A 2D		y = 1.0 - ax
Asymptotic Exponential A Transform 2D		y = 1.0 - abx + c
Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx))
Bruno Torremans Quadruple Exponential 2D		y = Offset - R1 * exp(-x/T1) + R2 * exp(-x/T2) + R3 * exp(-x/T3) + R4 * exp(-x/T4)
Double Exponential 2D		y = a * exp(bx) + c * exp(dx)
Exponential 2D		y = a * exp(bx)
Hocket-Sherby 2D		y = b - (b-a) * exp(-c * (xd))
Hoerl 2D		y = xa * exp(x)
Hoerl Transform 2D		y = (bx + c)a * exp(bx + c)
Inverted Exponential 2D		y = a * exp(b/x)
Inverted Offset Exponential 2D		y = a * exp(b/(x+c))
Offset Exponential 2D		y = a * exp(bx + c)
Scaled Exponential 2D		y = a * exp(x)
Shifted Exponential 2D		y = a * exp(x + b)
Simple Exponential 2D		y = ax
Standard Vapor Pressure 2D		y = exp(a + (b/x) + c*ln(x))
Steve Battison Exponential A 2D		y = exp((a + bx) / (c + dx))
Steve Battison Exponential B 2D		y = a * exp((b + cx) / (d + fx))
Stirling 2D		y = a * (exp(bx) - 1.0) / b
Triple Exponential 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx)
Asymptotic Exponential A Transform With Offset 2D		y = 1.0 - abx + c + Offset
Asymptotic Exponential A With Offset 2D		y = 1.0 - ax + Offset
Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) + Offset
Double Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + Offset
Exponential With Offset 2D		y = a * exp(bx) + Offset
Hoerl Transform With Offset 2D		y = (bx + c)a * exp(bx + c) + Offset
Hoerl With Offset 2D		y = xa * exp(x) + Offset
Inverted Exponential With Offset 2D		y = a * exp(b/x) + Offset
Inverted Offset Exponential With Offset 2D		y = a * exp(b/(x+c)) + Offset
Offset Exponential With Offset 2D		y = a * exp(bx + c) + Offset
Scaled Exponential With Offset 2D		y = a * exp(x) + Offset
Shifted Exponential With Offset 2D		y = a * exp(x + b) + Offset
Simple Exponential With Offset 2D		y = ax + Offset
Standard Vapor Pressure With Offset 2D		y = exp(a + (b/x) + c*ln(x)) + Offset
Steve Battison Exponential A With Offset 2D		y = exp((a + bx) / (c + dx)) + Offset
Steve Battison Exponential B With Offset 2D		y = a * exp((b + cx) / (d + fx)) + Offset
Stirling With Offset 2D		y = a * (exp(bx) - 1.0) / b + Offset
Triple Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) + Offset
Asymptotic Exponential A Transform With Exponential Decay 2D		y = 1.0 - abx + c y = y / (f * exp(x))
Asymptotic Exponential A With Exponential Decay 2D		y = 1.0 - ax y = y / (c * exp(x))
Asymptotic Exponential B With Exponential Decay 2D		y = a * (1.0 - exp(bx)) y = y / exp(x)
Double Exponential With Exponential Decay 2D		y = a * exp(bx) + c * exp(dx) y = y / (g * exp(x))
Exponential With Exponential Decay 2D		y = a * exp(bx) y = y / exp(x)
Hocket-Sherby With Exponential Decay 2D		y = b - (b-a) * exp(-c * (xd)) y = y / (g * exp(x))
Hoerl Transform With Exponential Decay 2D		y = (bx + c)a * exp(bx + c) y = y / (f * exp(x))
Hoerl With Exponential Decay 2D		y = xa * exp(x) y = y / (c * exp(x))
Inverted Exponential With Exponential Decay 2D		y = a * exp(b/x) y = y / exp(x)
Inverted Offset Exponential With Exponential Decay 2D		y = a * exp(b/(x+c)) y = y / exp(x)
Offset Exponential With Exponential Decay 2D		y = a * exp(bx + c) y = y / exp(x)
Scaled Exponential With Exponential Decay 2D		y = a * exp(x) y = y / exp(x)
Shifted Exponential With Exponential Decay 2D		y = a * exp(x + b) y = y / exp(x)
Simple Exponential With Exponential Decay 2D		y = ax y = y / (c * exp(x))
Standard Vapor Pressure With Exponential Decay 2D		y = exp(a + (b/x) + c*ln(x)) y = y / (f * exp(x))
Steve Battison Exponential A With Exponential Decay 2D		y = exp((a + bx) / (c + dx)) y = y / (g * exp(x))
Steve Battison Exponential B With Exponential Decay 2D		y = a * exp((b + cx) / (d + fx)) y = y / exp(x)
Stirling With Exponential Decay 2D		y = a * (exp(bx) - 1.0) / b y = y / exp(x)
Triple Exponential With Exponential Decay 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / exp(x)
Asymptotic Exponential A Transform With Exponential Decay And Offset 2D		y = 1.0 - abx + c y = y / (g * exp(x)) + Offset
Asymptotic Exponential A With Exponential Decay And Offset 2D		y = 1.0 - ax y = y / (d * exp(x)) + Offset
Asymptotic Exponential B With Exponential Decay And Offset 2D		y = a * (1.0 - exp(bx)) y = y / exp(x) + Offset
Double Exponential With Exponential Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y / (h * exp(x)) + Offset
Exponential With Exponential Decay And Offset 2D		y = a * exp(bx) y = y / exp(x) + Offset
Hoerl Transform With Exponential Decay And Offset 2D		y = (bx + c)a * exp(bx + c) y = y / (g * exp(x)) + Offset
Hoerl With Exponential Decay And Offset 2D		y = xa * exp(x) y = y / (d * exp(x)) + Offset
Inverted Exponential With Exponential Decay And Offset 2D		y = a * exp(b/x) y = y / exp(x) + Offset
Inverted Offset Exponential With Exponential Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / exp(x) + Offset
Offset Exponential With Exponential Decay And Offset 2D		y = a * exp(bx + c) y = y / exp(x) + Offset
Scaled Exponential With Exponential Decay And Offset 2D		y = a * exp(x) y = y / exp(x) + Offset
Shifted Exponential With Exponential Decay And Offset 2D		y = a * exp(x + b) y = y / exp(x) + Offset
Simple Exponential With Exponential Decay And Offset 2D		y = ax y = y / (d * exp(x)) + Offset
Standard Vapor Pressure With Exponential Decay And Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = y / (g * exp(x)) + Offset
Steve Battison Exponential A With Exponential Decay And Offset 2D		y = exp((a + bx) / (c + dx)) y = y / (h * exp(x)) + Offset
Steve Battison Exponential B With Exponential Decay And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y / exp(x) + Offset
Stirling With Exponential Decay And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y / exp(x) + Offset
Triple Exponential With Exponential Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / exp(x) + Offset
Asymptotic Exponential A Transform With Exponential Growth 2D		y = 1.0 - abx + c y = y * (f * exp(x))
Asymptotic Exponential A With Exponential Growth 2D		y = 1.0 - ax y = y * (c * exp(x))
Asymptotic Exponential B With Exponential Growth 2D		y = a * (1.0 - exp(bx)) y = y * exp(x)
Double Exponential With Exponential Growth 2D		y = a * exp(bx) + c * exp(dx) y = y * (g * exp(x))
Exponential With Exponential Growth 2D		y = a * exp(bx) y = y * exp(x)
Hocket-Sherby With Exponential Growth 2D		y = b - (b-a) * exp(-c * (xd)) y = y * (g * exp(x))
Hoerl Transform With Exponential Growth 2D		y = (bx + c)a * exp(bx + c) y = y * (f * exp(x))
Hoerl With Exponential Growth 2D		y = xa * exp(x) y = y * (c * exp(x))
Inverted Exponential With Exponential Growth 2D		y = a * exp(b/x) y = y * exp(x)
Inverted Offset Exponential With Exponential Growth 2D		y = a * exp(b/(x+c)) y = y * exp(x)
Offset Exponential With Exponential Growth 2D		y = a * exp(bx + c) y = y * exp(x)
Scaled Exponential With Exponential Growth 2D		y = a * exp(x) y = y * exp(x)
Shifted Exponential With Exponential Growth 2D		y = a * exp(x + b) y = y * exp(x)
Simple Exponential With Exponential Growth 2D		y = ax y = y * (c * exp(x))
Standard Vapor Pressure With Exponential Growth 2D		y = exp(a + (b/x) + c*ln(x)) y = y * (f * exp(x))
Steve Battison Exponential A With Exponential Growth 2D		y = exp((a + bx) / (c + dx)) y = y * (g * exp(x))
Steve Battison Exponential B With Exponential Growth 2D		y = a * exp((b + cx) / (d + fx)) y = y * exp(x)
Stirling With Exponential Growth 2D		y = a * (exp(bx) - 1.0) / b y = y * exp(x)
Triple Exponential With Exponential Growth 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * exp(x)
Asymptotic Exponential A Transform With Exponential Growth And Offset 2D		y = 1.0 - abx + c y = y * (g * exp(x)) + Offset
Asymptotic Exponential A With Exponential Growth And Offset 2D		y = 1.0 - ax y = y * (d * exp(x)) + Offset
Asymptotic Exponential B With Exponential Growth And Offset 2D		y = a * (1.0 - exp(bx)) y = y * exp(x) + Offset
Double Exponential With Exponential Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y * (h * exp(x)) + Offset
Exponential With Exponential Growth And Offset 2D		y = a * exp(bx) y = y * exp(x) + Offset
Hoerl Transform With Exponential Growth And Offset 2D		y = (bx + c)a * exp(bx + c) y = y * (g * exp(x)) + Offset
Hoerl With Exponential Growth And Offset 2D		y = xa * exp(x) y = y * (d * exp(x)) + Offset
Inverted Exponential With Exponential Growth And Offset 2D		y = a * exp(b/x) y = y * exp(x) + Offset
Inverted Offset Exponential With Exponential Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * exp(x) + Offset
Offset Exponential With Exponential Growth And Offset 2D		y = a * exp(bx + c) y = y * exp(x) + Offset
Scaled Exponential With Exponential Growth And Offset 2D		y = a * exp(x) y = y * exp(x) + Offset
Shifted Exponential With Exponential Growth And Offset 2D		y = a * exp(x + b) y = y * exp(x) + Offset
Simple Exponential With Exponential Growth And Offset 2D		y = ax y = y * (d * exp(x)) + Offset
Standard Vapor Pressure With Exponential Growth And Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = y * (g * exp(x)) + Offset
Steve Battison Exponential A With Exponential Growth And Offset 2D		y = exp((a + bx) / (c + dx)) y = y * (h * exp(x)) + Offset
Steve Battison Exponential B With Exponential Growth And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y * exp(x) + Offset
Stirling With Exponential Growth And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y * exp(x) + Offset
Triple Exponential With Exponential Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * exp(x) + Offset
Inverse Asymptotic Exponential A 2D		y = 1.0 - ax y = x / y
Inverse Asymptotic Exponential A Transform 2D		y = 1.0 - abx + c y = x / y
Inverse Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) y = x / y
Inverse Double Exponential 2D		y = a * exp(bx) + c * exp(dx) y = x / y
Inverse Exponential 2D		y = a * exp(bx) y = x / y
Inverse Hocket-Sherby 2D		y = b - (b-a) * exp(-c * (xd)) y = x / y
Inverse Hoerl 2D		y = xa * exp(x) y = x / y
Inverse Hoerl Transform 2D		y = (bx + c)a * exp(bx + c) y = x / y
Inverse Inverted Exponential 2D		y = a * exp(b/x) y = x / y
Inverse Inverted Offset Exponential 2D		y = a * exp(b/(x+c)) y = x / y
Inverse Offset Exponential 2D		y = a * exp(bx + c) y = x / y
Inverse Shifted Exponential 2D		y = a * exp(x + b) y = x / y
Inverse Standard Vapor Pressure 2D		y = exp(a + (b/x) + c*ln(x)) y = x / y
Inverse Steve Battison Exponential A 2D		y = exp((a + bx) / (c + dx)) y = x / y
Inverse Steve Battison Exponential B 2D		y = a * exp((b + cx) / (d + fx)) y = x / y
Inverse Stirling 2D		y = a * (exp(bx) - 1.0) / b y = x / y
Inverse Triple Exponential 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = x / y
Inverse Asymptotic Exponential A Transform With Offset 2D		y = 1.0 - abx + c y = x / y + Offset
Inverse Asymptotic Exponential A With Offset 2D		y = 1.0 - ax y = x / y + Offset
Inverse Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) y = x / y + Offset
Inverse Double Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) y = x / y + Offset
Inverse Exponential With Offset 2D		y = a * exp(bx) y = x / y + Offset
Inverse Hoerl Transform With Offset 2D		y = (bx + c)a * exp(bx + c) y = x / y + Offset
Inverse Hoerl With Offset 2D		y = xa * exp(x) y = x / y + Offset
Inverse Inverted Exponential With Offset 2D		y = a * exp(b/x) y = x / y + Offset
Inverse Inverted Offset Exponential With Offset 2D		y = a * exp(b/(x+c)) y = x / y + Offset
Inverse Offset Exponential With Offset 2D		y = a * exp(bx + c) y = x / y + Offset
Inverse Shifted Exponential With Offset 2D		y = a * exp(x + b) y = x / y + Offset
Inverse Standard Vapor Pressure With Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = x / y + Offset
Inverse Steve Battison Exponential A With Offset 2D		y = exp((a + bx) / (c + dx)) y = x / y + Offset
Inverse Steve Battison Exponential B With Offset 2D		y = a * exp((b + cx) / (d + fx)) y = x / y + Offset
Inverse Stirling With Offset 2D		y = a * (exp(bx) - 1.0) / b y = x / y + Offset
Inverse Triple Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = x / y + Offset
Asymptotic Exponential A Transform With Linear Decay 2D		y = 1.0 - abx + c y = y / (f * x)
Asymptotic Exponential A With Linear Decay 2D		y = 1.0 - ax y = y / (c * x)
Asymptotic Exponential B With Linear Decay 2D		y = a * (1.0 - exp(bx)) y = y / x
Double Exponential With Linear Decay 2D		y = a * exp(bx) + c * exp(dx) y = y / (g * x)
Exponential With Linear Decay 2D		y = a * exp(bx) y = y / x
Hocket-Sherby With Linear Decay 2D		y = b - (b-a) * exp(-c * (xd)) y = y / (g * x)
Hoerl Transform With Linear Decay 2D		y = (bx + c)a * exp(bx + c) y = y / (f * x)
Hoerl With Linear Decay 2D		y = xa * exp(x) y = y / (c * x)
Inverted Exponential With Linear Decay 2D		y = a * exp(b/x) y = y / x
Inverted Offset Exponential With Linear Decay 2D		y = a * exp(b/(x+c)) y = y / x
Offset Exponential With Linear Decay 2D		y = a * exp(bx + c) y = y / x
Scaled Exponential With Linear Decay 2D		y = a * exp(x) y = y / x
Shifted Exponential With Linear Decay 2D		y = a * exp(x + b) y = y / x
Simple Exponential With Linear Decay 2D		y = ax y = y / (c * x)
Standard Vapor Pressure With Linear Decay 2D		y = exp(a + (b/x) + c*ln(x)) y = y / (f * x)
Steve Battison Exponential A With Linear Decay 2D		y = exp((a + bx) / (c + dx)) y = y / (g * x)
Steve Battison Exponential B With Linear Decay 2D		y = a * exp((b + cx) / (d + fx)) y = y / x
Stirling With Linear Decay 2D		y = a * (exp(bx) - 1.0) / b y = y / x
Triple Exponential With Linear Decay 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / x
Asymptotic Exponential A Transform With Linear Decay And Offset 2D		y = 1.0 - abx + c y = y / (g * x) + Offset
Asymptotic Exponential A With Linear Decay And Offset 2D		y = 1.0 - ax y = y / (d * x) + Offset
Asymptotic Exponential B With Linear Decay And Offset 2D		y = a * (1.0 - exp(bx)) y = y / x + Offset
Double Exponential With Linear Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y / (h * x) + Offset
Exponential With Linear Decay And Offset 2D		y = a * exp(bx) y = y / x + Offset
Hoerl Transform With Linear Decay And Offset 2D		y = (bx + c)a * exp(bx + c) y = y / (g * x) + Offset
Hoerl With Linear Decay And Offset 2D		y = xa * exp(x) y = y / (d * x) + Offset
Inverted Exponential With Linear Decay And Offset 2D		y = a * exp(b/x) y = y / x + Offset
Inverted Offset Exponential With Linear Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / x + Offset
Offset Exponential With Linear Decay And Offset 2D		y = a * exp(bx + c) y = y / x + Offset
Scaled Exponential With Linear Decay And Offset 2D		y = a * exp(x) y = y / x + Offset
Shifted Exponential With Linear Decay And Offset 2D		y = a * exp(x + b) y = y / x + Offset
Simple Exponential With Linear Decay And Offset 2D		y = ax y = y / (d * x) + Offset
Standard Vapor Pressure With Linear Decay And Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = y / (g * x) + Offset
Steve Battison Exponential A With Linear Decay And Offset 2D		y = exp((a + bx) / (c + dx)) y = y / (h * x) + Offset
Steve Battison Exponential B With Linear Decay And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y / x + Offset
Stirling With Linear Decay And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y / x + Offset
Triple Exponential With Linear Decay And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y / x + Offset
Asymptotic Exponential A Transform With Linear Growth 2D		y = 1.0 - abx + c y = y * (f * x) + Offset
Asymptotic Exponential A With Linear Growth 2D		y = 1.0 - ax y = y * (c * x) + Offset
Asymptotic Exponential B With Linear Growth 2D		y = a * (1.0 - exp(bx)) y = y * x
Double Exponential With Linear Growth 2D		y = a * exp(bx) + c * exp(dx) y = y * (g * x) + Offset
Exponential With Linear Growth 2D		y = a * exp(bx) y = y * x
Hocket-Sherby With Linear Growth 2D		y = b - (b-a) * exp(-c * (xd)) y = y * (g * x) + Offset
Hoerl Transform With Linear Growth 2D		y = (bx + c)a * exp(bx + c) y = y * (f * x) + Offset
Hoerl With Linear Growth 2D		y = xa * exp(x) y = y * (c * x) + Offset
Inverted Exponential With Linear Growth 2D		y = a * exp(b/x) y = y * x
Inverted Offset Exponential With Linear Growth 2D		y = a * exp(b/(x+c)) y = y * x
Offset Exponential With Linear Growth 2D		y = a * exp(bx + c) y = y * x
Scaled Exponential With Linear Growth 2D		y = a * exp(x) y = y * x
Shifted Exponential With Linear Growth 2D		y = a * exp(x + b) y = y * x
Simple Exponential With Linear Growth 2D		y = ax y = y * (c * x) + Offset
Standard Vapor Pressure With Linear Growth 2D		y = exp(a + (b/x) + c*ln(x)) y = y * (f * x) + Offset
Steve Battison Exponential A With Linear Growth 2D		y = exp((a + bx) / (c + dx)) y = y * (g * x) + Offset
Steve Battison Exponential B With Linear Growth 2D		y = a * exp((b + cx) / (d + fx)) y = y * x
Stirling With Linear Growth 2D		y = a * (exp(bx) - 1.0) / b y = y * x
Triple Exponential With Linear Growth 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * x
Asymptotic Exponential A Transform With Linear Growth And Offset 2D		y = 1.0 - abx + c y = y * (g * x) + Offset
Asymptotic Exponential A With Linear Growth And Offset 2D		y = 1.0 - ax y = y * (d * x) + Offset
Asymptotic Exponential B With Linear Growth And Offset 2D		y = a * (1.0 - exp(bx)) y = y * x + Offset
Double Exponential With Linear Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) y = y * (h * x) + Offset
Exponential With Linear Growth And Offset 2D		y = a * exp(bx) y = y * x + Offset
Hoerl Transform With Linear Growth And Offset 2D		y = (bx + c)a * exp(bx + c) y = y * (g * x) + Offset
Hoerl With Linear Growth And Offset 2D		y = xa * exp(x) y = y * (d * x) + Offset
Inverted Exponential With Linear Growth And Offset 2D		y = a * exp(b/x) y = y * x + Offset
Inverted Offset Exponential With Linear Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * x + Offset
Offset Exponential With Linear Growth And Offset 2D		y = a * exp(bx + c) y = y * x + Offset
Scaled Exponential With Linear Growth And Offset 2D		y = a * exp(x) y = y * x + Offset
Shifted Exponential With Linear Growth And Offset 2D		y = a * exp(x + b) y = y * x + Offset
Simple Exponential With Linear Growth And Offset 2D		y = ax y = y * (d * x) + Offset
Standard Vapor Pressure With Linear Growth And Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = y * (g * x) + Offset
Steve Battison Exponential A With Linear Growth And Offset 2D		y = exp((a + bx) / (c + dx)) y = y * (h * x) + Offset
Steve Battison Exponential B With Linear Growth And Offset 2D		y = a * exp((b + cx) / (d + fx)) y = y * x + Offset
Stirling With Linear Growth And Offset 2D		y = a * (exp(bx) - 1.0) / b y = y * x + Offset
Triple Exponential With Linear Growth And Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = y * x + Offset
Reciprocal Asymptotic Exponential A 2D		y = 1.0 - ax y = 1.0 / y
Reciprocal Asymptotic Exponential A Transform 2D		y = 1.0 - abx + c y = 1.0 / y
Reciprocal Asymptotic Exponential B 2D		y = a * (1.0 - exp(bx)) y = 1.0 / y
Reciprocal Double Exponential 2D		y = a * exp(bx) + c * exp(dx) y = 1.0 / y
Reciprocal Exponential 2D		y = a * exp(bx) y = 1.0 / y
Reciprocal Hocket-Sherby 2D		y = b - (b-a) * exp(-c * (xd)) y = 1.0 / y
Reciprocal Hoerl 2D		y = xa * exp(x) y = 1.0 / y
Reciprocal Hoerl Transform 2D		y = (bx + c)a * exp(bx + c) y = 1.0 / y
Reciprocal Inverted Exponential 2D		y = a * exp(b/x) y = 1.0 / y
Reciprocal Inverted Offset Exponential 2D		y = a * exp(b/(x+c)) y = 1.0 / y
Reciprocal Offset Exponential 2D		y = a * exp(bx + c) y = 1.0 / y
Reciprocal Scaled Exponential 2D		y = a * exp(x) y = 1.0 / y
Reciprocal Shifted Exponential 2D		y = a * exp(x + b) y = 1.0 / y
Reciprocal Simple Exponential 2D		y = ax y = 1.0 / y
Reciprocal Standard Vapor Pressure 2D		y = exp(a + (b/x) + c*ln(x)) y = 1.0 / y
Reciprocal Steve Battison Exponential A 2D		y = exp((a + bx) / (c + dx)) y = 1.0 / y
Reciprocal Steve Battison Exponential B 2D		y = a * exp((b + cx) / (d + fx)) y = 1.0 / y
Reciprocal Stirling 2D		y = a * (exp(bx) - 1.0) / b y = 1.0 / y
Reciprocal Triple Exponential 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = 1.0 / y
Reciprocal Asymptotic Exponential A Transform With Offset 2D		y = 1.0 - abx + c y = 1.0 / y + Offset
Reciprocal Asymptotic Exponential A With Offset 2D		y = 1.0 - ax y = 1.0 / y + Offset
Reciprocal Asymptotic Exponential B With Offset 2D		y = a * (1.0 - exp(bx)) y = 1.0 / y + Offset
Reciprocal Double Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) y = 1.0 / y + Offset
Reciprocal Exponential With Offset 2D		y = a * exp(bx) y = 1.0 / y + Offset
Reciprocal Hoerl Transform With Offset 2D		y = (bx + c)a * exp(bx + c) y = 1.0 / y + Offset
Reciprocal Hoerl With Offset 2D		y = xa * exp(x) y = 1.0 / y + Offset
Reciprocal Inverted Exponential With Offset 2D		y = a * exp(b/x) y = 1.0 / y + Offset
Reciprocal Inverted Offset Exponential With Offset 2D		y = a * exp(b/(x+c)) y = 1.0 / y + Offset
Reciprocal Offset Exponential With Offset 2D		y = a * exp(bx + c) y = 1.0 / y + Offset
Reciprocal Scaled Exponential With Offset 2D		y = a * exp(x) y = 1.0 / y + Offset
Reciprocal Shifted Exponential With Offset 2D		y = a * exp(x + b) y = 1.0 / y + Offset
Reciprocal Simple Exponential With Offset 2D		y = ax y = 1.0 / y + Offset
Reciprocal Standard Vapor Pressure With Offset 2D		y = exp(a + (b/x) + c*ln(x)) y = 1.0 / y + Offset
Reciprocal Steve Battison Exponential A With Offset 2D		y = exp((a + bx) / (c + dx)) y = 1.0 / y + Offset
Reciprocal Steve Battison Exponential B With Offset 2D		y = a * exp((b + cx) / (d + fx)) y = 1.0 / y + Offset
Reciprocal Stirling With Offset 2D		y = a * (exp(bx) - 1.0) / b y = 1.0 / y + Offset
Reciprocal Triple Exponential With Offset 2D		y = a * exp(bx) + c * exp(dx) + f * exp(gx) y = 1.0 / y + Offset

2D LegendrePolynomial

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

2D Logarithmic

Base 10 Logarithmic 2D		y = a + b*log10(x)
Bradley 2D		y = a * ln(-b * ln(x))
Bradley Transform 2D		y = a * ln(-b * ln(cx + d))
Crystal Resonator Ageing MIL-PRF-55310E 2D		y = A(ln(Bt + 1)) + f0
Cubic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3
Cubic Logarithmic Scaled 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3
Cubic Logarithmic Transform 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3
Linear Logarithmic 2D		y = a + b*ln(x)
Linear Logarithmic Scaled 2D		y = a + b*ln(cx)
Linear Logarithmic Transform 2D		y = a + b*ln(cx+d)
Quadratic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2
Quadratic Logarithmic Scaled 2D		y = a + b*ln(dx) + c*ln(dx)2
Quadratic Logarithmic Transform 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2
Quartic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4
Quartic Logarithmic Scaled 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4
Quartic Logarithmic Transform 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4
Quintic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5
Quintic Logarithmic Scaled 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4
Quintic Logarithmic Transform 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5
Bradley Transform With Offset 2D		y = a * ln(-b * ln(cx + d)) + Offset
Bradley With Offset 2D		y = a * ln(-b * ln(x)) + Offset
Base 10 Logarithmic With Exponential Decay 2D		y = a + b*log10(x) y = y / (d * exp(x))
Bradley Transform With Exponential Decay 2D		y = a * ln(-b * ln(cx + d)) y = y / exp(x)
Bradley With Exponential Decay 2D		y = a * ln(-b * ln(x)) y = y / exp(x)
Crystal Resonator Ageing MIL-PRF-55310E With Exponential Decay 2D		y = A(ln(Bt + 1)) + f0 y = y / (f * exp(x))
Cubic Logarithmic Scaled With Exponential Decay 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3 y = y / (h * exp(x))
Cubic Logarithmic Transform With Exponential Decay 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3 y = y / (i * exp(x))
Cubic Logarithmic With Exponential Decay 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 y = y / (g * exp(x))
Linear Logarithmic Scaled With Exponential Decay 2D		y = a + b*ln(cx) y = y / (f * exp(x))
Linear Logarithmic Transform With Exponential Decay 2D		y = a + b*ln(cx+d) y = y / (g * exp(x))
Linear Logarithmic With Exponential Decay 2D		y = a + b*ln(x) y = y / (d * exp(x))
Quadratic Logarithmic Scaled With Exponential Decay 2D		y = a + b*ln(dx) + c*ln(dx)2 y = y / (g * exp(x))
Quadratic Logarithmic Transform With Exponential Decay 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2 y = y / (h * exp(x))
Quadratic Logarithmic With Exponential Decay 2D		y = a + b*ln(x) + c*ln(x)2 y = y / (f * exp(x))
Quartic Logarithmic Scaled With Exponential Decay 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 y = y / (i * exp(x))
Quartic Logarithmic Transform With Exponential Decay 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4 y = y / (j * exp(x))
Quartic Logarithmic With Exponential Decay 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 y = y / (h * exp(x))
Quintic Logarithmic Scaled With Exponential Decay 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4 y = y / (j * exp(x))
Quintic Logarithmic Transform With Exponential Decay 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5 y = y / (k * exp(x))
Quintic Logarithmic With Exponential Decay 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5 y = y / (i * exp(x))
Bradley Transform With Exponential Decay And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y / exp(x) + Offset
Bradley With Exponential Decay And Offset 2D		y = a * ln(-b * ln(x)) y = y / exp(x) + Offset
Base 10 Logarithmic With Exponential Growth 2D		y = a + b*log10(x) y = y * (d * exp(x))
Bradley Transform With Exponential Growth 2D		y = a * ln(-b * ln(cx + d)) y = y * exp(x)
Bradley With Exponential Growth 2D		y = a * ln(-b * ln(x)) y = y * exp(x)
Crystal Resonator Ageing MIL-PRF-55310E With Exponential Growth 2D		y = A(ln(Bt + 1)) + f0 y = y * (f * exp(x))
Cubic Logarithmic Scaled With Exponential Growth 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3 y = y * (h * exp(x))
Cubic Logarithmic Transform With Exponential Growth 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3 y = y * (i * exp(x))
Cubic Logarithmic With Exponential Growth 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 y = y * (g * exp(x))
Linear Logarithmic Scaled With Exponential Growth 2D		y = a + b*ln(cx) y = y * (f * exp(x))
Linear Logarithmic Transform With Exponential Growth 2D		y = a + b*ln(cx+d) y = y * (g * exp(x))
Linear Logarithmic With Exponential Growth 2D		y = a + b*ln(x) y = y * (d * exp(x))
Quadratic Logarithmic Scaled With Exponential Growth 2D		y = a + b*ln(dx) + c*ln(dx)2 y = y * (g * exp(x))
Quadratic Logarithmic Transform With Exponential Growth 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2 y = y * (h * exp(x))
Quadratic Logarithmic With Exponential Growth 2D		y = a + b*ln(x) + c*ln(x)2 y = y * (f * exp(x))
Quartic Logarithmic Scaled With Exponential Growth 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 y = y * (i * exp(x))
Quartic Logarithmic Transform With Exponential Growth 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4 y = y * (j * exp(x))
Quartic Logarithmic With Exponential Growth 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 y = y * (h * exp(x))
Quintic Logarithmic Scaled With Exponential Growth 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4 y = y * (j * exp(x))
Quintic Logarithmic Transform With Exponential Growth 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5 y = y * (k * exp(x))
Quintic Logarithmic With Exponential Growth 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5 y = y * (i * exp(x))
Bradley Transform With Exponential Growth And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y * exp(x) + Offset
Bradley With Exponential Growth And Offset 2D		y = a * ln(-b * ln(x)) y = y * exp(x) + Offset
Inverse Base 10 Logarithmic 2D		y = a + b*log10(x) y = x / y
Inverse Bradley 2D		y = a * ln(-b * ln(x)) y = x / y
Inverse Bradley Transform 2D		y = a * ln(-b * ln(cx + d)) y = x / y
Inverse Crystal Resonator Ageing MIL-PRF-55310E 2D		y = A(ln(Bt + 1)) + f0 y = x / y
Inverse Cubic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 y = x / y
Inverse Cubic Logarithmic Scaled 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3 y = x / y
Inverse Cubic Logarithmic Transform 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3 y = x / y
Inverse Linear Logarithmic 2D		y = a + b*ln(x) y = x / y
Inverse Linear Logarithmic Scaled 2D		y = a + b*ln(cx) y = x / y
Inverse Linear Logarithmic Transform 2D		y = a + b*ln(cx+d) y = x / y
Inverse Quadratic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 y = x / y
Inverse Quadratic Logarithmic Scaled 2D		y = a + b*ln(dx) + c*ln(dx)2 y = x / y
Inverse Quadratic Logarithmic Transform 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2 y = x / y
Inverse Quartic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 y = x / y
Inverse Quartic Logarithmic Scaled 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 y = x / y
Inverse Quartic Logarithmic Transform 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4 y = x / y
Inverse Quintic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5 y = x / y
Inverse Quintic Logarithmic Scaled 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4 y = x / y
Inverse Quintic Logarithmic Transform 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5 y = x / y
Inverse Bradley Transform With Offset 2D		y = a * ln(-b * ln(cx + d)) y = x / y + Offset
Inverse Bradley With Offset 2D		y = a * ln(-b * ln(x)) y = x / y + Offset
Base 10 Logarithmic With Linear Decay 2D		y = a + b*log10(x) y = y / (d * x)
Bradley Transform With Linear Decay 2D		y = a * ln(-b * ln(cx + d)) y = y / x
Bradley With Linear Decay 2D		y = a * ln(-b * ln(x)) y = y / x
Crystal Resonator Ageing MIL-PRF-55310E With Linear Decay 2D		y = A(ln(Bt + 1)) + f0 y = y / (f * x)
Cubic Logarithmic Scaled With Linear Decay 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3 y = y / (h * x)
Cubic Logarithmic Transform With Linear Decay 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3 y = y / (i * x)
Cubic Logarithmic With Linear Decay 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 y = y / (g * x)
Linear Logarithmic Scaled With Linear Decay 2D		y = a + b*ln(cx) y = y / (f * x)
Linear Logarithmic Transform With Linear Decay 2D		y = a + b*ln(cx+d) y = y / (g * x)
Linear Logarithmic With Linear Decay 2D		y = a + b*ln(x) y = y / (d * x)
Quadratic Logarithmic Scaled With Linear Decay 2D		y = a + b*ln(dx) + c*ln(dx)2 y = y / (g * x)
Quadratic Logarithmic Transform With Linear Decay 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2 y = y / (h * x)
Quadratic Logarithmic With Linear Decay 2D		y = a + b*ln(x) + c*ln(x)2 y = y / (f * x)
Quartic Logarithmic Scaled With Linear Decay 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 y = y / (i * x)
Quartic Logarithmic Transform With Linear Decay 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4 y = y / (j * x)
Quartic Logarithmic With Linear Decay 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 y = y / (h * x)
Quintic Logarithmic Scaled With Linear Decay 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4 y = y / (j * x)
Quintic Logarithmic Transform With Linear Decay 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5 y = y / (k * x)
Quintic Logarithmic With Linear Decay 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5 y = y / (i * x)
Bradley Transform With Linear Decay And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y / x + Offset
Bradley With Linear Decay And Offset 2D		y = a * ln(-b * ln(x)) y = y / x + Offset
Base 10 Logarithmic With Linear Growth 2D		y = a + b*log10(x) y = y * (d * x) + Offset
Bradley Transform With Linear Growth 2D		y = a * ln(-b * ln(cx + d)) y = y * x
Bradley With Linear Growth 2D		y = a * ln(-b * ln(x)) y = y * x
Crystal Resonator Ageing MIL-PRF-55310E With Linear Growth 2D		y = A(ln(Bt + 1)) + f0 y = y * (f * x) + Offset
Cubic Logarithmic Scaled With Linear Growth 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3 y = y * (h * x) + Offset
Cubic Logarithmic Transform With Linear Growth 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3 y = y * (i * x) + Offset
Cubic Logarithmic With Linear Growth 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 y = y * (g * x) + Offset
Linear Logarithmic Scaled With Linear Growth 2D		y = a + b*ln(cx) y = y * (f * x) + Offset
Linear Logarithmic Transform With Linear Growth 2D		y = a + b*ln(cx+d) y = y * (g * x) + Offset
Linear Logarithmic With Linear Growth 2D		y = a + b*ln(x) y = y * (d * x) + Offset
Quadratic Logarithmic Scaled With Linear Growth 2D		y = a + b*ln(dx) + c*ln(dx)2 y = y * (g * x) + Offset
Quadratic Logarithmic Transform With Linear Growth 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2 y = y * (h * x) + Offset
Quadratic Logarithmic With Linear Growth 2D		y = a + b*ln(x) + c*ln(x)2 y = y * (f * x) + Offset
Quartic Logarithmic Scaled With Linear Growth 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 y = y * (i * x) + Offset
Quartic Logarithmic Transform With Linear Growth 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4 y = y * (j * x) + Offset
Quartic Logarithmic With Linear Growth 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 y = y * (h * x) + Offset
Quintic Logarithmic Scaled With Linear Growth 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4 y = y * (j * x) + Offset
Quintic Logarithmic Transform With Linear Growth 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5 y = y * (k * x) + Offset
Quintic Logarithmic With Linear Growth 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5 y = y * (i * x) + Offset
Bradley Transform With Linear Growth And Offset 2D		y = a * ln(-b * ln(cx + d)) y = y * x + Offset
Bradley With Linear Growth And Offset 2D		y = a * ln(-b * ln(x)) y = y * x + Offset
Reciprocal Base 10 Logarithmic 2D		y = a + b*log10(x) y = 1.0 / y
Reciprocal Bradley 2D		y = a * ln(-b * ln(x)) y = 1.0 / y
Reciprocal Bradley Transform 2D		y = a * ln(-b * ln(cx + d)) y = 1.0 / y
Reciprocal Crystal Resonator Ageing MIL-PRF-55310E 2D		y = A(ln(Bt + 1)) + f0 y = 1.0 / y
Reciprocal Cubic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 y = 1.0 / y
Reciprocal Cubic Logarithmic Scaled 2D		y = a + b*ln(f*x) + c*ln(f*x)2 + d*ln(f*x)3 y = 1.0 / y
Reciprocal Cubic Logarithmic Transform 2D		y = a + b*ln(f*x+g) + c*ln(f*x+g)2 + d*ln(f*x+g)3 y = 1.0 / y
Reciprocal Linear Logarithmic 2D		y = a + b*ln(x) y = 1.0 / y
Reciprocal Linear Logarithmic Scaled 2D		y = a + b*ln(cx) y = 1.0 / y
Reciprocal Linear Logarithmic Transform 2D		y = a + b*ln(cx+d) y = 1.0 / y
Reciprocal Quadratic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 y = 1.0 / y
Reciprocal Quadratic Logarithmic Scaled 2D		y = a + b*ln(dx) + c*ln(dx)2 y = 1.0 / y
Reciprocal Quadratic Logarithmic Transform 2D		y = a + b*ln(dx+f) + c*ln(dx+f)2 y = 1.0 / y
Reciprocal Quartic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 y = 1.0 / y
Reciprocal Quartic Logarithmic Scaled 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 y = 1.0 / y
Reciprocal Quartic Logarithmic Transform 2D		y = a + b*ln(g*x+h) + c*ln(g*x+h)2 + d*ln(g*x+h)3 + f*ln(g*x+h)4 y = 1.0 / y
Reciprocal Quintic Logarithmic 2D		y = a + b*ln(x) + c*ln(x)2 + d*ln(x)3 + f*ln(x)4 + g*ln(x)5 y = 1.0 / y
Reciprocal Quintic Logarithmic Scaled 2D		y = a + b*ln(h*x) + c*ln(h*x)2 + d*ln(h*x)3 + f*ln(h*x)4 + g*ln(h*x)4 y = 1.0 / y
Reciprocal Quintic Logarithmic Transform 2D		y = a + b*ln(h*x+i) + c*ln(h*x+i)2 + d*ln(h*x+i)3 + f*ln(h*x+i)4 + g*ln(h*x+i)5 y = 1.0 / y
Reciprocal Bradley Transform With Offset 2D		y = a * ln(-b * ln(cx + d)) y = 1.0 / y + Offset
Reciprocal Bradley With Offset 2D		y = a * ln(-b * ln(x)) y = 1.0 / y + Offset

2D Miscellaneous

Arrhenius Rate Constant Law 2D		y = a * exp(-b/x)
Arrhenius Rate Constant Law Stretched 2D		y = a * exp(-pow(b/x, c))
Bleasdale-Nelder 2D		y = (a + bx)-1/c
Bleasdale-Nelder Power 2D		y = (a + bxc)-1/d
Catenary 2D		y = a * cosh(x / a)   [web citation]
Catenary Transform 2D		y = a * cosh((bx + c) / a)   [web citation]
Combined Power And Exponential 2D		y = axb * exp(cx)
David Rodbard NIH 2D		y = d + (a - d) / (1.0 + (x/c)b)   [web citation]
Double Langmuir Probe Characteristic 2D		y = a * tanh(bx+c)
Double Rectangular Hyperbola A 2D		y = ax/(b+x) + cx/(d+x)
Double Rectangular Hyperbola B 2D		y = ax/(b+x) + cx/(d+x) + fx
Gunary 2D		y = x / (a + bx + cx0.5)
Hyperbola A Modified 2D		y = ax/(1+bx)
Hyperbola B Modified 2D		y = x/(a+bx)
Hyperbolic Decay 2D		y = ab/(b+x)
Lame's Cubic 2D		y = (a3 - x3)1/3   [web citation]
Lame's Cubic Transform 2D		y = (a3 - (bx + c)3)1/3   [web citation]
Miscellaneous 1 2D		y = 1.0 + a(1.0 - exp(bx))
Nelder 2D		y = (a + x) / (b + c(a + x) + d(a + x)2
Pareto A 2D		y = 1 - x-a
Pareto B 2D		y = a(1 - x-b)
Pareto C 2D		y = 1.0 - (1.0 / (1 + ax)b
Pareto D 2D		y = 1.0 - (1.0 / xa)
Polytrope 2D		y = a / xb   [web citation]
Polytrope Transform 2D		y = a / (cx + d)b   [web citation]
Pursuit Curve 2D		y = ax2 - log(x)
Pursuit Curve Transform 2D		y = a(bx + c)2 - log(bx + c)
Rectangular Hyperbola A 2D		y = ax/(b+x)
Rectangular Hyperbola B 2D		y = ax/(b+x) + cx
Serpentine 2D		y = ax / (1.0 + bx2)
Shifted Reciprocal 2D		y = 1.0 / (a - x)
Simple Equation 01 2D		y = a
Simple Equation 02 2D		y = a/pow(x,2.0)
Simple Equation 03 2D		y = a*pow(ln(x),b)
Simple Equation 04 2D		y = a*pow(x,3.0)
Simple Equation 05 2D		y = a*pow(x,4.0)
Simple Equation 06 2D		y = x/(a+b*pow(x,2.0))
Simple Equation 07 2D		y = a * pow(b,x) * pow(x,c)
Simple Equation 08 2D		y = a*pow(b,1.0/x)*pow(x,c)
Simple Equation 09 2D		y = a*exp(pow(x-b,2.0)/c)
Simple Equation 10 2D		y = a*exp(pow(ln(x)-b,2.0)/c)
Simple Equation 11 2D		y = a*pow(x,b)*pow(1.0-x,c)
Simple Equation 13 2D		y = a*pow(x/b,c)*exp(x/b)
Simple Equation 14 2D		y = a*pow(x,b+c*x)
Simple Equation 15 2D		y = a*pow(x,b+c/x)
Simple Equation 16 2D		y = a*pow(x,b+c*ln(x))
Simple Equation 17 2D		y = a*pow(x,b*x+c*pow(x,2.0))
Simple Equation 18 2D		y = a*exp(b*x+c*pow(x,0.5))
Simple Equation 19 2D		y = a*exp(b/x+c*x)
Simple Equation 20 2D		y = (a+x)/(b+c*x)
Simple Equation 21 2D		y = (a+x)/(b+c*pow(x,2.0))
Simple Equation 22 2D		y = a*(exp(b*x)-exp(c*x))
Simple Equation 23 2D		y = a*exp(b*exp(c*x))
Simple Equation 24 2D		y = a/(1.0 + b * exp(c*x))
Simple Equation 25 2D		y = a/(b+pow(x,c))
Simple Equation 26 2D		y = a/pow(1.0 + b * pow(x,c),2.0)
Simple Equation 27 2D		y = pow(a+b*x,c)
Simple Equation 28 2D		y = exp(a+b/x+c*ln(x))
Simple Equation 29 2D		y = a*exp(b*pow(x,c))
Simple Equation 30 2D		y = a*pow(x,b*pow(x,c))
Simple Equation 31 2D		y = a*ln(x+b)
Simple Equation 32 2D		y = a/x+b*pow(x,c)
Simple Equation 33 2D		y = a/x+b*exp(c/x)
Simple Equation 34 2D		y = a/x+b*exp(c*x)
Simple Equation 35 2D		y = a*exp(b*x)/x
Simple Equation 36 2D		y = a*exp(b/x)/x
Simple Equation 37 2D		y = a*pow(x,b)*ln(x)
Simple Equation 38 2D		y = a*pow(x,b)/ln(x)
Simple Equation 39 2D		y = a*pow(x,b)*ln(x+c)
Simple Equation 40 2D		y = a*pow(ln(x+b),c)
Simple Equation 41 2D		y = a*pow(x,b/x)+c*x
Simple Equation 42 2D		y = a*pow(x,b/x)+c*ln(x)
Simple Reciprocal 2D		y = a / x
Square Modified 2D		y = x2 - ax
Square Modified Transform 2D		y = (bx + c)2 - a(bx + c)
Transition State Rate Constant Law 2D		y = axb * exp(-c/x)
Witch Of Maria Agnesi A 2D		y = 8a3 / (x2 + 4a2)
Witch Of Maria Agnesi B 2D		y = a3 / (x2 + a2)
Witch Of Maria Agnesi C 2D		y = a3 / ((x * b + c)2 + a2)
Arrhenius Rate Constant Law Stretched With Offset 2D		y = a * exp(-pow(b/x, c)) + Offset
Arrhenius Rate Constant Law With Offset 2D		y = a * exp(-b/x) + Offset
Bleasdale-Nelder Power With Offset 2D		y = (a + bxc)-1/d + Offset
Bleasdale-Nelder With Offset 2D		y = (a + bx)-1/c + Offset
Catenary Transform With Offset 2D		y = a * cosh((bx + c) / a) + Offset   [web citation]
Catenary With Offset 2D		y = a * cosh(x / a) + Offset   [web citation]
Combined Power And Exponential With Offset 2D		y = axb * exp(cx) + Offset
Double Langmuir Probe Characteristic With Offset 2D		y = a * tanh(bx+c) + Offset
Double Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + cx/(d+x) + Offset
Double Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx/(d+x) + fx + Offset
Gunary With Offset 2D		y = x / (a + bx + cx0.5) + Offset
Hyperbola A Modified With Offset 2D		y = ax/(1+bx) + Offset
Hyperbola B Modified With Offset 2D		y = x/(a+bx) + Offset
Hyperbolic Decay With Offset 2D		y = ab/(b+x) + Offset
Lame's Cubic Transform With Offset 2D		y = (a3 - (bx + c)3)1/3 + Offset   [web citation]
Lame's Cubic With Offset 2D		y = (a3 - x3)1/3 + Offset   [web citation]
Miscellaneous 1 With Offset 2D		y = 1.0 + a(1.0 - exp(bx)) + Offset
Nelder With Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 + Offset
Pareto A With Offset 2D		y = 1 - x-a + Offset
Pareto B With Offset 2D		y = a(1 - x-b) + Offset
Pareto C With Offset 2D		y = 1.0 - (1.0 / (1 + ax)b + Offset
Pareto D With Offset 2D		y = 1.0 - (1.0 / xa) + Offset
Polytrope Transform With Offset 2D		y = a / (cx + d)b + Offset   [web citation]
Polytrope With Offset 2D		y = a / xb + Offset   [web citation]
Pursuit Curve Transform With Offset 2D		y = a(bx + c)2 - log(bx + c) + Offset
Pursuit Curve With Offset 2D		y = ax2 - log(x) + Offset
Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + Offset
Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx + Offset
Serpentine With Offset 2D		y = ax / (1.0 + bx2) + Offset
Shifted Reciprocal With Offset 2D		y = 1.0 / (a - x) + Offset
Simple Equation 02 With Offset 2D		y = a/pow(x,2.0) + Offset
Simple Equation 03 With Offset 2D		y = a*pow(ln(x),b) + Offset
Simple Equation 04 With Offset 2D		y = a*pow(x,3.0) + Offset
Simple Equation 05 With Offset 2D		y = a*pow(x,4.0) + Offset
Simple Equation 06 With Offset 2D		y = x/(a+b*pow(x,2.0)) + Offset
Simple Equation 07 With Offset 2D		y = a * pow(b,x) * pow(x,c) + Offset
Simple Equation 08 With Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) + Offset
Simple Equation 09 With Offset 2D		y = a*exp(pow(x-b,2.0)/c) + Offset
Simple Equation 10 With Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) + Offset
Simple Equation 11 With Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) + Offset
Simple Equation 13 With Offset 2D		y = a*pow(x/b,c)*exp(x/b) + Offset
Simple Equation 14 With Offset 2D		y = a*pow(x,b+c*x) + Offset
Simple Equation 15 With Offset 2D		y = a*pow(x,b+c/x) + Offset
Simple Equation 16 With Offset 2D		y = a*pow(x,b+c*ln(x)) + Offset
Simple Equation 17 With Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) + Offset
Simple Equation 18 With Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) + Offset
Simple Equation 19 With Offset 2D		y = a*exp(b/x+c*x) + Offset
Simple Equation 20 With Offset 2D		y = (a+x)/(b+c*x) + Offset
Simple Equation 21 With Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) + Offset
Simple Equation 22 With Offset 2D		y = a*(exp(b*x)-exp(c*x)) + Offset
Simple Equation 23 With Offset 2D		y = a*exp(b*exp(c*x)) + Offset
Simple Equation 24 With Offset 2D		y = a/(1.0 + b * exp(c*x)) + Offset
Simple Equation 25 With Offset 2D		y = a/(b+pow(x,c)) + Offset
Simple Equation 26 With Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) + Offset
Simple Equation 27 With Offset 2D		y = pow(a+b*x,c) + Offset
Simple Equation 28 With Offset 2D		y = exp(a+b/x+c*ln(x)) + Offset
Simple Equation 29 With Offset 2D		y = a*exp(b*pow(x,c)) + Offset
Simple Equation 30 With Offset 2D		y = a*pow(x,b*pow(x,c)) + Offset
Simple Equation 31 With Offset 2D		y = a*ln(x+b) + Offset
Simple Equation 32 With Offset 2D		y = a/x+b*pow(x,c) + Offset
Simple Equation 33 With Offset 2D		y = a/x+b*exp(c/x) + Offset
Simple Equation 34 With Offset 2D		y = a/x+b*exp(c*x) + Offset
Simple Equation 35 With Offset 2D		y = a*exp(b*x)/x + Offset
Simple Equation 36 With Offset 2D		y = a*exp(b/x)/x + Offset
Simple Equation 37 With Offset 2D		y = a*pow(x,b)*ln(x) + Offset
Simple Equation 38 With Offset 2D		y = a*pow(x,b)/ln(x) + Offset
Simple Equation 39 With Offset 2D		y = a*pow(x,b)*ln(x+c) + Offset
Simple Equation 40 With Offset 2D		y = a*pow(ln(x+b),c) + Offset
Simple Equation 41 With Offset 2D		y = a*pow(x,b/x)+c*x + Offset
Simple Equation 42 With Offset 2D		y = a*pow(x,b/x)+c*ln(x) + Offset
Simple Reciprocal With Offset 2D		y = a / x + Offset
Square Modified Transform With Offset 2D		y = (bx + c)2 - a(bx + c) + Offset
Square Modified With Offset 2D		y = x2 - ax + Offset
Transition State Rate Constant Law With Offset 2D		y = axb * exp(-c/x) + Offset
Witch Of Maria Agnesi A With Offset 2D		y = 8a3 / (x2 + 4a2) + Offset
Witch Of Maria Agnesi B With Offset 2D		y = a3 / (x2 + a2) + Offset
Witch Of Maria Agnesi C With Offset 2D		y = a3 / ((x * b + c)2 + a2) + Offset
Arrhenius Rate Constant Law Stretched With Exponential Decay 2D		y = a * exp(-pow(b/x, c)) y = y / exp(x)
Arrhenius Rate Constant Law With Exponential Decay 2D		y = a * exp(-b/x) y = y / exp(x)
Bleasdale-Nelder Power With Exponential Decay 2D		y = (a + bxc)-1/d y = y / (g * exp(x))
Bleasdale-Nelder With Exponential Decay 2D		y = (a + bx)-1/c y = y / (f * exp(x))
Catenary Transform With Exponential Decay 2D		y = a * cosh((bx + c) / a) y = y / exp(x)   [web citation]
Catenary With Exponential Decay 2D		y = a * cosh(x / a) y = y / exp(x)   [web citation]
Combined Power And Exponential With Exponential Decay 2D		y = axb * exp(cx) y = y / exp(x)
David Rodbard NIH With Exponential Decay 2D		y = d + (a - d) / (1.0 + (x/c)b) y = y / (g * exp(x))   [web citation]
Double Langmuir Probe Characteristic With Exponential Decay 2D		y = a * tanh(bx+c) y = y / exp(x)
Double Rectangular Hyperbola A With Exponential Decay 2D		y = ax/(b+x) + cx/(d+x) y = y / (g * exp(x))
Double Rectangular Hyperbola B With Exponential Decay 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (h * exp(x))
Gunary With Exponential Decay 2D		y = x / (a + bx + cx0.5) y = y / (f * exp(x))
Hyperbola A Modified With Exponential Decay 2D		y = ax/(1+bx) y = y / exp(x)
Hyperbola B Modified With Exponential Decay 2D		y = x/(a+bx) y = y / (d * exp(x))
Hyperbolic Decay With Exponential Decay 2D		y = ab/(b+x) y = y / exp(x)
Lame's Cubic Transform With Exponential Decay 2D		y = (a3 - (bx + c)3)1/3 y = y / (f * exp(x))   [web citation]
Lame's Cubic With Exponential Decay 2D		y = (a3 - x3)1/3 y = y / (c * exp(x))   [web citation]
Miscellaneous 1 With Exponential Decay 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (d * exp(x))
Nelder With Exponential Decay 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y / (g * exp(x))
Pareto A With Exponential Decay 2D		y = 1 - x-a y = y / (c * exp(x))
Pareto B With Exponential Decay 2D		y = a(1 - x-b) y = y / exp(x)
Pareto C With Exponential Decay 2D		y = 1.0 - (1.0 / (1 + ax)b y = y / (d * exp(x))
Pareto D With Exponential Decay 2D		y = 1.0 - (1.0 / xa) y = y / (c * exp(x))
Polytrope Transform With Exponential Decay 2D		y = a / (cx + d)b y = y / exp(x)   [web citation]
Polytrope With Exponential Decay 2D		y = a / xb y = y / exp(x)   [web citation]
Pursuit Curve Transform With Exponential Decay 2D		y = a(bx + c)2 - log(bx + c) y = y / (f * exp(x))
Pursuit Curve With Exponential Decay 2D		y = ax2 - log(x) y = y / (c * exp(x))
Rectangular Hyperbola A With Exponential Decay 2D		y = ax/(b+x) y = y / exp(x)
Rectangular Hyperbola B With Exponential Decay 2D		y = ax/(b+x) + cx y = y / (f * exp(x))
Serpentine With Exponential Decay 2D		y = ax / (1.0 + bx2) y = y / exp(x)
Shifted Reciprocal With Exponential Decay 2D		y = 1.0 / (a - x) y = y / (c * exp(x))
Simple Equation 02 With Exponential Decay 2D		y = a/pow(x,2.0) y = y / exp(x)
Simple Equation 03 With Exponential Decay 2D		y = a*pow(ln(x),b) y = y / exp(x)
Simple Equation 04 With Exponential Decay 2D		y = a*pow(x,3.0) y = y / exp(x)
Simple Equation 05 With Exponential Decay 2D		y = a*pow(x,4.0) y = y / exp(x)
Simple Equation 06 With Exponential Decay 2D		y = x/(a+b*pow(x,2.0)) y = y / (d * exp(x))
Simple Equation 07 With Exponential Decay 2D		y = a * pow(b,x) * pow(x,c) y = y / exp(x)
Simple Equation 08 With Exponential Decay 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y / exp(x)
Simple Equation 09 With Exponential Decay 2D		y = a*exp(pow(x-b,2.0)/c) y = y / exp(x)
Simple Equation 10 With Exponential Decay 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / exp(x)
Simple Equation 11 With Exponential Decay 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y / exp(x)
Simple Equation 13 With Exponential Decay 2D		y = a*pow(x/b,c)*exp(x/b) y = y / exp(x)
Simple Equation 14 With Exponential Decay 2D		y = a*pow(x,b+c*x) y = y / exp(x)
Simple Equation 15 With Exponential Decay 2D		y = a*pow(x,b+c/x) y = y / exp(x)
Simple Equation 16 With Exponential Decay 2D		y = a*pow(x,b+c*ln(x)) y = y / exp(x)
Simple Equation 17 With Exponential Decay 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y / exp(x)
Simple Equation 18 With Exponential Decay 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y / exp(x)
Simple Equation 19 With Exponential Decay 2D		y = a*exp(b/x+c*x) y = y / exp(x)
Simple Equation 20 With Exponential Decay 2D		y = (a+x)/(b+c*x) y = y / (f * exp(x))
Simple Equation 21 With Exponential Decay 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y / (f * exp(x))
Simple Equation 22 With Exponential Decay 2D		y = a*(exp(b*x)-exp(c*x)) y = y / exp(x)
Simple Equation 23 With Exponential Decay 2D		y = a*exp(b*exp(c*x)) y = y / exp(x)
Simple Equation 24 With Exponential Decay 2D		y = a/(1.0 + b * exp(c*x)) y = y / exp(x)
Simple Equation 25 With Exponential Decay 2D		y = a/(b+pow(x,c)) y = y / exp(x)
Simple Equation 26 With Exponential Decay 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / exp(x)
Simple Equation 27 With Exponential Decay 2D		y = pow(a+b*x,c) y = y / (f * exp(x))
Simple Equation 28 With Exponential Decay 2D		y = exp(a+b/x+c*ln(x)) y = y / (f * exp(x))
Simple Equation 29 With Exponential Decay 2D		y = a*exp(b*pow(x,c)) y = y / exp(x)
Simple Equation 30 With Exponential Decay 2D		y = a*pow(x,b*pow(x,c)) y = y / exp(x)
Simple Equation 31 With Exponential Decay 2D		y = a*ln(x+b) y = y / exp(x)
Simple Equation 32 With Exponential Decay 2D		y = a/x+b*pow(x,c) y = y / (f * exp(x))
Simple Equation 33 With Exponential Decay 2D		y = a/x+b*exp(c/x) y = y / (f * exp(x))
Simple Equation 34 With Exponential Decay 2D		y = a/x+b*exp(c*x) y = y / (f * exp(x))
Simple Equation 35 With Exponential Decay 2D		y = a*exp(b*x)/x y = y / exp(x)
Simple Equation 36 With Exponential Decay 2D		y = a*exp(b/x)/x y = y / exp(x)
Simple Equation 37 With Exponential Decay 2D		y = a*pow(x,b)*ln(x) y = y / exp(x)
Simple Equation 38 With Exponential Decay 2D		y = a*pow(x,b)/ln(x) y = y / exp(x)
Simple Equation 39 With Exponential Decay 2D		y = a*pow(x,b)*ln(x+c) y = y / exp(x)
Simple Equation 40 With Exponential Decay 2D		y = a*pow(ln(x+b),c) y = y / exp(x)
Simple Equation 41 With Exponential Decay 2D		y = a*pow(x,b/x)+c*x y = y / exp(x)
Simple Equation 42 With Exponential Decay 2D		y = a*pow(x,b/x)+c*ln(x) y = y / (f * exp(x))
Simple Reciprocal With Exponential Decay 2D		y = a / x y = y / exp(x)
Square Modified Transform With Exponential Decay 2D		y = (bx + c)2 - a(bx + c) y = y / (f * exp(x))
Square Modified With Exponential Decay 2D		y = x2 - ax y = y / (c * exp(x))
Transition State Rate Constant Law With Exponential Decay 2D		y = axb * exp(-c/x) y = y / exp(x)
Witch Of Maria Agnesi A With Exponential Decay 2D		y = 8a3 / (x2 + 4a2) y = y / (c * exp(x))
Witch Of Maria Agnesi B With Exponential Decay 2D		y = a3 / (x2 + a2) y = y / (c * exp(x))
Witch Of Maria Agnesi C With Exponential Decay 2D		y = a3 / ((x * b + c)2 + a2) y = y / (f * exp(x))
Arrhenius Rate Constant Law Stretched With Exponential Decay And Offset 2D		y = a * exp(-pow(b/x, c)) y = y / exp(x) + Offset
Arrhenius Rate Constant Law With Exponential Decay And Offset 2D		y = a * exp(-b/x) y = y / exp(x) + Offset
Bleasdale-Nelder Power With Exponential Decay And Offset 2D		y = (a + bxc)-1/d y = y / (h * exp(x)) + Offset
Bleasdale-Nelder With Exponential Decay And Offset 2D		y = (a + bx)-1/c y = y / (g * exp(x)) + Offset
Catenary Transform With Exponential Decay And Offset 2D		y = a * cosh((bx + c) / a) y = y / exp(x) + Offset   [web citation]
Catenary With Exponential Decay And Offset 2D		y = a * cosh(x / a) y = y / exp(x) + Offset   [web citation]
Combined Power And Exponential With Exponential Decay And Offset 2D		y = axb * exp(cx) y = y / exp(x) + Offset
Double Langmuir Probe Characteristic With Exponential Decay And Offset 2D		y = a * tanh(bx+c) y = y / exp(x) + Offset
Double Rectangular Hyperbola A With Exponential Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y / (h * exp(x)) + Offset
Double Rectangular Hyperbola B With Exponential Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (i * exp(x)) + Offset
Gunary With Exponential Decay And Offset 2D		y = x / (a + bx + cx0.5) y = y / (g * exp(x)) + Offset
Hyperbola A Modified With Exponential Decay And Offset 2D		y = ax/(1+bx) y = y / exp(x) + Offset
Hyperbola B Modified With Exponential Decay And Offset 2D		y = x/(a+bx) y = y / (f * exp(x)) + Offset
Hyperbolic Decay With Exponential Decay And Offset 2D		y = ab/(b+x) y = y / exp(x) + Offset
Lame's Cubic Transform With Exponential Decay And Offset 2D		y = (a3 - (bx + c)3)1/3 y = y / (g * exp(x)) + Offset   [web citation]
Lame's Cubic With Exponential Decay And Offset 2D		y = (a3 - x3)1/3 y = y / (d * exp(x)) + Offset   [web citation]
Miscellaneous 1 With Exponential Decay And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (f * exp(x)) + Offset
Nelder With Exponential Decay And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y / (h * exp(x)) + Offset
Pareto A With Exponential Decay And Offset 2D		y = 1 - x-a y = y / (d * exp(x)) + Offset
Pareto B With Exponential Decay And Offset 2D		y = a(1 - x-b) y = y / exp(x) + Offset
Pareto C With Exponential Decay And Offset 2D		y = 1.0 - (1.0 / (1 + ax)b y = y / (f * exp(x)) + Offset
Pareto D With Exponential Decay And Offset 2D		y = 1.0 - (1.0 / xa) y = y / (d * exp(x)) + Offset
Polytrope Transform With Exponential Decay And Offset 2D		y = a / (cx + d)b y = y / exp(x) + Offset   [web citation]
Polytrope With Exponential Decay And Offset 2D		y = a / xb y = y / exp(x) + Offset   [web citation]
Pursuit Curve Transform With Exponential Decay And Offset 2D		y = a(bx + c)2 - log(bx + c) y = y / (g * exp(x)) + Offset
Pursuit Curve With Exponential Decay And Offset 2D		y = ax2 - log(x) y = y / (d * exp(x)) + Offset
Rectangular Hyperbola A With Exponential Decay And Offset 2D		y = ax/(b+x) y = y / exp(x) + Offset
Rectangular Hyperbola B With Exponential Decay And Offset 2D		y = ax/(b+x) + cx y = y / (g * exp(x)) + Offset
Serpentine With Exponential Decay And Offset 2D		y = ax / (1.0 + bx2) y = y / exp(x) + Offset
Shifted Reciprocal With Exponential Decay And Offset 2D		y = 1.0 / (a - x) y = y / (d * exp(x)) + Offset
Simple Equation 02 With Exponential Decay And Offset 2D		y = a/pow(x,2.0) y = y / exp(x) + Offset
Simple Equation 03 With Exponential Decay And Offset 2D		y = a*pow(ln(x),b) y = y / exp(x) + Offset
Simple Equation 04 With Exponential Decay And Offset 2D		y = a*pow(x,3.0) y = y / exp(x) + Offset
Simple Equation 05 With Exponential Decay And Offset 2D		y = a*pow(x,4.0) y = y / exp(x) + Offset
Simple Equation 06 With Exponential Decay And Offset 2D		y = x/(a+b*pow(x,2.0)) y = y / (f * exp(x)) + Offset
Simple Equation 07 With Exponential Decay And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y / exp(x) + Offset
Simple Equation 08 With Exponential Decay And Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y / exp(x) + Offset
Simple Equation 09 With Exponential Decay And Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = y / exp(x) + Offset
Simple Equation 10 With Exponential Decay And Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / exp(x) + Offset
Simple Equation 11 With Exponential Decay And Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y / exp(x) + Offset
Simple Equation 13 With Exponential Decay And Offset 2D		y = a*pow(x/b,c)*exp(x/b) y = y / exp(x) + Offset
Simple Equation 14 With Exponential Decay And Offset 2D		y = a*pow(x,b+c*x) y = y / exp(x) + Offset
Simple Equation 15 With Exponential Decay And Offset 2D		y = a*pow(x,b+c/x) y = y / exp(x) + Offset
Simple Equation 16 With Exponential Decay And Offset 2D		y = a*pow(x,b+c*ln(x)) y = y / exp(x) + Offset
Simple Equation 17 With Exponential Decay And Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y / exp(x) + Offset
Simple Equation 18 With Exponential Decay And Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y / exp(x) + Offset
Simple Equation 19 With Exponential Decay And Offset 2D		y = a*exp(b/x+c*x) y = y / exp(x) + Offset
Simple Equation 20 With Exponential Decay And Offset 2D		y = (a+x)/(b+c*x) y = y / (g * exp(x)) + Offset
Simple Equation 21 With Exponential Decay And Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y / (g * exp(x)) + Offset
Simple Equation 22 With Exponential Decay And Offset 2D		y = a*(exp(b*x)-exp(c*x)) y = y / exp(x) + Offset
Simple Equation 23 With Exponential Decay And Offset 2D		y = a*exp(b*exp(c*x)) y = y / exp(x) + Offset
Simple Equation 24 With Exponential Decay And Offset 2D		y = a/(1.0 + b * exp(c*x)) y = y / exp(x) + Offset
Simple Equation 25 With Exponential Decay And Offset 2D		y = a/(b+pow(x,c)) y = y / exp(x) + Offset
Simple Equation 26 With Exponential Decay And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / exp(x) + Offset
Simple Equation 27 With Exponential Decay And Offset 2D		y = pow(a+b*x,c) y = y / (g * exp(x)) + Offset
Simple Equation 28 With Exponential Decay And Offset 2D		y = exp(a+b/x+c*ln(x)) y = y / (g * exp(x)) + Offset
Simple Equation 29 With Exponential Decay And Offset 2D		y = a*exp(b*pow(x,c)) y = y / exp(x) + Offset
Simple Equation 30 With Exponential Decay And Offset 2D		y = a*pow(x,b*pow(x,c)) y = y / exp(x) + Offset
Simple Equation 31 With Exponential Decay And Offset 2D		y = a*ln(x+b) y = y / exp(x) + Offset
Simple Equation 32 With Exponential Decay And Offset 2D		y = a/x+b*pow(x,c) y = y / (g * exp(x)) + Offset
Simple Equation 33 With Exponential Decay And Offset 2D		y = a/x+b*exp(c/x) y = y / (g * exp(x)) + Offset
Simple Equation 34 With Exponential Decay And Offset 2D		y = a/x+b*exp(c*x) y = y / (g * exp(x)) + Offset
Simple Equation 35 With Exponential Decay And Offset 2D		y = a*exp(b*x)/x y = y / exp(x) + Offset
Simple Equation 36 With Exponential Decay And Offset 2D		y = a*exp(b/x)/x y = y / exp(x) + Offset
Simple Equation 37 With Exponential Decay And Offset 2D		y = a*pow(x,b)*ln(x) y = y / exp(x) + Offset
Simple Equation 38 With Exponential Decay And Offset 2D		y = a*pow(x,b)/ln(x) y = y / exp(x) + Offset
Simple Equation 39 With Exponential Decay And Offset 2D		y = a*pow(x,b)*ln(x+c) y = y / exp(x) + Offset
Simple Equation 40 With Exponential Decay And Offset 2D		y = a*pow(ln(x+b),c) y = y / exp(x) + Offset
Simple Equation 41 With Exponential Decay And Offset 2D		y = a*pow(x,b/x)+c*x y = y / exp(x) + Offset
Simple Equation 42 With Exponential Decay And Offset 2D		y = a*pow(x,b/x)+c*ln(x) y = y / (g * exp(x)) + Offset
Simple Reciprocal With Exponential Decay And Offset 2D		y = a / x y = y / exp(x) + Offset
Square Modified Transform With Exponential Decay And Offset 2D		y = (bx + c)2 - a(bx + c) y = y / (g * exp(x)) + Offset
Square Modified With Exponential Decay And Offset 2D		y = x2 - ax y = y / (d * exp(x)) + Offset
Transition State Rate Constant Law With Exponential Decay And Offset 2D		y = axb * exp(-c/x) y = y / exp(x) + Offset
Witch Of Maria Agnesi A With Exponential Decay And Offset 2D		y = 8a3 / (x2 + 4a2) y = y / (d * exp(x)) + Offset
Witch Of Maria Agnesi B With Exponential Decay And Offset 2D		y = a3 / (x2 + a2) y = y / (d * exp(x)) + Offset
Witch Of Maria Agnesi C With Exponential Decay And Offset 2D		y = a3 / ((x * b + c)2 + a2) y = y / (g * exp(x)) + Offset
Arrhenius Rate Constant Law Stretched With Exponential Growth 2D		y = a * exp(-pow(b/x, c)) y = y * exp(x)
Arrhenius Rate Constant Law With Exponential Growth 2D		y = a * exp(-b/x) y = y * exp(x)
Bleasdale-Nelder Power With Exponential Growth 2D		y = (a + bxc)-1/d y = y * (g * exp(x))
Bleasdale-Nelder With Exponential Growth 2D		y = (a + bx)-1/c y = y * (f * exp(x))
Catenary Transform With Exponential Growth 2D		y = a * cosh((bx + c) / a) y = y * exp(x)   [web citation]
Catenary With Exponential Growth 2D		y = a * cosh(x / a) y = y * exp(x)   [web citation]
Combined Power And Exponential With Exponential Growth 2D		y = axb * exp(cx) y = y * exp(x)
David Rodbard NIH With Exponential Growth 2D		y = d + (a - d) / (1.0 + (x/c)b) y = y * (g * exp(x))   [web citation]
Double Langmuir Probe Characteristic With Exponential Growth 2D		y = a * tanh(bx+c) y = y * exp(x)
Double Rectangular Hyperbola A With Exponential Growth 2D		y = ax/(b+x) + cx/(d+x) y = y * (g * exp(x))
Double Rectangular Hyperbola B With Exponential Growth 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (h * exp(x))
Gunary With Exponential Growth 2D		y = x / (a + bx + cx0.5) y = y * (f * exp(x))
Hyperbola A Modified With Exponential Growth 2D		y = ax/(1+bx) y = y * exp(x)
Hyperbola B Modified With Exponential Growth 2D		y = x/(a+bx) y = y * (d * exp(x))
Hyperbolic Decay With Exponential Growth 2D		y = ab/(b+x) y = y * exp(x)
Lame's Cubic Transform With Exponential Growth 2D		y = (a3 - (bx + c)3)1/3 y = y * (f * exp(x))   [web citation]
Lame's Cubic With Exponential Growth 2D		y = (a3 - x3)1/3 y = y * (c * exp(x))   [web citation]
Miscellaneous 1 With Exponential Growth 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (d * exp(x))
Nelder With Exponential Growth 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y * (g * exp(x))
Pareto A With Exponential Growth 2D		y = 1 - x-a y = y * (c * exp(x))
Pareto B With Exponential Growth 2D		y = a(1 - x-b) y = y * exp(x)
Pareto C With Exponential Growth 2D		y = 1.0 - (1.0 / (1 + ax)b y = y * (d * exp(x))
Pareto D With Exponential Growth 2D		y = 1.0 - (1.0 / xa) y = y * (c * exp(x))
Polytrope Transform With Exponential Growth 2D		y = a / (cx + d)b y = y * exp(x)   [web citation]
Polytrope With Exponential Growth 2D		y = a / xb y = y * exp(x)   [web citation]
Pursuit Curve Transform With Exponential Growth 2D		y = a(bx + c)2 - log(bx + c) y = y * (f * exp(x))
Pursuit Curve With Exponential Growth 2D		y = ax2 - log(x) y = y * (c * exp(x))
Rectangular Hyperbola A With Exponential Growth 2D		y = ax/(b+x) y = y * exp(x)
Rectangular Hyperbola B With Exponential Growth 2D		y = ax/(b+x) + cx y = y * (f * exp(x))
Serpentine With Exponential Growth 2D		y = ax / (1.0 + bx2) y = y * exp(x)
Shifted Reciprocal With Exponential Growth 2D		y = 1.0 / (a - x) y = y * (c * exp(x))
Simple Equation 02 With Exponential Growth 2D		y = a/pow(x,2.0) y = y * exp(x)
Simple Equation 03 With Exponential Growth 2D		y = a*pow(ln(x),b) y = y * exp(x)
Simple Equation 04 With Exponential Growth 2D		y = a*pow(x,3.0) y = y * exp(x)
Simple Equation 05 With Exponential Growth 2D		y = a*pow(x,4.0) y = y * exp(x)
Simple Equation 06 With Exponential Growth 2D		y = x/(a+b*pow(x,2.0)) y = y * (d * exp(x))
Simple Equation 07 With Exponential Growth 2D		y = a * pow(b,x) * pow(x,c) y = y * exp(x)
Simple Equation 08 With Exponential Growth 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y * exp(x)
Simple Equation 09 With Exponential Growth 2D		y = a*exp(pow(x-b,2.0)/c) y = y * exp(x)
Simple Equation 10 With Exponential Growth 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y * exp(x)
Simple Equation 11 With Exponential Growth 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y * exp(x)
Simple Equation 13 With Exponential Growth 2D		y = a*pow(x/b,c)*exp(x/b) y = y * exp(x)
Simple Equation 14 With Exponential Growth 2D		y = a*pow(x,b+c*x) y = y * exp(x)
Simple Equation 15 With Exponential Growth 2D		y = a*pow(x,b+c/x) y = y * exp(x)
Simple Equation 16 With Exponential Growth 2D		y = a*pow(x,b+c*ln(x)) y = y * exp(x)
Simple Equation 17 With Exponential Growth 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y * exp(x)
Simple Equation 18 With Exponential Growth 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y * exp(x)
Simple Equation 19 With Exponential Growth 2D		y = a*exp(b/x+c*x) y = y * exp(x)
Simple Equation 20 With Exponential Growth 2D		y = (a+x)/(b+c*x) y = y * (f * exp(x))
Simple Equation 21 With Exponential Growth 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y * (f * exp(x))
Simple Equation 22 With Exponential Growth 2D		y = a*(exp(b*x)-exp(c*x)) y = y * exp(x)
Simple Equation 23 With Exponential Growth 2D		y = a*exp(b*exp(c*x)) y = y * exp(x)
Simple Equation 24 With Exponential Growth 2D		y = a/(1.0 + b * exp(c*x)) y = y * exp(x)
Simple Equation 25 With Exponential Growth 2D		y = a/(b+pow(x,c)) y = y * exp(x)
Simple Equation 26 With Exponential Growth 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * exp(x)
Simple Equation 27 With Exponential Growth 2D		y = pow(a+b*x,c) y = y * (f * exp(x))
Simple Equation 28 With Exponential Growth 2D		y = exp(a+b/x+c*ln(x)) y = y * (f * exp(x))
Simple Equation 29 With Exponential Growth 2D		y = a*exp(b*pow(x,c)) y = y * exp(x)
Simple Equation 30 With Exponential Growth 2D		y = a*pow(x,b*pow(x,c)) y = y * exp(x)
Simple Equation 31 With Exponential Growth 2D		y = a*ln(x+b) y = y * exp(x)
Simple Equation 32 With Exponential Growth 2D		y = a/x+b*pow(x,c) y = y * (f * exp(x))
Simple Equation 33 With Exponential Growth 2D		y = a/x+b*exp(c/x) y = y * (f * exp(x))
Simple Equation 34 With Exponential Growth 2D		y = a/x+b*exp(c*x) y = y * (f * exp(x))
Simple Equation 35 With Exponential Growth 2D		y = a*exp(b*x)/x y = y * exp(x)
Simple Equation 36 With Exponential Growth 2D		y = a*exp(b/x)/x y = y * exp(x)
Simple Equation 37 With Exponential Growth 2D		y = a*pow(x,b)*ln(x) y = y * exp(x)
Simple Equation 38 With Exponential Growth 2D		y = a*pow(x,b)/ln(x) y = y * exp(x)
Simple Equation 39 With Exponential Growth 2D		y = a*pow(x,b)*ln(x+c) y = y * exp(x)
Simple Equation 40 With Exponential Growth 2D		y = a*pow(ln(x+b),c) y = y * exp(x)
Simple Equation 41 With Exponential Growth 2D		y = a*pow(x,b/x)+c*x y = y * exp(x)
Simple Equation 42 With Exponential Growth 2D		y = a*pow(x,b/x)+c*ln(x) y = y * (f * exp(x))
Simple Reciprocal With Exponential Growth 2D		y = a / x y = y * exp(x)
Square Modified Transform With Exponential Growth 2D		y = (bx + c)2 - a(bx + c) y = y * (f * exp(x))
Square Modified With Exponential Growth 2D		y = x2 - ax y = y * (c * exp(x))
Transition State Rate Constant Law With Exponential Growth 2D		y = axb * exp(-c/x) y = y * exp(x)
Witch Of Maria Agnesi A With Exponential Growth 2D		y = 8a3 / (x2 + 4a2) y = y * (c * exp(x))
Witch Of Maria Agnesi B With Exponential Growth 2D		y = a3 / (x2 + a2) y = y * (c * exp(x))
Witch Of Maria Agnesi C With Exponential Growth 2D		y = a3 / ((x * b + c)2 + a2) y = y * (f * exp(x))
Arrhenius Rate Constant Law Stretched With Exponential Growth And Offset 2D		y = a * exp(-pow(b/x, c)) y = y * exp(x) + Offset
Arrhenius Rate Constant Law With Exponential Growth And Offset 2D		y = a * exp(-b/x) y = y * exp(x) + Offset
Bleasdale-Nelder Power With Exponential Growth And Offset 2D		y = (a + bxc)-1/d y = y * (h * exp(x)) + Offset
Bleasdale-Nelder With Exponential Growth And Offset 2D		y = (a + bx)-1/c y = y * (g * exp(x)) + Offset
Catenary Transform With Exponential Growth And Offset 2D		y = a * cosh((bx + c) / a) y = y * exp(x) + Offset   [web citation]
Catenary With Exponential Growth And Offset 2D		y = a * cosh(x / a) y = y * exp(x) + Offset   [web citation]
Combined Power And Exponential With Exponential Growth And Offset 2D		y = axb * exp(cx) y = y * exp(x) + Offset
Double Langmuir Probe Characteristic With Exponential Growth And Offset 2D		y = a * tanh(bx+c) y = y * exp(x) + Offset
Double Rectangular Hyperbola A With Exponential Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y * (h * exp(x)) + Offset
Double Rectangular Hyperbola B With Exponential Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (i * exp(x)) + Offset
Gunary With Exponential Growth And Offset 2D		y = x / (a + bx + cx0.5) y = y * (g * exp(x)) + Offset
Hyperbola A Modified With Exponential Growth And Offset 2D		y = ax/(1+bx) y = y * exp(x) + Offset
Hyperbola B Modified With Exponential Growth And Offset 2D		y = x/(a+bx) y = y * (f * exp(x)) + Offset
Hyperbolic Decay With Exponential Growth And Offset 2D		y = ab/(b+x) y = y * exp(x) + Offset
Lame's Cubic Transform With Exponential Growth And Offset 2D		y = (a3 - (bx + c)3)1/3 y = y * (g * exp(x)) + Offset   [web citation]
Lame's Cubic With Exponential Growth And Offset 2D		y = (a3 - x3)1/3 y = y * (d * exp(x)) + Offset   [web citation]
Miscellaneous 1 With Exponential Growth And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (f * exp(x)) + Offset
Nelder With Exponential Growth And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y * (h * exp(x)) + Offset
Pareto A With Exponential Growth And Offset 2D		y = 1 - x-a y = y * (d * exp(x)) + Offset
Pareto B With Exponential Growth And Offset 2D		y = a(1 - x-b) y = y * exp(x) + Offset
Pareto C With Exponential Growth And Offset 2D		y = 1.0 - (1.0 / (1 + ax)b y = y * (f * exp(x)) + Offset
Pareto D With Exponential Growth And Offset 2D		y = 1.0 - (1.0 / xa) y = y * (d * exp(x)) + Offset
Polytrope Transform With Exponential Growth And Offset 2D		y = a / (cx + d)b y = y * exp(x) + Offset   [web citation]
Polytrope With Exponential Growth And Offset 2D		y = a / xb y = y * exp(x) + Offset   [web citation]
Pursuit Curve Transform With Exponential Growth And Offset 2D		y = a(bx + c)2 - log(bx + c) y = y * (g * exp(x)) + Offset
Pursuit Curve With Exponential Growth And Offset 2D		y = ax2 - log(x) y = y * (d * exp(x)) + Offset
Rectangular Hyperbola A With Exponential Growth And Offset 2D		y = ax/(b+x) y = y * exp(x) + Offset
Rectangular Hyperbola B With Exponential Growth And Offset 2D		y = ax/(b+x) + cx y = y * (g * exp(x)) + Offset
Serpentine With Exponential Growth And Offset 2D		y = ax / (1.0 + bx2) y = y * exp(x) + Offset
Shifted Reciprocal With Exponential Growth And Offset 2D		y = 1.0 / (a - x) y = y * (d * exp(x)) + Offset
Simple Equation 02 With Exponential Growth And Offset 2D		y = a/pow(x,2.0) y = y * exp(x) + Offset
Simple Equation 03 With Exponential Growth And Offset 2D		y = a*pow(ln(x),b) y = y * exp(x) + Offset
Simple Equation 04 With Exponential Growth And Offset 2D		y = a*pow(x,3.0) y = y * exp(x) + Offset
Simple Equation 05 With Exponential Growth And Offset 2D		y = a*pow(x,4.0) y = y * exp(x) + Offset
Simple Equation 06 With Exponential Growth And Offset 2D		y = x/(a+b*pow(x,2.0)) y = y * (f * exp(x)) + Offset
Simple Equation 07 With Exponential Growth And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y * exp(x) + Offset
Simple Equation 08 With Exponential Growth And Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y * exp(x) + Offset
Simple Equation 09 With Exponential Growth And Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = y * exp(x) + Offset
Simple Equation 10 With Exponential Growth And Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y * exp(x) + Offset
Simple Equation 11 With Exponential Growth And Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y * exp(x) + Offset
Simple Equation 13 With Exponential Growth And Offset 2D		y = a*pow(x/b,c)*exp(x/b) y = y * exp(x) + Offset
Simple Equation 14 With Exponential Growth And Offset 2D		y = a*pow(x,b+c*x) y = y * exp(x) + Offset
Simple Equation 15 With Exponential Growth And Offset 2D		y = a*pow(x,b+c/x) y = y * exp(x) + Offset
Simple Equation 16 With Exponential Growth And Offset 2D		y = a*pow(x,b+c*ln(x)) y = y * exp(x) + Offset
Simple Equation 17 With Exponential Growth And Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y * exp(x) + Offset
Simple Equation 18 With Exponential Growth And Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y * exp(x) + Offset
Simple Equation 19 With Exponential Growth And Offset 2D		y = a*exp(b/x+c*x) y = y * exp(x) + Offset
Simple Equation 20 With Exponential Growth And Offset 2D		y = (a+x)/(b+c*x) y = y * (g * exp(x)) + Offset
Simple Equation 21 With Exponential Growth And Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y * (g * exp(x)) + Offset
Simple Equation 22 With Exponential Growth And Offset 2D		y = a*(exp(b*x)-exp(c*x)) y = y * exp(x) + Offset
Simple Equation 23 With Exponential Growth And Offset 2D		y = a*exp(b*exp(c*x)) y = y * exp(x) + Offset
Simple Equation 24 With Exponential Growth And Offset 2D		y = a/(1.0 + b * exp(c*x)) y = y * exp(x) + Offset
Simple Equation 25 With Exponential Growth And Offset 2D		y = a/(b+pow(x,c)) y = y * exp(x) + Offset
Simple Equation 26 With Exponential Growth And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * exp(x) + Offset
Simple Equation 27 With Exponential Growth And Offset 2D		y = pow(a+b*x,c) y = y * (g * exp(x)) + Offset
Simple Equation 28 With Exponential Growth And Offset 2D		y = exp(a+b/x+c*ln(x)) y = y * (g * exp(x)) + Offset
Simple Equation 29 With Exponential Growth And Offset 2D		y = a*exp(b*pow(x,c)) y = y * exp(x) + Offset
Simple Equation 30 With Exponential Growth And Offset 2D		y = a*pow(x,b*pow(x,c)) y = y * exp(x) + Offset
Simple Equation 31 With Exponential Growth And Offset 2D		y = a*ln(x+b) y = y * exp(x) + Offset
Simple Equation 32 With Exponential Growth And Offset 2D		y = a/x+b*pow(x,c) y = y * (g * exp(x)) + Offset
Simple Equation 33 With Exponential Growth And Offset 2D		y = a/x+b*exp(c/x) y = y * (g * exp(x)) + Offset
Simple Equation 34 With Exponential Growth And Offset 2D		y = a/x+b*exp(c*x) y = y * (g * exp(x)) + Offset
Simple Equation 35 With Exponential Growth And Offset 2D		y = a*exp(b*x)/x y = y * exp(x) + Offset
Simple Equation 36 With Exponential Growth And Offset 2D		y = a*exp(b/x)/x y = y * exp(x) + Offset
Simple Equation 37 With Exponential Growth And Offset 2D		y = a*pow(x,b)*ln(x) y = y * exp(x) + Offset
Simple Equation 38 With Exponential Growth And Offset 2D		y = a*pow(x,b)/ln(x) y = y * exp(x) + Offset
Simple Equation 39 With Exponential Growth And Offset 2D		y = a*pow(x,b)*ln(x+c) y = y * exp(x) + Offset
Simple Equation 40 With Exponential Growth And Offset 2D		y = a*pow(ln(x+b),c) y = y * exp(x) + Offset
Simple Equation 41 With Exponential Growth And Offset 2D		y = a*pow(x,b/x)+c*x y = y * exp(x) + Offset
Simple Equation 42 With Exponential Growth And Offset 2D		y = a*pow(x,b/x)+c*ln(x) y = y * (g * exp(x)) + Offset
Simple Reciprocal With Exponential Growth And Offset 2D		y = a / x y = y * exp(x) + Offset
Square Modified Transform With Exponential Growth And Offset 2D		y = (bx + c)2 - a(bx + c) y = y * (g * exp(x)) + Offset
Square Modified With Exponential Growth And Offset 2D		y = x2 - ax y = y * (d * exp(x)) + Offset
Transition State Rate Constant Law With Exponential Growth And Offset 2D		y = axb * exp(-c/x) y = y * exp(x) + Offset
Witch Of Maria Agnesi A With Exponential Growth And Offset 2D		y = 8a3 / (x2 + 4a2) y = y * (d * exp(x)) + Offset
Witch Of Maria Agnesi B With Exponential Growth And Offset 2D		y = a3 / (x2 + a2) y = y * (d * exp(x)) + Offset
Witch Of Maria Agnesi C With Exponential Growth And Offset 2D		y = a3 / ((x * b + c)2 + a2) y = y * (g * exp(x)) + Offset
Inverse Arrhenius Rate Constant Law 2D		y = a * exp(-b/x) y = x / y
Inverse Arrhenius Rate Constant Law Stretched 2D		y = a * exp(-pow(b/x, c)) y = x / y
Inverse Bleasdale-Nelder 2D		y = (a + bx)-1/c y = x / y
Inverse Bleasdale-Nelder Power 2D		y = (a + bxc)-1/d y = x / y
Inverse Catenary 2D		y = a * cosh(x / a) y = x / y   [web citation]
Inverse Catenary Transform 2D		y = a * cosh((bx + c) / a) y = x / y   [web citation]
Inverse David Rodbard NIH 2D		y = d + (a - d) / (1.0 + (x/c)b) y = x / y   [web citation]
Inverse Double Langmuir Probe Characteristic 2D		y = a * tanh(bx+c) y = x / y
Inverse Double Rectangular Hyperbola A 2D		y = ax/(b+x) + cx/(d+x) y = x / y
Inverse Double Rectangular Hyperbola B 2D		y = ax/(b+x) + cx/(d+x) + fx y = x / y
Inverse Hyperbolic Decay 2D		y = ab/(b+x) y = x / y
Inverse Lame's Cubic 2D		y = (a3 - x3)1/3 y = x / y   [web citation]
Inverse Lame's Cubic Transform 2D		y = (a3 - (bx + c)3)1/3 y = x / y   [web citation]
Inverse Miscellaneous 1 2D		y = 1.0 + a(1.0 - exp(bx)) y = x / y
Inverse Nelder 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = x / y
Inverse Pareto A 2D		y = 1 - x-a y = x / y
Inverse Pareto B 2D		y = a(1 - x-b) y = x / y
Inverse Pareto C 2D		y = 1.0 - (1.0 / (1 + ax)b y = x / y
Inverse Pareto D 2D		y = 1.0 - (1.0 / xa) y = x / y
Inverse Polytrope Transform 2D		y = a / (cx + d)b y = x / y   [web citation]
Inverse Pursuit Curve 2D		y = ax2 - log(x) y = x / y
Inverse Pursuit Curve Transform 2D		y = a(bx + c)2 - log(bx + c) y = x / y
Inverse Rectangular Hyperbola B 2D		y = ax/(b+x) + cx y = x / y
Inverse Shifted Reciprocal 2D		y = 1.0 / (a - x) y = x / y
Inverse Simple Equation 03 2D		y = a*pow(ln(x),b) y = x / y
Inverse Simple Equation 07 2D		y = a * pow(b,x) * pow(x,c) y = x / y
Inverse Simple Equation 08 2D		y = a*pow(b,1.0/x)*pow(x,c) y = x / y
Inverse Simple Equation 09 2D		y = a*exp(pow(x-b,2.0)/c) y = x / y
Inverse Simple Equation 10 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = x / y
Inverse Simple Equation 11 2D		y = a*pow(x,b)*pow(1.0-x,c) y = x / y
Inverse Simple Equation 13 2D		y = a*pow(x/b,c)*exp(x/b) y = x / y
Inverse Simple Equation 15 2D		y = a*pow(x,b+c/x) y = x / y
Inverse Simple Equation 16 2D		y = a*pow(x,b+c*ln(x)) y = x / y
Inverse Simple Equation 17 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = x / y
Inverse Simple Equation 18 2D		y = a*exp(b*x+c*pow(x,0.5)) y = x / y
Inverse Simple Equation 19 2D		y = a*exp(b/x+c*x) y = x / y
Inverse Simple Equation 20 2D		y = (a+x)/(b+c*x) y = x / y
Inverse Simple Equation 21 2D		y = (a+x)/(b+c*pow(x,2.0)) y = x / y
Inverse Simple Equation 22 2D		y = a*(exp(b*x)-exp(c*x)) y = x / y
Inverse Simple Equation 23 2D		y = a*exp(b*exp(c*x)) y = x / y
Inverse Simple Equation 24 2D		y = a/(1.0 + b * exp(c*x)) y = x / y
Inverse Simple Equation 25 2D		y = a/(b+pow(x,c)) y = x / y
Inverse Simple Equation 26 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = x / y
Inverse Simple Equation 27 2D		y = pow(a+b*x,c) y = x / y
Inverse Simple Equation 28 2D		y = exp(a+b/x+c*ln(x)) y = x / y
Inverse Simple Equation 29 2D		y = a*exp(b*pow(x,c)) y = x / y
Inverse Simple Equation 30 2D		y = a*pow(x,b*pow(x,c)) y = x / y
Inverse Simple Equation 31 2D		y = a*ln(x+b) y = x / y
Inverse Simple Equation 32 2D		y = a/x+b*pow(x,c) y = x / y
Inverse Simple Equation 33 2D		y = a/x+b*exp(c/x) y = x / y
Inverse Simple Equation 34 2D		y = a/x+b*exp(c*x) y = x / y
Inverse Simple Equation 35 2D		y = a*exp(b*x)/x y = x / y
Inverse Simple Equation 38 2D		y = a*pow(x,b)/ln(x) y = x / y
Inverse Simple Equation 39 2D		y = a*pow(x,b)*ln(x+c) y = x / y
Inverse Simple Equation 40 2D		y = a*pow(ln(x+b),c) y = x / y
Inverse Simple Equation 41 2D		y = a*pow(x,b/x)+c*x y = x / y
Inverse Simple Equation 42 2D		y = a*pow(x,b/x)+c*ln(x) y = x / y
Inverse Square Modified 2D		y = x2 - ax y = x / y
Inverse Square Modified Transform 2D		y = (bx + c)2 - a(bx + c) y = x / y
Inverse Transition State Rate Constant Law 2D		y = axb * exp(-c/x) y = x / y
Inverse Witch Of Maria Agnesi A 2D		y = 8a3 / (x2 + 4a2) y = x / y
Inverse Witch Of Maria Agnesi B 2D		y = a3 / (x2 + a2) y = x / y
Inverse Witch Of Maria Agnesi C 2D		y = a3 / ((x * b + c)2 + a2) y = x / y
Inverse Arrhenius Rate Constant Law Stretched With Offset 2D		y = a * exp(-pow(b/x, c)) y = x / y + Offset
Inverse Arrhenius Rate Constant Law With Offset 2D		y = a * exp(-b/x) y = x / y + Offset
Inverse Bleasdale-Nelder Power With Offset 2D		y = (a + bxc)-1/d y = x / y + Offset
Inverse Bleasdale-Nelder With Offset 2D		y = (a + bx)-1/c y = x / y + Offset
Inverse Catenary Transform With Offset 2D		y = a * cosh((bx + c) / a) y = x / y + Offset   [web citation]
Inverse Catenary With Offset 2D		y = a * cosh(x / a) y = x / y + Offset   [web citation]
Inverse Double Langmuir Probe Characteristic With Offset 2D		y = a * tanh(bx+c) y = x / y + Offset
Inverse Double Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + cx/(d+x) y = x / y + Offset
Inverse Double Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = x / y + Offset
Inverse Hyperbolic Decay With Offset 2D		y = ab/(b+x) y = x / y + Offset
Inverse Lame's Cubic Transform With Offset 2D		y = (a3 - (bx + c)3)1/3 y = x / y + Offset   [web citation]
Inverse Lame's Cubic With Offset 2D		y = (a3 - x3)1/3 y = x / y + Offset   [web citation]
Inverse Miscellaneous 1 With Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = x / y + Offset
Inverse Nelder With Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = x / y + Offset
Inverse Pareto A With Offset 2D		y = 1 - x-a y = x / y + Offset
Inverse Pareto B With Offset 2D		y = a(1 - x-b) y = x / y + Offset
Inverse Pareto C With Offset 2D		y = 1.0 - (1.0 / (1 + ax)b y = x / y + Offset
Inverse Pareto D With Offset 2D		y = 1.0 - (1.0 / xa) y = x / y + Offset
Inverse Polytrope Transform With Offset 2D		y = a / (cx + d)b y = x / y + Offset   [web citation]
Inverse Pursuit Curve Transform With Offset 2D		y = a(bx + c)2 - log(bx + c) y = x / y + Offset
Inverse Pursuit Curve With Offset 2D		y = ax2 - log(x) y = x / y + Offset
Inverse Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx y = x / y + Offset
Inverse Shifted Reciprocal With Offset 2D		y = 1.0 / (a - x) y = x / y + Offset
Inverse Simple Equation 03 With Offset 2D		y = a*pow(ln(x),b) y = x / y + Offset
Inverse Simple Equation 07 With Offset 2D		y = a * pow(b,x) * pow(x,c) y = x / y + Offset
Inverse Simple Equation 08 With Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) y = x / y + Offset
Inverse Simple Equation 09 With Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = x / y + Offset
Inverse Simple Equation 10 With Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = x / y + Offset
Inverse Simple Equation 11 With Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) y = x / y + Offset
Inverse Simple Equation 13 With Offset 2D		y = a*pow(x/b,c)*exp(x/b) y = x / y + Offset
Inverse Simple Equation 15 With Offset 2D		y = a*pow(x,b+c/x) y = x / y + Offset
Inverse Simple Equation 16 With Offset 2D		y = a*pow(x,b+c*ln(x)) y = x / y + Offset
Inverse Simple Equation 17 With Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = x / y + Offset
Inverse Simple Equation 18 With Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) y = x / y + Offset
Inverse Simple Equation 19 With Offset 2D		y = a*exp(b/x+c*x) y = x / y + Offset
Inverse Simple Equation 20 With Offset 2D		y = (a+x)/(b+c*x) y = x / y + Offset
Inverse Simple Equation 21 With Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = x / y + Offset
Inverse Simple Equation 22 With Offset 2D		y = a*(exp(b*x)-exp(c*x)) y = x / y + Offset
Inverse Simple Equation 23 With Offset 2D		y = a*exp(b*exp(c*x)) y = x / y + Offset
Inverse Simple Equation 24 With Offset 2D		y = a/(1.0 + b * exp(c*x)) y = x / y + Offset
Inverse Simple Equation 25 With Offset 2D		y = a/(b+pow(x,c)) y = x / y + Offset
Inverse Simple Equation 26 With Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = x / y + Offset
Inverse Simple Equation 27 With Offset 2D		y = pow(a+b*x,c) y = x / y + Offset
Inverse Simple Equation 28 With Offset 2D		y = exp(a+b/x+c*ln(x)) y = x / y + Offset
Inverse Simple Equation 29 With Offset 2D		y = a*exp(b*pow(x,c)) y = x / y + Offset
Inverse Simple Equation 30 With Offset 2D		y = a*pow(x,b*pow(x,c)) y = x / y + Offset
Inverse Simple Equation 31 With Offset 2D		y = a*ln(x+b) y = x / y + Offset
Inverse Simple Equation 32 With Offset 2D		y = a/x+b*pow(x,c) y = x / y + Offset
Inverse Simple Equation 33 With Offset 2D		y = a/x+b*exp(c/x) y = x / y + Offset
Inverse Simple Equation 34 With Offset 2D		y = a/x+b*exp(c*x) y = x / y + Offset
Inverse Simple Equation 35 With Offset 2D		y = a*exp(b*x)/x y = x / y + Offset
Inverse Simple Equation 38 With Offset 2D		y = a*pow(x,b)/ln(x) y = x / y + Offset
Inverse Simple Equation 39 With Offset 2D		y = a*pow(x,b)*ln(x+c) y = x / y + Offset
Inverse Simple Equation 40 With Offset 2D		y = a*pow(ln(x+b),c) y = x / y + Offset
Inverse Simple Equation 41 With Offset 2D		y = a*pow(x,b/x)+c*x y = x / y + Offset
Inverse Simple Equation 42 With Offset 2D		y = a*pow(x,b/x)+c*ln(x) y = x / y + Offset
Inverse Square Modified Transform With Offset 2D		y = (bx + c)2 - a(bx + c) y = x / y + Offset
Inverse Square Modified With Offset 2D		y = x2 - ax y = x / y + Offset
Inverse Transition State Rate Constant Law With Offset 2D		y = axb * exp(-c/x) y = x / y + Offset
Inverse Witch Of Maria Agnesi A With Offset 2D		y = 8a3 / (x2 + 4a2) y = x / y + Offset
Inverse Witch Of Maria Agnesi B With Offset 2D		y = a3 / (x2 + a2) y = x / y + Offset
Inverse Witch Of Maria Agnesi C With Offset 2D		y = a3 / ((x * b + c)2 + a2) y = x / y + Offset
Arrhenius Rate Constant Law Stretched With Linear Decay 2D		y = a * exp(-pow(b/x, c)) y = y / x
Arrhenius Rate Constant Law With Linear Decay 2D		y = a * exp(-b/x) y = y / x
Bleasdale-Nelder Power With Linear Decay 2D		y = (a + bxc)-1/d y = y / (g * x)
Bleasdale-Nelder With Linear Decay 2D		y = (a + bx)-1/c y = y / (f * x)
Catenary Transform With Linear Decay 2D		y = a * cosh((bx + c) / a) y = y / x   [web citation]
Catenary With Linear Decay 2D		y = a * cosh(x / a) y = y / x   [web citation]
Combined Power And Exponential With Linear Decay 2D		y = axb * exp(cx) y = y / x
David Rodbard NIH With Linear Decay 2D		y = d + (a - d) / (1.0 + (x/c)b) y = y / (g * x)   [web citation]
Double Langmuir Probe Characteristic With Linear Decay 2D		y = a * tanh(bx+c) y = y / x
Double Rectangular Hyperbola A With Linear Decay 2D		y = ax/(b+x) + cx/(d+x) y = y / (g * x)
Double Rectangular Hyperbola B With Linear Decay 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (h * x)
Gunary With Linear Decay 2D		y = x / (a + bx + cx0.5) y = y / (f * x)
Hyperbola A Modified With Linear Decay 2D		y = ax/(1+bx) y = y / x
Hyperbola B Modified With Linear Decay 2D		y = x/(a+bx) y = y / (d * x)
Hyperbolic Decay With Linear Decay 2D		y = ab/(b+x) y = y / x
Lame's Cubic Transform With Linear Decay 2D		y = (a3 - (bx + c)3)1/3 y = y / (f * x)   [web citation]
Lame's Cubic With Linear Decay 2D		y = (a3 - x3)1/3 y = y / (c * x)   [web citation]
Miscellaneous 1 With Linear Decay 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (d * x)
Nelder With Linear Decay 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y / (g * x)
Pareto A With Linear Decay 2D		y = 1 - x-a y = y / (c * x)
Pareto B With Linear Decay 2D		y = a(1 - x-b) y = y / x
Pareto C With Linear Decay 2D		y = 1.0 - (1.0 / (1 + ax)b y = y / (d * x)
Pareto D With Linear Decay 2D		y = 1.0 - (1.0 / xa) y = y / (c * x)
Polytrope Transform With Linear Decay 2D		y = a / (cx + d)b y = y / x   [web citation]
Polytrope With Linear Decay 2D		y = a / xb y = y / x   [web citation]
Pursuit Curve Transform With Linear Decay 2D		y = a(bx + c)2 - log(bx + c) y = y / (f * x)
Pursuit Curve With Linear Decay 2D		y = ax2 - log(x) y = y / (c * x)
Rectangular Hyperbola A With Linear Decay 2D		y = ax/(b+x) y = y / x
Rectangular Hyperbola B With Linear Decay 2D		y = ax/(b+x) + cx y = y / (f * x)
Serpentine With Linear Decay 2D		y = ax / (1.0 + bx2) y = y / x
Shifted Reciprocal With Linear Decay 2D		y = 1.0 / (a - x) y = y / (c * x)
Simple Equation 02 With Linear Decay 2D		y = a/pow(x,2.0) y = y / x
Simple Equation 03 With Linear Decay 2D		y = a*pow(ln(x),b) y = y / x
Simple Equation 04 With Linear Decay 2D		y = a*pow(x,3.0) y = y / x
Simple Equation 05 With Linear Decay 2D		y = a*pow(x,4.0) y = y / x
Simple Equation 06 With Linear Decay 2D		y = x/(a+b*pow(x,2.0)) y = y / (d * x)
Simple Equation 07 With Linear Decay 2D		y = a * pow(b,x) * pow(x,c) y = y / x
Simple Equation 08 With Linear Decay 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y / x
Simple Equation 09 With Linear Decay 2D		y = a*exp(pow(x-b,2.0)/c) y = y / x
Simple Equation 10 With Linear Decay 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / x
Simple Equation 11 With Linear Decay 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y / x
Simple Equation 13 With Linear Decay 2D		y = a*pow(x/b,c)*exp(x/b) y = y / x
Simple Equation 14 With Linear Decay 2D		y = a*pow(x,b+c*x) y = y / x
Simple Equation 15 With Linear Decay 2D		y = a*pow(x,b+c/x) y = y / x
Simple Equation 16 With Linear Decay 2D		y = a*pow(x,b+c*ln(x)) y = y / x
Simple Equation 17 With Linear Decay 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y / x
Simple Equation 18 With Linear Decay 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y / x
Simple Equation 19 With Linear Decay 2D		y = a*exp(b/x+c*x) y = y / x
Simple Equation 20 With Linear Decay 2D		y = (a+x)/(b+c*x) y = y / (f * x)
Simple Equation 21 With Linear Decay 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y / (f * x)
Simple Equation 22 With Linear Decay 2D		y = a*(exp(b*x)-exp(c*x)) y = y / x
Simple Equation 23 With Linear Decay 2D		y = a*exp(b*exp(c*x)) y = y / x
Simple Equation 24 With Linear Decay 2D		y = a/(1.0 + b * exp(c*x)) y = y / x
Simple Equation 25 With Linear Decay 2D		y = a/(b+pow(x,c)) y = y / x
Simple Equation 26 With Linear Decay 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / x
Simple Equation 27 With Linear Decay 2D		y = pow(a+b*x,c) y = y / (f * x)
Simple Equation 28 With Linear Decay 2D		y = exp(a+b/x+c*ln(x)) y = y / (f * x)
Simple Equation 29 With Linear Decay 2D		y = a*exp(b*pow(x,c)) y = y / x
Simple Equation 30 With Linear Decay 2D		y = a*pow(x,b*pow(x,c)) y = y / x
Simple Equation 31 With Linear Decay 2D		y = a*ln(x+b) y = y / x
Simple Equation 32 With Linear Decay 2D		y = a/x+b*pow(x,c) y = y / (f * x)
Simple Equation 33 With Linear Decay 2D		y = a/x+b*exp(c/x) y = y / (f * x)
Simple Equation 34 With Linear Decay 2D		y = a/x+b*exp(c*x) y = y / (f * x)
Simple Equation 35 With Linear Decay 2D		y = a*exp(b*x)/x y = y / x
Simple Equation 36 With Linear Decay 2D		y = a*exp(b/x)/x y = y / x
Simple Equation 37 With Linear Decay 2D		y = a*pow(x,b)*ln(x) y = y / x
Simple Equation 38 With Linear Decay 2D		y = a*pow(x,b)/ln(x) y = y / x
Simple Equation 39 With Linear Decay 2D		y = a*pow(x,b)*ln(x+c) y = y / x
Simple Equation 40 With Linear Decay 2D		y = a*pow(ln(x+b),c) y = y / x
Simple Equation 41 With Linear Decay 2D		y = a*pow(x,b/x)+c*x y = y / x
Simple Equation 42 With Linear Decay 2D		y = a*pow(x,b/x)+c*ln(x) y = y / (f * x)
Simple Reciprocal With Linear Decay 2D		y = a / x y = y / x
Square Modified Transform With Linear Decay 2D		y = (bx + c)2 - a(bx + c) y = y / (f * x)
Square Modified With Linear Decay 2D		y = x2 - ax y = y / (c * x)
Transition State Rate Constant Law With Linear Decay 2D		y = axb * exp(-c/x) y = y / x
Witch Of Maria Agnesi A With Linear Decay 2D		y = 8a3 / (x2 + 4a2) y = y / (c * x)
Witch Of Maria Agnesi B With Linear Decay 2D		y = a3 / (x2 + a2) y = y / (c * x)
Witch Of Maria Agnesi C With Linear Decay 2D		y = a3 / ((x * b + c)2 + a2) y = y / (f * x)
Arrhenius Rate Constant Law Stretched With Linear Decay And Offset 2D		y = a * exp(-pow(b/x, c)) y = y / x + Offset
Arrhenius Rate Constant Law With Linear Decay And Offset 2D		y = a * exp(-b/x) y = y / x + Offset
Bleasdale-Nelder Power With Linear Decay And Offset 2D		y = (a + bxc)-1/d y = y / (h * x) + Offset
Bleasdale-Nelder With Linear Decay And Offset 2D		y = (a + bx)-1/c y = y / (g * x) + Offset
Catenary Transform With Linear Decay And Offset 2D		y = a * cosh((bx + c) / a) y = y / x + Offset   [web citation]
Catenary With Linear Decay And Offset 2D		y = a * cosh(x / a) y = y / x + Offset   [web citation]
Combined Power And Exponential With Linear Decay And Offset 2D		y = axb * exp(cx) y = y / x + Offset
Double Langmuir Probe Characteristic With Linear Decay And Offset 2D		y = a * tanh(bx+c) y = y / x + Offset
Double Rectangular Hyperbola A With Linear Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y / (h * x) + Offset
Double Rectangular Hyperbola B With Linear Decay And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y / (i * x) + Offset
Gunary With Linear Decay And Offset 2D		y = x / (a + bx + cx0.5) y = y / (g * x) + Offset
Hyperbola A Modified With Linear Decay And Offset 2D		y = ax/(1+bx) y = y / x + Offset
Hyperbola B Modified With Linear Decay And Offset 2D		y = x/(a+bx) y = y / (f * x) + Offset
Hyperbolic Decay With Linear Decay And Offset 2D		y = ab/(b+x) y = y / x + Offset
Lame's Cubic Transform With Linear Decay And Offset 2D		y = (a3 - (bx + c)3)1/3 y = y / (g * x) + Offset   [web citation]
Lame's Cubic With Linear Decay And Offset 2D		y = (a3 - x3)1/3 y = y / (d * x) + Offset   [web citation]
Miscellaneous 1 With Linear Decay And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y / (f * x) + Offset
Nelder With Linear Decay And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y / (h * x) + Offset
Pareto A With Linear Decay And Offset 2D		y = 1 - x-a y = y / (d * x) + Offset
Pareto B With Linear Decay And Offset 2D		y = a(1 - x-b) y = y / x + Offset
Pareto C With Linear Decay And Offset 2D		y = 1.0 - (1.0 / (1 + ax)b y = y / (f * x) + Offset
Pareto D With Linear Decay And Offset 2D		y = 1.0 - (1.0 / xa) y = y / (d * x) + Offset
Polytrope Transform With Linear Decay And Offset 2D		y = a / (cx + d)b y = y / x + Offset   [web citation]
Polytrope With Linear Decay And Offset 2D		y = a / xb y = y / x + Offset   [web citation]
Pursuit Curve Transform With Linear Decay And Offset 2D		y = a(bx + c)2 - log(bx + c) y = y / (g * x) + Offset
Pursuit Curve With Linear Decay And Offset 2D		y = ax2 - log(x) y = y / (d * x) + Offset
Rectangular Hyperbola A With Linear Decay And Offset 2D		y = ax/(b+x) y = y / x + Offset
Rectangular Hyperbola B With Linear Decay And Offset 2D		y = ax/(b+x) + cx y = y / (g * x) + Offset
Serpentine With Linear Decay And Offset 2D		y = ax / (1.0 + bx2) y = y / x + Offset
Shifted Reciprocal With Linear Decay And Offset 2D		y = 1.0 / (a - x) y = y / (d * x) + Offset
Simple Equation 02 With Linear Decay And Offset 2D		y = a/pow(x,2.0) y = y / x + Offset
Simple Equation 03 With Linear Decay And Offset 2D		y = a*pow(ln(x),b) y = y / x + Offset
Simple Equation 04 With Linear Decay And Offset 2D		y = a*pow(x,3.0) y = y / x + Offset
Simple Equation 05 With Linear Decay And Offset 2D		y = a*pow(x,4.0) y = y / x + Offset
Simple Equation 06 With Linear Decay And Offset 2D		y = x/(a+b*pow(x,2.0)) y = y / (f * x) + Offset
Simple Equation 07 With Linear Decay And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y / x + Offset
Simple Equation 08 With Linear Decay And Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y / x + Offset
Simple Equation 09 With Linear Decay And Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = y / x + Offset
Simple Equation 10 With Linear Decay And Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y / x + Offset
Simple Equation 11 With Linear Decay And Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y / x + Offset
Simple Equation 13 With Linear Decay And Offset 2D		y = a*pow(x/b,c)*exp(x/b) y = y / x + Offset
Simple Equation 14 With Linear Decay And Offset 2D		y = a*pow(x,b+c*x) y = y / x + Offset
Simple Equation 15 With Linear Decay And Offset 2D		y = a*pow(x,b+c/x) y = y / x + Offset
Simple Equation 16 With Linear Decay And Offset 2D		y = a*pow(x,b+c*ln(x)) y = y / x + Offset
Simple Equation 17 With Linear Decay And Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y / x + Offset
Simple Equation 18 With Linear Decay And Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y / x + Offset
Simple Equation 19 With Linear Decay And Offset 2D		y = a*exp(b/x+c*x) y = y / x + Offset
Simple Equation 20 With Linear Decay And Offset 2D		y = (a+x)/(b+c*x) y = y / (g * x) + Offset
Simple Equation 21 With Linear Decay And Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y / (g * x) + Offset
Simple Equation 22 With Linear Decay And Offset 2D		y = a*(exp(b*x)-exp(c*x)) y = y / x + Offset
Simple Equation 23 With Linear Decay And Offset 2D		y = a*exp(b*exp(c*x)) y = y / x + Offset
Simple Equation 24 With Linear Decay And Offset 2D		y = a/(1.0 + b * exp(c*x)) y = y / x + Offset
Simple Equation 25 With Linear Decay And Offset 2D		y = a/(b+pow(x,c)) y = y / x + Offset
Simple Equation 26 With Linear Decay And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y / x + Offset
Simple Equation 27 With Linear Decay And Offset 2D		y = pow(a+b*x,c) y = y / (g * x) + Offset
Simple Equation 28 With Linear Decay And Offset 2D		y = exp(a+b/x+c*ln(x)) y = y / (g * x) + Offset
Simple Equation 29 With Linear Decay And Offset 2D		y = a*exp(b*pow(x,c)) y = y / x + Offset
Simple Equation 30 With Linear Decay And Offset 2D		y = a*pow(x,b*pow(x,c)) y = y / x + Offset
Simple Equation 31 With Linear Decay And Offset 2D		y = a*ln(x+b) y = y / x + Offset
Simple Equation 32 With Linear Decay And Offset 2D		y = a/x+b*pow(x,c) y = y / (g * x) + Offset
Simple Equation 33 With Linear Decay And Offset 2D		y = a/x+b*exp(c/x) y = y / (g * x) + Offset
Simple Equation 34 With Linear Decay And Offset 2D		y = a/x+b*exp(c*x) y = y / (g * x) + Offset
Simple Equation 35 With Linear Decay And Offset 2D		y = a*exp(b*x)/x y = y / x + Offset
Simple Equation 36 With Linear Decay And Offset 2D		y = a*exp(b/x)/x y = y / x + Offset
Simple Equation 37 With Linear Decay And Offset 2D		y = a*pow(x,b)*ln(x) y = y / x + Offset
Simple Equation 38 With Linear Decay And Offset 2D		y = a*pow(x,b)/ln(x) y = y / x + Offset
Simple Equation 39 With Linear Decay And Offset 2D		y = a*pow(x,b)*ln(x+c) y = y / x + Offset
Simple Equation 40 With Linear Decay And Offset 2D		y = a*pow(ln(x+b),c) y = y / x + Offset
Simple Equation 41 With Linear Decay And Offset 2D		y = a*pow(x,b/x)+c*x y = y / x + Offset
Simple Equation 42 With Linear Decay And Offset 2D		y = a*pow(x,b/x)+c*ln(x) y = y / (g * x) + Offset
Simple Reciprocal With Linear Decay And Offset 2D		y = a / x y = y / x + Offset
Square Modified Transform With Linear Decay And Offset 2D		y = (bx + c)2 - a(bx + c) y = y / (g * x) + Offset
Square Modified With Linear Decay And Offset 2D		y = x2 - ax y = y / (d * x) + Offset
Transition State Rate Constant Law With Linear Decay And Offset 2D		y = axb * exp(-c/x) y = y / x + Offset
Witch Of Maria Agnesi A With Linear Decay And Offset 2D		y = 8a3 / (x2 + 4a2) y = y / (d * x) + Offset
Witch Of Maria Agnesi B With Linear Decay And Offset 2D		y = a3 / (x2 + a2) y = y / (d * x) + Offset
Witch Of Maria Agnesi C With Linear Decay And Offset 2D		y = a3 / ((x * b + c)2 + a2) y = y / (g * x) + Offset
Arrhenius Rate Constant Law Stretched With Linear Growth 2D		y = a * exp(-pow(b/x, c)) y = y * x
Arrhenius Rate Constant Law With Linear Growth 2D		y = a * exp(-b/x) y = y * x
Bleasdale-Nelder Power With Linear Growth 2D		y = (a + bxc)-1/d y = y * (g * x) + Offset
Bleasdale-Nelder With Linear Growth 2D		y = (a + bx)-1/c y = y * (f * x) + Offset
Catenary Transform With Linear Growth 2D		y = a * cosh((bx + c) / a) y = y * x   [web citation]
Catenary With Linear Growth 2D		y = a * cosh(x / a) y = y * x   [web citation]
Combined Power And Exponential With Linear Growth 2D		y = axb * exp(cx) y = y * x
David Rodbard NIH With Linear Growth 2D		y = d + (a - d) / (1.0 + (x/c)b) y = y * (g * x) + Offset   [web citation]
Double Langmuir Probe Characteristic With Linear Growth 2D		y = a * tanh(bx+c) y = y * x
Double Rectangular Hyperbola A With Linear Growth 2D		y = ax/(b+x) + cx/(d+x) y = y * (g * x) + Offset
Double Rectangular Hyperbola B With Linear Growth 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (h * x) + Offset
Gunary With Linear Growth 2D		y = x / (a + bx + cx0.5) y = y * (f * x) + Offset
Hyperbola A Modified With Linear Growth 2D		y = ax/(1+bx) y = y * x
Hyperbola B Modified With Linear Growth 2D		y = x/(a+bx) y = y * (d * x) + Offset
Hyperbolic Decay With Linear Growth 2D		y = ab/(b+x) y = y * x
Lame's Cubic Transform With Linear Growth 2D		y = (a3 - (bx + c)3)1/3 y = y * (f * x) + Offset   [web citation]
Lame's Cubic With Linear Growth 2D		y = (a3 - x3)1/3 y = y * (c * x) + Offset   [web citation]
Miscellaneous 1 With Linear Growth 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (d * x) + Offset
Nelder With Linear Growth 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y * (g * x) + Offset
Pareto A With Linear Growth 2D		y = 1 - x-a y = y * (c * x) + Offset
Pareto B With Linear Growth 2D		y = a(1 - x-b) y = y * x
Pareto C With Linear Growth 2D		y = 1.0 - (1.0 / (1 + ax)b y = y * (d * x) + Offset
Pareto D With Linear Growth 2D		y = 1.0 - (1.0 / xa) y = y * (c * x) + Offset
Polytrope Transform With Linear Growth 2D		y = a / (cx + d)b y = y * x   [web citation]
Polytrope With Linear Growth 2D		y = a / xb y = y * x   [web citation]
Pursuit Curve Transform With Linear Growth 2D		y = a(bx + c)2 - log(bx + c) y = y * (f * x) + Offset
Pursuit Curve With Linear Growth 2D		y = ax2 - log(x) y = y * (c * x) + Offset
Rectangular Hyperbola A With Linear Growth 2D		y = ax/(b+x) y = y * x
Rectangular Hyperbola B With Linear Growth 2D		y = ax/(b+x) + cx y = y * (f * x) + Offset
Serpentine With Linear Growth 2D		y = ax / (1.0 + bx2) y = y * x
Shifted Reciprocal With Linear Growth 2D		y = 1.0 / (a - x) y = y * (c * x) + Offset
Simple Equation 02 With Linear Growth 2D		y = a/pow(x,2.0) y = y * x
Simple Equation 03 With Linear Growth 2D		y = a*pow(ln(x),b) y = y * x
Simple Equation 04 With Linear Growth 2D		y = a*pow(x,3.0) y = y * x
Simple Equation 05 With Linear Growth 2D		y = a*pow(x,4.0) y = y * x
Simple Equation 06 With Linear Growth 2D		y = x/(a+b*pow(x,2.0)) y = y * (d * x) + Offset
Simple Equation 07 With Linear Growth 2D		y = a * pow(b,x) * pow(x,c) y = y * x
Simple Equation 08 With Linear Growth 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y * x
Simple Equation 09 With Linear Growth 2D		y = a*exp(pow(x-b,2.0)/c) y = y * x
Simple Equation 10 With Linear Growth 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y * x
Simple Equation 11 With Linear Growth 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y * x
Simple Equation 13 With Linear Growth 2D		y = a*pow(x/b,c)*exp(x/b) y = y * x
Simple Equation 14 With Linear Growth 2D		y = a*pow(x,b+c*x) y = y * x
Simple Equation 15 With Linear Growth 2D		y = a*pow(x,b+c/x) y = y * x
Simple Equation 16 With Linear Growth 2D		y = a*pow(x,b+c*ln(x)) y = y * x
Simple Equation 17 With Linear Growth 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y * x
Simple Equation 18 With Linear Growth 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y * x
Simple Equation 19 With Linear Growth 2D		y = a*exp(b/x+c*x) y = y * x
Simple Equation 20 With Linear Growth 2D		y = (a+x)/(b+c*x) y = y * (f * x) + Offset
Simple Equation 21 With Linear Growth 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y * (f * x) + Offset
Simple Equation 22 With Linear Growth 2D		y = a*(exp(b*x)-exp(c*x)) y = y * x
Simple Equation 23 With Linear Growth 2D		y = a*exp(b*exp(c*x)) y = y * x
Simple Equation 24 With Linear Growth 2D		y = a/(1.0 + b * exp(c*x)) y = y * x
Simple Equation 25 With Linear Growth 2D		y = a/(b+pow(x,c)) y = y * x
Simple Equation 26 With Linear Growth 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * x
Simple Equation 27 With Linear Growth 2D		y = pow(a+b*x,c) y = y * (f * x) + Offset
Simple Equation 28 With Linear Growth 2D		y = exp(a+b/x+c*ln(x)) y = y * (f * x) + Offset
Simple Equation 29 With Linear Growth 2D		y = a*exp(b*pow(x,c)) y = y * x
Simple Equation 30 With Linear Growth 2D		y = a*pow(x,b*pow(x,c)) y = y * x
Simple Equation 31 With Linear Growth 2D		y = a*ln(x+b) y = y * x
Simple Equation 32 With Linear Growth 2D		y = a/x+b*pow(x,c) y = y * (f * x) + Offset
Simple Equation 33 With Linear Growth 2D		y = a/x+b*exp(c/x) y = y * (f * x) + Offset
Simple Equation 34 With Linear Growth 2D		y = a/x+b*exp(c*x) y = y * (f * x) + Offset
Simple Equation 35 With Linear Growth 2D		y = a*exp(b*x)/x y = y * x
Simple Equation 36 With Linear Growth 2D		y = a*exp(b/x)/x y = y * x
Simple Equation 37 With Linear Growth 2D		y = a*pow(x,b)*ln(x) y = y * x
Simple Equation 38 With Linear Growth 2D		y = a*pow(x,b)/ln(x) y = y * x
Simple Equation 39 With Linear Growth 2D		y = a*pow(x,b)*ln(x+c) y = y * x
Simple Equation 40 With Linear Growth 2D		y = a*pow(ln(x+b),c) y = y * x
Simple Equation 41 With Linear Growth 2D		y = a*pow(x,b/x)+c*x y = y * x
Simple Equation 42 With Linear Growth 2D		y = a*pow(x,b/x)+c*ln(x) y = y * (f * x) + Offset
Simple Reciprocal With Linear Growth 2D		y = a / x y = y * x
Square Modified Transform With Linear Growth 2D		y = (bx + c)2 - a(bx + c) y = y * (f * x) + Offset
Square Modified With Linear Growth 2D		y = x2 - ax y = y * (c * x) + Offset
Transition State Rate Constant Law With Linear Growth 2D		y = axb * exp(-c/x) y = y * x
Witch Of Maria Agnesi A With Linear Growth 2D		y = 8a3 / (x2 + 4a2) y = y * (c * x) + Offset
Witch Of Maria Agnesi B With Linear Growth 2D		y = a3 / (x2 + a2) y = y * (c * x) + Offset
Witch Of Maria Agnesi C With Linear Growth 2D		y = a3 / ((x * b + c)2 + a2) y = y * (f * x) + Offset
Arrhenius Rate Constant Law Stretched With Linear Growth And Offset 2D		y = a * exp(-pow(b/x, c)) y = y * x + Offset
Arrhenius Rate Constant Law With Linear Growth And Offset 2D		y = a * exp(-b/x) y = y * x + Offset
Bleasdale-Nelder Power With Linear Growth And Offset 2D		y = (a + bxc)-1/d y = y * (h * x) + Offset
Bleasdale-Nelder With Linear Growth And Offset 2D		y = (a + bx)-1/c y = y * (g * x) + Offset
Catenary Transform With Linear Growth And Offset 2D		y = a * cosh((bx + c) / a) y = y * x + Offset   [web citation]
Catenary With Linear Growth And Offset 2D		y = a * cosh(x / a) y = y * x + Offset   [web citation]
Combined Power And Exponential With Linear Growth And Offset 2D		y = axb * exp(cx) y = y * x + Offset
Double Langmuir Probe Characteristic With Linear Growth And Offset 2D		y = a * tanh(bx+c) y = y * x + Offset
Double Rectangular Hyperbola A With Linear Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) y = y * (h * x) + Offset
Double Rectangular Hyperbola B With Linear Growth And Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = y * (i * x) + Offset
Gunary With Linear Growth And Offset 2D		y = x / (a + bx + cx0.5) y = y * (g * x) + Offset
Hyperbola A Modified With Linear Growth And Offset 2D		y = ax/(1+bx) y = y * x + Offset
Hyperbola B Modified With Linear Growth And Offset 2D		y = x/(a+bx) y = y * (f * x) + Offset
Hyperbolic Decay With Linear Growth And Offset 2D		y = ab/(b+x) y = y * x + Offset
Lame's Cubic Transform With Linear Growth And Offset 2D		y = (a3 - (bx + c)3)1/3 y = y * (g * x) + Offset   [web citation]
Lame's Cubic With Linear Growth And Offset 2D		y = (a3 - x3)1/3 y = y * (d * x) + Offset   [web citation]
Miscellaneous 1 With Linear Growth And Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = y * (f * x) + Offset
Nelder With Linear Growth And Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = y * (h * x) + Offset
Pareto A With Linear Growth And Offset 2D		y = 1 - x-a y = y * (d * x) + Offset
Pareto B With Linear Growth And Offset 2D		y = a(1 - x-b) y = y * x + Offset
Pareto C With Linear Growth And Offset 2D		y = 1.0 - (1.0 / (1 + ax)b y = y * (f * x) + Offset
Pareto D With Linear Growth And Offset 2D		y = 1.0 - (1.0 / xa) y = y * (d * x) + Offset
Polytrope Transform With Linear Growth And Offset 2D		y = a / (cx + d)b y = y * x + Offset   [web citation]
Polytrope With Linear Growth And Offset 2D		y = a / xb y = y * x + Offset   [web citation]
Pursuit Curve Transform With Linear Growth And Offset 2D		y = a(bx + c)2 - log(bx + c) y = y * (g * x) + Offset
Pursuit Curve With Linear Growth And Offset 2D		y = ax2 - log(x) y = y * (d * x) + Offset
Rectangular Hyperbola A With Linear Growth And Offset 2D		y = ax/(b+x) y = y * x + Offset
Rectangular Hyperbola B With Linear Growth And Offset 2D		y = ax/(b+x) + cx y = y * (g * x) + Offset
Serpentine With Linear Growth And Offset 2D		y = ax / (1.0 + bx2) y = y * x + Offset
Shifted Reciprocal With Linear Growth And Offset 2D		y = 1.0 / (a - x) y = y * (d * x) + Offset
Simple Equation 02 With Linear Growth And Offset 2D		y = a/pow(x,2.0) y = y * x + Offset
Simple Equation 03 With Linear Growth And Offset 2D		y = a*pow(ln(x),b) y = y * x + Offset
Simple Equation 04 With Linear Growth And Offset 2D		y = a*pow(x,3.0) y = y * x + Offset
Simple Equation 05 With Linear Growth And Offset 2D		y = a*pow(x,4.0) y = y * x + Offset
Simple Equation 06 With Linear Growth And Offset 2D		y = x/(a+b*pow(x,2.0)) y = y * (f * x) + Offset
Simple Equation 07 With Linear Growth And Offset 2D		y = a * pow(b,x) * pow(x,c) y = y * x + Offset
Simple Equation 08 With Linear Growth And Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) y = y * x + Offset
Simple Equation 09 With Linear Growth And Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = y * x + Offset
Simple Equation 10 With Linear Growth And Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = y * x + Offset
Simple Equation 11 With Linear Growth And Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) y = y * x + Offset
Simple Equation 13 With Linear Growth And Offset 2D		y = a*pow(x/b,c)*exp(x/b) y = y * x + Offset
Simple Equation 14 With Linear Growth And Offset 2D		y = a*pow(x,b+c*x) y = y * x + Offset
Simple Equation 15 With Linear Growth And Offset 2D		y = a*pow(x,b+c/x) y = y * x + Offset
Simple Equation 16 With Linear Growth And Offset 2D		y = a*pow(x,b+c*ln(x)) y = y * x + Offset
Simple Equation 17 With Linear Growth And Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = y * x + Offset
Simple Equation 18 With Linear Growth And Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) y = y * x + Offset
Simple Equation 19 With Linear Growth And Offset 2D		y = a*exp(b/x+c*x) y = y * x + Offset
Simple Equation 20 With Linear Growth And Offset 2D		y = (a+x)/(b+c*x) y = y * (g * x) + Offset
Simple Equation 21 With Linear Growth And Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = y * (g * x) + Offset
Simple Equation 22 With Linear Growth And Offset 2D		y = a*(exp(b*x)-exp(c*x)) y = y * x + Offset
Simple Equation 23 With Linear Growth And Offset 2D		y = a*exp(b*exp(c*x)) y = y * x + Offset
Simple Equation 24 With Linear Growth And Offset 2D		y = a/(1.0 + b * exp(c*x)) y = y * x + Offset
Simple Equation 25 With Linear Growth And Offset 2D		y = a/(b+pow(x,c)) y = y * x + Offset
Simple Equation 26 With Linear Growth And Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = y * x + Offset
Simple Equation 27 With Linear Growth And Offset 2D		y = pow(a+b*x,c) y = y * (g * x) + Offset
Simple Equation 28 With Linear Growth And Offset 2D		y = exp(a+b/x+c*ln(x)) y = y * (g * x) + Offset
Simple Equation 29 With Linear Growth And Offset 2D		y = a*exp(b*pow(x,c)) y = y * x + Offset
Simple Equation 30 With Linear Growth And Offset 2D		y = a*pow(x,b*pow(x,c)) y = y * x + Offset
Simple Equation 31 With Linear Growth And Offset 2D		y = a*ln(x+b) y = y * x + Offset
Simple Equation 32 With Linear Growth And Offset 2D		y = a/x+b*pow(x,c) y = y * (g * x) + Offset
Simple Equation 33 With Linear Growth And Offset 2D		y = a/x+b*exp(c/x) y = y * (g * x) + Offset
Simple Equation 34 With Linear Growth And Offset 2D		y = a/x+b*exp(c*x) y = y * (g * x) + Offset
Simple Equation 35 With Linear Growth And Offset 2D		y = a*exp(b*x)/x y = y * x + Offset
Simple Equation 36 With Linear Growth And Offset 2D		y = a*exp(b/x)/x y = y * x + Offset
Simple Equation 37 With Linear Growth And Offset 2D		y = a*pow(x,b)*ln(x) y = y * x + Offset
Simple Equation 38 With Linear Growth And Offset 2D		y = a*pow(x,b)/ln(x) y = y * x + Offset
Simple Equation 39 With Linear Growth And Offset 2D		y = a*pow(x,b)*ln(x+c) y = y * x + Offset
Simple Equation 40 With Linear Growth And Offset 2D		y = a*pow(ln(x+b),c) y = y * x + Offset
Simple Equation 41 With Linear Growth And Offset 2D		y = a*pow(x,b/x)+c*x y = y * x + Offset
Simple Equation 42 With Linear Growth And Offset 2D		y = a*pow(x,b/x)+c*ln(x) y = y * (g * x) + Offset
Simple Reciprocal With Linear Growth And Offset 2D		y = a / x y = y * x + Offset
Square Modified Transform With Linear Growth And Offset 2D		y = (bx + c)2 - a(bx + c) y = y * (g * x) + Offset
Square Modified With Linear Growth And Offset 2D		y = x2 - ax y = y * (d * x) + Offset
Transition State Rate Constant Law With Linear Growth And Offset 2D		y = axb * exp(-c/x) y = y * x + Offset
Witch Of Maria Agnesi A With Linear Growth And Offset 2D		y = 8a3 / (x2 + 4a2) y = y * (d * x) + Offset
Witch Of Maria Agnesi B With Linear Growth And Offset 2D		y = a3 / (x2 + a2) y = y * (d * x) + Offset
Witch Of Maria Agnesi C With Linear Growth And Offset 2D		y = a3 / ((x * b + c)2 + a2) y = y * (g * x) + Offset
Reciprocal Arrhenius Rate Constant Law 2D		y = a * exp(-b/x) y = 1.0 / y
Reciprocal Arrhenius Rate Constant Law Stretched 2D		y = a * exp(-pow(b/x, c)) y = 1.0 / y
Reciprocal Bleasdale-Nelder 2D		y = (a + bx)-1/c y = 1.0 / y
Reciprocal Bleasdale-Nelder Power 2D		y = (a + bxc)-1/d y = 1.0 / y
Reciprocal Catenary 2D		y = a * cosh(x / a) y = 1.0 / y   [web citation]
Reciprocal Catenary Transform 2D		y = a * cosh((bx + c) / a) y = 1.0 / y   [web citation]
Reciprocal Combined Power And Exponential 2D		y = axb * exp(cx) y = 1.0 / y
Reciprocal David Rodbard NIH 2D		y = d + (a - d) / (1.0 + (x/c)b) y = 1.0 / y   [web citation]
Reciprocal Double Langmuir Probe Characteristic 2D		y = a * tanh(bx+c) y = 1.0 / y
Reciprocal Double Rectangular Hyperbola A 2D		y = ax/(b+x) + cx/(d+x) y = 1.0 / y
Reciprocal Double Rectangular Hyperbola B 2D		y = ax/(b+x) + cx/(d+x) + fx y = 1.0 / y
Reciprocal Gunary 2D		y = x / (a + bx + cx0.5) y = 1.0 / y
Reciprocal Hyperbola A Modified 2D		y = ax/(1+bx) y = 1.0 / y
Reciprocal Hyperbola B Modified 2D		y = x/(a+bx) y = 1.0 / y
Reciprocal Hyperbolic Decay 2D		y = ab/(b+x) y = 1.0 / y
Reciprocal Lame's Cubic 2D		y = (a3 - x3)1/3 y = 1.0 / y   [web citation]
Reciprocal Lame's Cubic Transform 2D		y = (a3 - (bx + c)3)1/3 y = 1.0 / y   [web citation]
Reciprocal Miscellaneous 1 2D		y = 1.0 + a(1.0 - exp(bx)) y = 1.0 / y
Reciprocal Nelder 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = 1.0 / y
Reciprocal Pareto A 2D		y = 1 - x-a y = 1.0 / y
Reciprocal Pareto B 2D		y = a(1 - x-b) y = 1.0 / y
Reciprocal Pareto C 2D		y = 1.0 - (1.0 / (1 + ax)b y = 1.0 / y
Reciprocal Pareto D 2D		y = 1.0 - (1.0 / xa) y = 1.0 / y
Reciprocal Polytrope 2D		y = a / xb y = 1.0 / y   [web citation]
Reciprocal Polytrope Transform 2D		y = a / (cx + d)b y = 1.0 / y   [web citation]
Reciprocal Pursuit Curve 2D		y = ax2 - log(x) y = 1.0 / y
Reciprocal Pursuit Curve Transform 2D		y = a(bx + c)2 - log(bx + c) y = 1.0 / y
Reciprocal Rectangular Hyperbola A 2D		y = ax/(b+x) y = 1.0 / y
Reciprocal Rectangular Hyperbola B 2D		y = ax/(b+x) + cx y = 1.0 / y
Reciprocal Serpentine 2D		y = ax / (1.0 + bx2) y = 1.0 / y
Reciprocal Simple Equation 02 2D		y = a/pow(x,2.0) y = 1.0 / y
Reciprocal Simple Equation 03 2D		y = a*pow(ln(x),b) y = 1.0 / y
Reciprocal Simple Equation 04 2D		y = a*pow(x,3.0) y = 1.0 / y
Reciprocal Simple Equation 05 2D		y = a*pow(x,4.0) y = 1.0 / y
Reciprocal Simple Equation 06 2D		y = x/(a+b*pow(x,2.0)) y = 1.0 / y
Reciprocal Simple Equation 07 2D		y = a * pow(b,x) * pow(x,c) y = 1.0 / y
Reciprocal Simple Equation 08 2D		y = a*pow(b,1.0/x)*pow(x,c) y = 1.0 / y
Reciprocal Simple Equation 09 2D		y = a*exp(pow(x-b,2.0)/c) y = 1.0 / y
Reciprocal Simple Equation 10 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = 1.0 / y
Reciprocal Simple Equation 11 2D		y = a*pow(x,b)*pow(1.0-x,c) y = 1.0 / y
Reciprocal Simple Equation 13 2D		y = a*pow(x/b,c)*exp(x/b) y = 1.0 / y
Reciprocal Simple Equation 14 2D		y = a*pow(x,b+c*x) y = 1.0 / y
Reciprocal Simple Equation 15 2D		y = a*pow(x,b+c/x) y = 1.0 / y
Reciprocal Simple Equation 16 2D		y = a*pow(x,b+c*ln(x)) y = 1.0 / y
Reciprocal Simple Equation 17 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = 1.0 / y
Reciprocal Simple Equation 18 2D		y = a*exp(b*x+c*pow(x,0.5)) y = 1.0 / y
Reciprocal Simple Equation 19 2D		y = a*exp(b/x+c*x) y = 1.0 / y
Reciprocal Simple Equation 20 2D		y = (a+x)/(b+c*x) y = 1.0 / y
Reciprocal Simple Equation 21 2D		y = (a+x)/(b+c*pow(x,2.0)) y = 1.0 / y
Reciprocal Simple Equation 22 2D		y = a*(exp(b*x)-exp(c*x)) y = 1.0 / y
Reciprocal Simple Equation 23 2D		y = a*exp(b*exp(c*x)) y = 1.0 / y
Reciprocal Simple Equation 24 2D		y = a/(1.0 + b * exp(c*x)) y = 1.0 / y
Reciprocal Simple Equation 25 2D		y = a/(b+pow(x,c)) y = 1.0 / y
Reciprocal Simple Equation 26 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = 1.0 / y
Reciprocal Simple Equation 27 2D		y = pow(a+b*x,c) y = 1.0 / y
Reciprocal Simple Equation 28 2D		y = exp(a+b/x+c*ln(x)) y = 1.0 / y
Reciprocal Simple Equation 29 2D		y = a*exp(b*pow(x,c)) y = 1.0 / y
Reciprocal Simple Equation 30 2D		y = a*pow(x,b*pow(x,c)) y = 1.0 / y
Reciprocal Simple Equation 31 2D		y = a*ln(x+b) y = 1.0 / y
Reciprocal Simple Equation 32 2D		y = a/x+b*pow(x,c) y = 1.0 / y
Reciprocal Simple Equation 33 2D		y = a/x+b*exp(c/x) y = 1.0 / y
Reciprocal Simple Equation 34 2D		y = a/x+b*exp(c*x) y = 1.0 / y
Reciprocal Simple Equation 35 2D		y = a*exp(b*x)/x y = 1.0 / y
Reciprocal Simple Equation 36 2D		y = a*exp(b/x)/x y = 1.0 / y
Reciprocal Simple Equation 37 2D		y = a*pow(x,b)*ln(x) y = 1.0 / y
Reciprocal Simple Equation 38 2D		y = a*pow(x,b)/ln(x) y = 1.0 / y
Reciprocal Simple Equation 39 2D		y = a*pow(x,b)*ln(x+c) y = 1.0 / y
Reciprocal Simple Equation 40 2D		y = a*pow(ln(x+b),c) y = 1.0 / y
Reciprocal Simple Equation 41 2D		y = a*pow(x,b/x)+c*x y = 1.0 / y
Reciprocal Simple Equation 42 2D		y = a*pow(x,b/x)+c*ln(x) y = 1.0 / y
Reciprocal Square Modified 2D		y = x2 - ax y = 1.0 / y
Reciprocal Square Modified Transform 2D		y = (bx + c)2 - a(bx + c) y = 1.0 / y
Reciprocal Transition State Rate Constant Law 2D		y = axb * exp(-c/x) y = 1.0 / y
Reciprocal Witch Of Maria Agnesi A 2D		y = 8a3 / (x2 + 4a2) y = 1.0 / y
Reciprocal Witch Of Maria Agnesi B 2D		y = a3 / (x2 + a2) y = 1.0 / y
Reciprocal Witch Of Maria Agnesi C 2D		y = a3 / ((x * b + c)2 + a2) y = 1.0 / y
Reciprocal Arrhenius Rate Constant Law Stretched With Offset 2D		y = a * exp(-pow(b/x, c)) y = 1.0 / y + Offset
Reciprocal Arrhenius Rate Constant Law With Offset 2D		y = a * exp(-b/x) y = 1.0 / y + Offset
Reciprocal Bleasdale-Nelder Power With Offset 2D		y = (a + bxc)-1/d y = 1.0 / y + Offset
Reciprocal Bleasdale-Nelder With Offset 2D		y = (a + bx)-1/c y = 1.0 / y + Offset
Reciprocal Catenary Transform With Offset 2D		y = a * cosh((bx + c) / a) y = 1.0 / y + Offset   [web citation]
Reciprocal Catenary With Offset 2D		y = a * cosh(x / a) y = 1.0 / y + Offset   [web citation]
Reciprocal Combined Power And Exponential With Offset 2D		y = axb * exp(cx) y = 1.0 / y + Offset
Reciprocal Double Langmuir Probe Characteristic With Offset 2D		y = a * tanh(bx+c) y = 1.0 / y + Offset
Reciprocal Double Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) + cx/(d+x) y = 1.0 / y + Offset
Reciprocal Double Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx/(d+x) + fx y = 1.0 / y + Offset
Reciprocal Gunary With Offset 2D		y = x / (a + bx + cx0.5) y = 1.0 / y + Offset
Reciprocal Hyperbola A Modified With Offset 2D		y = ax/(1+bx) y = 1.0 / y + Offset
Reciprocal Hyperbola B Modified With Offset 2D		y = x/(a+bx) y = 1.0 / y + Offset
Reciprocal Hyperbolic Decay With Offset 2D		y = ab/(b+x) y = 1.0 / y + Offset
Reciprocal Lame's Cubic Transform With Offset 2D		y = (a3 - (bx + c)3)1/3 y = 1.0 / y + Offset   [web citation]
Reciprocal Lame's Cubic With Offset 2D		y = (a3 - x3)1/3 y = 1.0 / y + Offset   [web citation]
Reciprocal Miscellaneous 1 With Offset 2D		y = 1.0 + a(1.0 - exp(bx)) y = 1.0 / y + Offset
Reciprocal Nelder With Offset 2D		y = (a + x) / (b + c(a + x) + d(a + x)2 y = 1.0 / y + Offset
Reciprocal Pareto A With Offset 2D		y = 1 - x-a y = 1.0 / y + Offset
Reciprocal Pareto B With Offset 2D		y = a(1 - x-b) y = 1.0 / y + Offset
Reciprocal Pareto C With Offset 2D		y = 1.0 - (1.0 / (1 + ax)b y = 1.0 / y + Offset
Reciprocal Pareto D With Offset 2D		y = 1.0 - (1.0 / xa) y = 1.0 / y + Offset
Reciprocal Polytrope Transform With Offset 2D		y = a / (cx + d)b y = 1.0 / y + Offset   [web citation]
Reciprocal Polytrope With Offset 2D		y = a / xb y = 1.0 / y + Offset   [web citation]
Reciprocal Pursuit Curve Transform With Offset 2D		y = a(bx + c)2 - log(bx + c) y = 1.0 / y + Offset
Reciprocal Pursuit Curve With Offset 2D		y = ax2 - log(x) y = 1.0 / y + Offset
Reciprocal Rectangular Hyperbola A With Offset 2D		y = ax/(b+x) y = 1.0 / y + Offset
Reciprocal Rectangular Hyperbola B With Offset 2D		y = ax/(b+x) + cx y = 1.0 / y + Offset
Reciprocal Serpentine With Offset 2D		y = ax / (1.0 + bx2) y = 1.0 / y + Offset
Reciprocal Simple Equation 02 With Offset 2D		y = a/pow(x,2.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 03 With Offset 2D		y = a*pow(ln(x),b) y = 1.0 / y + Offset
Reciprocal Simple Equation 04 With Offset 2D		y = a*pow(x,3.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 05 With Offset 2D		y = a*pow(x,4.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 06 With Offset 2D		y = x/(a+b*pow(x,2.0)) y = 1.0 / y + Offset
Reciprocal Simple Equation 07 With Offset 2D		y = a * pow(b,x) * pow(x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 08 With Offset 2D		y = a*pow(b,1.0/x)*pow(x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 09 With Offset 2D		y = a*exp(pow(x-b,2.0)/c) y = 1.0 / y + Offset
Reciprocal Simple Equation 10 With Offset 2D		y = a*exp(pow(ln(x)-b,2.0)/c) y = 1.0 / y + Offset
Reciprocal Simple Equation 11 With Offset 2D		y = a*pow(x,b)*pow(1.0-x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 13 With Offset 2D		y = a*pow(x/b,c)*exp(x/b) y = 1.0 / y + Offset
Reciprocal Simple Equation 14 With Offset 2D		y = a*pow(x,b+c*x) y = 1.0 / y + Offset
Reciprocal Simple Equation 15 With Offset 2D		y = a*pow(x,b+c/x) y = 1.0 / y + Offset
Reciprocal Simple Equation 16 With Offset 2D		y = a*pow(x,b+c*ln(x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 17 With Offset 2D		y = a*pow(x,b*x+c*pow(x,2.0)) y = 1.0 / y + Offset
Reciprocal Simple Equation 18 With Offset 2D		y = a*exp(b*x+c*pow(x,0.5)) y = 1.0 / y + Offset
Reciprocal Simple Equation 19 With Offset 2D		y = a*exp(b/x+c*x) y = 1.0 / y + Offset
Reciprocal Simple Equation 20 With Offset 2D		y = (a+x)/(b+c*x) y = 1.0 / y + Offset
Reciprocal Simple Equation 21 With Offset 2D		y = (a+x)/(b+c*pow(x,2.0)) y = 1.0 / y + Offset
Reciprocal Simple Equation 22 With Offset 2D		y = a*(exp(b*x)-exp(c*x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 23 With Offset 2D		y = a*exp(b*exp(c*x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 24 With Offset 2D		y = a/(1.0 + b * exp(c*x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 25 With Offset 2D		y = a/(b+pow(x,c)) y = 1.0 / y + Offset
Reciprocal Simple Equation 26 With Offset 2D		y = a/pow(1.0 + b * pow(x,c),2.0) y = 1.0 / y + Offset
Reciprocal Simple Equation 27 With Offset 2D		y = pow(a+b*x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 28 With Offset 2D		y = exp(a+b/x+c*ln(x)) y = 1.0 / y + Offset
Reciprocal Simple Equation 29 With Offset 2D		y = a*exp(b*pow(x,c)) y = 1.0 / y + Offset
Reciprocal Simple Equation 30 With Offset 2D		y = a*pow(x,b*pow(x,c)) y = 1.0 / y + Offset
Reciprocal Simple Equation 31 With Offset 2D		y = a*ln(x+b) y = 1.0 / y + Offset
Reciprocal Simple Equation 32 With Offset 2D		y = a/x+b*pow(x,c) y = 1.0 / y + Offset
Reciprocal Simple Equation 33 With Offset 2D		y = a/x+b*exp(c/x) y = 1.0 / y + Offset
Reciprocal Simple Equation 34 With Offset 2D		y = a/x+b*exp(c*x) y = 1.0 / y + Offset
Reciprocal Simple Equation 35 With Offset 2D		y = a*exp(b*x)/x y = 1.0 / y + Offset
Reciprocal Simple Equation 36 With Offset 2D		y = a*exp(b/x)/x y = 1.0 / y + Offset
Reciprocal Simple Equation 37 With Offset 2D		y = a*pow(x,b)*ln(x) y = 1.0 / y + Offset
Reciprocal Simple Equation 38 With Offset 2D		y = a*pow(x,b)/ln(x) y = 1.0 / y + Offset
Reciprocal Simple Equation 39 With Offset 2D		y = a*pow(x,b)*ln(x+c) y = 1.0 / y + Offset
Reciprocal Simple Equation 40 With Offset 2D		y = a*pow(ln(x+b),c) y = 1.0 / y + Offset
Reciprocal Simple Equation 41 With Offset 2D		y = a*pow(x,b/x)+c*x y = 1.0 / y + Offset
Reciprocal Simple Equation 42 With Offset 2D		y = a*pow(x,b/x)+c*ln(x) y = 1.0 / y + Offset
Reciprocal Square Modified Transform With Offset 2D		y = (bx + c)2 - a(bx + c) y = 1.0 / y + Offset
Reciprocal Square Modified With Offset 2D		y = x2 - ax y = 1.0 / y + Offset
Reciprocal Transition State Rate Constant Law With Offset 2D		y = axb * exp(-c/x) y = 1.0 / y + Offset
Reciprocal Witch Of Maria Agnesi A With Offset 2D		y = 8a3 / (x2 + 4a2) y = 1.0 / y + Offset
Reciprocal Witch Of Maria Agnesi B With Offset 2D		y = a3 / (x2 + a2) y = 1.0 / y + Offset
Reciprocal Witch Of Maria Agnesi C With Offset 2D		y = a3 / ((x * b + c)2 + a2) y = 1.0 / y + Offset

2D NIST

NIST Bennett5 2D		y = a * (b+x)-1/c   [web citation]
NIST BoxBOD 2D		y = a * (1.0-exp(-b*x))   [web citation]
NIST Chwirut 2D		y = exp(-a*x) / (b + c*x)   [web citation]
NIST DanWood 2D		y = a*xb   [web citation]
NIST ENSO 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h)   [web citation]
NIST Eckerle4 2D		y = (a/b) * exp(-0.5*((x-c)/b)2)   [web citation]
NIST Gauss 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2)   [web citation]
NIST Hahn 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3)   [web citation]
NIST Kirby 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2)   [web citation]
NIST Lanczos 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x)   [web citation]
NIST MGH09 2D		y = a * (x2 + b*x) / (x2 + c*x + d)   [web citation]
NIST MGH10 2D		y = a * exp(b/(x+c))   [web citation]
NIST MGH17 2D		y = a + b*exp(-x*d) + c*exp(-x*f)   [web citation]
NIST Misra1a 2D		y = a * (1.0 - exp(-b*x))   [web citation]
NIST Misra1b 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0)   [web citation]
NIST Misra1c 2D		y = a * (1.0 - 2.0*b*x)-0.5   [web citation]
NIST Misra1d 2D		y = a * b * x * (1.0 + b*x)-1.0   [web citation]
NIST Rat42 2D		y = a / (1.0 + exp(b - c*x))   [web citation]
NIST Rat43 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d))   [web citation]
NIST Roszman 2D		y = a - bx - (arctan(c/(x-d)) / pi)   [web citation]
NIST Thurber 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3)   [web citation]
NIST Bennett5 With Offset 2D		y = a * (b+x)-1/c + Offset   [web citation]
NIST BoxBOD With Offset 2D		y = a * (1.0-exp(-b*x)) + Offset   [web citation]
NIST Chwirut With Offset 2D		y = exp(-a*x) / (b + c*x) + Offset   [web citation]
NIST DanWood With Offset 2D		y = a*xb + Offset   [web citation]
NIST Eckerle4 With Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) + Offset   [web citation]
NIST Gauss With Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) + Offset   [web citation]
NIST Hahn With Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) + Offset   [web citation]
NIST Kirby With Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) + Offset   [web citation]
NIST Lanczos With Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) + Offset   [web citation]
NIST MGH09 With Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) + Offset   [web citation]
NIST MGH10 With Offset 2D		y = a * exp(b/(x+c)) + Offset   [web citation]
NIST Misra1a With Offset 2D		y = a * (1.0 - exp(-b*x)) + Offset   [web citation]
NIST Misra1b With Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) + Offset   [web citation]
NIST Misra1c With Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 + Offset   [web citation]
NIST Misra1d With Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 + Offset   [web citation]
NIST Rat42 With Offset 2D		y = a / (1.0 + exp(b - c*x)) + Offset   [web citation]
NIST Rat43 With Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) + Offset   [web citation]
NIST Thurber With Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) + Offset   [web citation]
NIST Bennett5 With Exponential Decay 2D		y = a * (b+x)-1/c y = y / exp(x)   [web citation]
NIST BoxBOD With Exponential Decay 2D		y = a * (1.0-exp(-b*x)) y = y / exp(x)   [web citation]
NIST Chwirut With Exponential Decay 2D		y = exp(-a*x) / (b + c*x) y = y / (f * exp(x))   [web citation]
NIST DanWood With Exponential Decay 2D		y = a*xb y = y / exp(x)   [web citation]
NIST ENSO With Exponential Decay 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h) y = y / (m * exp(x))   [web citation]
NIST Eckerle4 With Exponential Decay 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y / exp(x)   [web citation]
NIST Gauss With Exponential Decay 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y / (k * exp(x))   [web citation]
NIST Hahn With Exponential Decay 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y / (j * exp(x))   [web citation]
NIST Kirby With Exponential Decay 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y / (h * exp(x))   [web citation]
NIST Lanczos With Exponential Decay 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y / (i * exp(x))   [web citation]
NIST MGH09 With Exponential Decay 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y / exp(x)   [web citation]
NIST MGH10 With Exponential Decay 2D		y = a * exp(b/(x+c)) y = y / exp(x)   [web citation]
NIST MGH17 With Exponential Decay 2D		y = a + b*exp(-x*d) + c*exp(-x*f) y = y / (h * exp(x))   [web citation]
NIST Misra1a With Exponential Decay 2D		y = a * (1.0 - exp(-b*x)) y = y / exp(x)   [web citation]
NIST Misra1b With Exponential Decay 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y / exp(x)   [web citation]
NIST Misra1c With Exponential Decay 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y / exp(x)   [web citation]
NIST Misra1d With Exponential Decay 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y / exp(x)   [web citation]
NIST Rat42 With Exponential Decay 2D		y = a / (1.0 + exp(b - c*x)) y = y / exp(x)   [web citation]
NIST Rat43 With Exponential Decay 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y / exp(x)   [web citation]
NIST Roszman With Exponential Decay 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y / (g * exp(x))   [web citation]
NIST Thurber With Exponential Decay 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y / (j * exp(x))   [web citation]
NIST Bennett5 With Exponential Decay And Offset 2D		y = a * (b+x)-1/c y = y / exp(x) + Offset   [web citation]
NIST BoxBOD With Exponential Decay And Offset 2D		y = a * (1.0-exp(-b*x)) y = y / exp(x) + Offset   [web citation]
NIST Chwirut With Exponential Decay And Offset 2D		y = exp(-a*x) / (b + c*x) y = y / (g * exp(x)) + Offset   [web citation]
NIST DanWood With Exponential Decay And Offset 2D		y = a*xb y = y / exp(x) + Offset   [web citation]
NIST Eckerle4 With Exponential Decay And Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y / exp(x) + Offset   [web citation]
NIST Gauss With Exponential Decay And Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y / (m * exp(x)) + Offset   [web citation]
NIST Hahn With Exponential Decay And Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y / (k * exp(x)) + Offset   [web citation]
NIST Kirby With Exponential Decay And Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y / (i * exp(x)) + Offset   [web citation]
NIST Lanczos With Exponential Decay And Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y / (j * exp(x)) + Offset   [web citation]
NIST MGH09 With Exponential Decay And Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y / exp(x) + Offset   [web citation]
NIST MGH10 With Exponential Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / exp(x) + Offset   [web citation]
NIST Misra1a With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-b*x)) y = y / exp(x) + Offset   [web citation]
NIST Misra1b With Exponential Decay And Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y / exp(x) + Offset   [web citation]
NIST Misra1c With Exponential Decay And Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y / exp(x) + Offset   [web citation]
NIST Misra1d With Exponential Decay And Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y / exp(x) + Offset   [web citation]
NIST Rat42 With Exponential Decay And Offset 2D		y = a / (1.0 + exp(b - c*x)) y = y / exp(x) + Offset   [web citation]
NIST Rat43 With Exponential Decay And Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y / exp(x) + Offset   [web citation]
NIST Thurber With Exponential Decay And Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y / (k * exp(x)) + Offset   [web citation]
NIST Bennett5 With Exponential Growth 2D		y = a * (b+x)-1/c y = y * exp(x)   [web citation]
NIST BoxBOD With Exponential Growth 2D		y = a * (1.0-exp(-b*x)) y = y * exp(x)   [web citation]
NIST Chwirut With Exponential Growth 2D		y = exp(-a*x) / (b + c*x) y = y * (f * exp(x))   [web citation]
NIST DanWood With Exponential Growth 2D		y = a*xb y = y * exp(x)   [web citation]
NIST ENSO With Exponential Growth 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h) y = y * (m * exp(x))   [web citation]
NIST Eckerle4 With Exponential Growth 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y * exp(x)   [web citation]
NIST Gauss With Exponential Growth 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y * (k * exp(x))   [web citation]
NIST Hahn With Exponential Growth 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y * (j * exp(x))   [web citation]
NIST Kirby With Exponential Growth 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y * (h * exp(x))   [web citation]
NIST Lanczos With Exponential Growth 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y * (i * exp(x))   [web citation]
NIST MGH09 With Exponential Growth 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y * exp(x)   [web citation]
NIST MGH10 With Exponential Growth 2D		y = a * exp(b/(x+c)) y = y * exp(x)   [web citation]
NIST MGH17 With Exponential Growth 2D		y = a + b*exp(-x*d) + c*exp(-x*f) y = y * (h * exp(x))   [web citation]
NIST Misra1a With Exponential Growth 2D		y = a * (1.0 - exp(-b*x)) y = y * exp(x)   [web citation]
NIST Misra1b With Exponential Growth 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y * exp(x)   [web citation]
NIST Misra1c With Exponential Growth 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y * exp(x)   [web citation]
NIST Misra1d With Exponential Growth 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y * exp(x)   [web citation]
NIST Rat42 With Exponential Growth 2D		y = a / (1.0 + exp(b - c*x)) y = y * exp(x)   [web citation]
NIST Rat43 With Exponential Growth 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y * exp(x)   [web citation]
NIST Roszman With Exponential Growth 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y * (g * exp(x))   [web citation]
NIST Thurber With Exponential Growth 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y * (j * exp(x))   [web citation]
NIST Bennett5 With Exponential Growth And Offset 2D		y = a * (b+x)-1/c y = y * exp(x) + Offset   [web citation]
NIST BoxBOD With Exponential Growth And Offset 2D		y = a * (1.0-exp(-b*x)) y = y * exp(x) + Offset   [web citation]
NIST Chwirut With Exponential Growth And Offset 2D		y = exp(-a*x) / (b + c*x) y = y * (g * exp(x)) + Offset   [web citation]
NIST DanWood With Exponential Growth And Offset 2D		y = a*xb y = y * exp(x) + Offset   [web citation]
NIST Eckerle4 With Exponential Growth And Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y * exp(x) + Offset   [web citation]
NIST Gauss With Exponential Growth And Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y * (m * exp(x)) + Offset   [web citation]
NIST Hahn With Exponential Growth And Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y * (k * exp(x)) + Offset   [web citation]
NIST Kirby With Exponential Growth And Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y * (i * exp(x)) + Offset   [web citation]
NIST Lanczos With Exponential Growth And Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y * (j * exp(x)) + Offset   [web citation]
NIST MGH09 With Exponential Growth And Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y * exp(x) + Offset   [web citation]
NIST MGH10 With Exponential Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * exp(x) + Offset   [web citation]
NIST Misra1a With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-b*x)) y = y * exp(x) + Offset   [web citation]
NIST Misra1b With Exponential Growth And Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y * exp(x) + Offset   [web citation]
NIST Misra1c With Exponential Growth And Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y * exp(x) + Offset   [web citation]
NIST Misra1d With Exponential Growth And Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y * exp(x) + Offset   [web citation]
NIST Rat42 With Exponential Growth And Offset 2D		y = a / (1.0 + exp(b - c*x)) y = y * exp(x) + Offset   [web citation]
NIST Rat43 With Exponential Growth And Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y * exp(x) + Offset   [web citation]
NIST Thurber With Exponential Growth And Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y * (k * exp(x)) + Offset   [web citation]
Inverse NIST Bennett5 2D		y = a * (b+x)-1/c y = x / y   [web citation]
Inverse NIST BoxBOD 2D		y = a * (1.0-exp(-b*x)) y = x / y   [web citation]
Inverse NIST Chwirut 2D		y = exp(-a*x) / (b + c*x) y = x / y   [web citation]
Inverse NIST DanWood 2D		y = a*xb y = x / y   [web citation]
Inverse NIST ENSO 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h) y = x / y   [web citation]
Inverse NIST Eckerle4 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = x / y   [web citation]
Inverse NIST Gauss 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = x / y   [web citation]
Inverse NIST Hahn 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = x / y   [web citation]
Inverse NIST Kirby 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = x / y   [web citation]
Inverse NIST Lanczos 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = x / y   [web citation]
Inverse NIST MGH09 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = x / y   [web citation]
Inverse NIST MGH10 2D		y = a * exp(b/(x+c)) y = x / y   [web citation]
Inverse NIST MGH17 2D		y = a + b*exp(-x*d) + c*exp(-x*f) y = x / y   [web citation]
Inverse NIST Misra1a 2D		y = a * (1.0 - exp(-b*x)) y = x / y   [web citation]
Inverse NIST Misra1b 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = x / y   [web citation]
Inverse NIST Misra1c 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = x / y   [web citation]
Inverse NIST Misra1d 2D		y = a * b * x * (1.0 + b*x)-1.0 y = x / y   [web citation]
Inverse NIST Rat42 2D		y = a / (1.0 + exp(b - c*x)) y = x / y   [web citation]
Inverse NIST Rat43 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = x / y   [web citation]
Inverse NIST Roszman 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = x / y   [web citation]
Inverse NIST Thurber 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = x / y   [web citation]
Inverse NIST Bennett5 With Offset 2D		y = a * (b+x)-1/c y = x / y + Offset   [web citation]
Inverse NIST BoxBOD With Offset 2D		y = a * (1.0-exp(-b*x)) y = x / y + Offset   [web citation]
Inverse NIST Chwirut With Offset 2D		y = exp(-a*x) / (b + c*x) y = x / y + Offset   [web citation]
Inverse NIST DanWood With Offset 2D		y = a*xb y = x / y + Offset   [web citation]
Inverse NIST Eckerle4 With Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = x / y + Offset   [web citation]
Inverse NIST Gauss With Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = x / y + Offset   [web citation]
Inverse NIST Hahn With Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = x / y + Offset   [web citation]
Inverse NIST Kirby With Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = x / y + Offset   [web citation]
Inverse NIST Lanczos With Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = x / y + Offset   [web citation]
Inverse NIST MGH09 With Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = x / y + Offset   [web citation]
Inverse NIST MGH10 With Offset 2D		y = a * exp(b/(x+c)) y = x / y + Offset   [web citation]
Inverse NIST Misra1a With Offset 2D		y = a * (1.0 - exp(-b*x)) y = x / y + Offset   [web citation]
Inverse NIST Misra1b With Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = x / y + Offset   [web citation]
Inverse NIST Misra1c With Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = x / y + Offset   [web citation]
Inverse NIST Misra1d With Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 y = x / y + Offset   [web citation]
Inverse NIST Rat42 With Offset 2D		y = a / (1.0 + exp(b - c*x)) y = x / y + Offset   [web citation]
Inverse NIST Rat43 With Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = x / y + Offset   [web citation]
Inverse NIST Thurber With Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = x / y + Offset   [web citation]
NIST Bennett5 With Linear Decay 2D		y = a * (b+x)-1/c y = y / x   [web citation]
NIST BoxBOD With Linear Decay 2D		y = a * (1.0-exp(-b*x)) y = y / x   [web citation]
NIST Chwirut With Linear Decay 2D		y = exp(-a*x) / (b + c*x) y = y / (f * x)   [web citation]
NIST DanWood With Linear Decay 2D		y = a*xb y = y / x   [web citation]
NIST ENSO With Linear Decay 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h) y = y / (m * x)   [web citation]
NIST Eckerle4 With Linear Decay 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y / x   [web citation]
NIST Gauss With Linear Decay 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y / (k * x)   [web citation]
NIST Hahn With Linear Decay 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y / (j * x)   [web citation]
NIST Kirby With Linear Decay 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y / (h * x)   [web citation]
NIST Lanczos With Linear Decay 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y / (i * x)   [web citation]
NIST MGH09 With Linear Decay 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y / x   [web citation]
NIST MGH10 With Linear Decay 2D		y = a * exp(b/(x+c)) y = y / x   [web citation]
NIST MGH17 With Linear Decay 2D		y = a + b*exp(-x*d) + c*exp(-x*f) y = y / (h * x)   [web citation]
NIST Misra1a With Linear Decay 2D		y = a * (1.0 - exp(-b*x)) y = y / x   [web citation]
NIST Misra1b With Linear Decay 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y / x   [web citation]
NIST Misra1c With Linear Decay 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y / x   [web citation]
NIST Misra1d With Linear Decay 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y / x   [web citation]
NIST Rat42 With Linear Decay 2D		y = a / (1.0 + exp(b - c*x)) y = y / x   [web citation]
NIST Rat43 With Linear Decay 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y / x   [web citation]
NIST Roszman With Linear Decay 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y / (g * x)   [web citation]
NIST Thurber With Linear Decay 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y / (j * x)   [web citation]
NIST Bennett5 With Linear Decay And Offset 2D		y = a * (b+x)-1/c y = y / x + Offset   [web citation]
NIST BoxBOD With Linear Decay And Offset 2D		y = a * (1.0-exp(-b*x)) y = y / x + Offset   [web citation]
NIST Chwirut With Linear Decay And Offset 2D		y = exp(-a*x) / (b + c*x) y = y / (g * x) + Offset   [web citation]
NIST DanWood With Linear Decay And Offset 2D		y = a*xb y = y / x + Offset   [web citation]
NIST Eckerle4 With Linear Decay And Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y / x + Offset   [web citation]
NIST Gauss With Linear Decay And Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y / (m * x) + Offset   [web citation]
NIST Hahn With Linear Decay And Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y / (k * x) + Offset   [web citation]
NIST Kirby With Linear Decay And Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y / (i * x) + Offset   [web citation]
NIST Lanczos With Linear Decay And Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y / (j * x) + Offset   [web citation]
NIST MGH09 With Linear Decay And Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y / x + Offset   [web citation]
NIST MGH10 With Linear Decay And Offset 2D		y = a * exp(b/(x+c)) y = y / x + Offset   [web citation]
NIST Misra1a With Linear Decay And Offset 2D		y = a * (1.0 - exp(-b*x)) y = y / x + Offset   [web citation]
NIST Misra1b With Linear Decay And Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y / x + Offset   [web citation]
NIST Misra1c With Linear Decay And Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y / x + Offset   [web citation]
NIST Misra1d With Linear Decay And Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y / x + Offset   [web citation]
NIST Rat42 With Linear Decay And Offset 2D		y = a / (1.0 + exp(b - c*x)) y = y / x + Offset   [web citation]
NIST Rat43 With Linear Decay And Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y / x + Offset   [web citation]
NIST Thurber With Linear Decay And Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y / (k * x) + Offset   [web citation]
NIST Bennett5 With Linear Growth 2D		y = a * (b+x)-1/c y = y * x   [web citation]
NIST BoxBOD With Linear Growth 2D		y = a * (1.0-exp(-b*x)) y = y * x   [web citation]
NIST Chwirut With Linear Growth 2D		y = exp(-a*x) / (b + c*x) y = y * (f * x) + Offset   [web citation]
NIST DanWood With Linear Growth 2D		y = a*xb y = y * x   [web citation]
NIST ENSO With Linear Growth 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h) y = y * (m * x) + Offset   [web citation]
NIST Eckerle4 With Linear Growth 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y * x   [web citation]
NIST Gauss With Linear Growth 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y * (k * x) + Offset   [web citation]
NIST Hahn With Linear Growth 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y * (j * x) + Offset   [web citation]
NIST Kirby With Linear Growth 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y * (h * x) + Offset   [web citation]
NIST Lanczos With Linear Growth 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y * (i * x) + Offset   [web citation]
NIST MGH09 With Linear Growth 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y * x   [web citation]
NIST MGH10 With Linear Growth 2D		y = a * exp(b/(x+c)) y = y * x   [web citation]
NIST MGH17 With Linear Growth 2D		y = a + b*exp(-x*d) + c*exp(-x*f) y = y * (h * x) + Offset   [web citation]
NIST Misra1a With Linear Growth 2D		y = a * (1.0 - exp(-b*x)) y = y * x   [web citation]
NIST Misra1b With Linear Growth 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y * x   [web citation]
NIST Misra1c With Linear Growth 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y * x   [web citation]
NIST Misra1d With Linear Growth 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y * x   [web citation]
NIST Rat42 With Linear Growth 2D		y = a / (1.0 + exp(b - c*x)) y = y * x   [web citation]
NIST Rat43 With Linear Growth 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y * x   [web citation]
NIST Roszman With Linear Growth 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = y * (g * x) + Offset   [web citation]
NIST Thurber With Linear Growth 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y * (j * x) + Offset   [web citation]
NIST Bennett5 With Linear Growth And Offset 2D		y = a * (b+x)-1/c y = y * x + Offset   [web citation]
NIST BoxBOD With Linear Growth And Offset 2D		y = a * (1.0-exp(-b*x)) y = y * x + Offset   [web citation]
NIST Chwirut With Linear Growth And Offset 2D		y = exp(-a*x) / (b + c*x) y = y * (g * x) + Offset   [web citation]
NIST DanWood With Linear Growth And Offset 2D		y = a*xb y = y * x + Offset   [web citation]
NIST Eckerle4 With Linear Growth And Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = y * x + Offset   [web citation]
NIST Gauss With Linear Growth And Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = y * (m * x) + Offset   [web citation]
NIST Hahn With Linear Growth And Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = y * (k * x) + Offset   [web citation]
NIST Kirby With Linear Growth And Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = y * (i * x) + Offset   [web citation]
NIST Lanczos With Linear Growth And Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = y * (j * x) + Offset   [web citation]
NIST MGH09 With Linear Growth And Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = y * x + Offset   [web citation]
NIST MGH10 With Linear Growth And Offset 2D		y = a * exp(b/(x+c)) y = y * x + Offset   [web citation]
NIST Misra1a With Linear Growth And Offset 2D		y = a * (1.0 - exp(-b*x)) y = y * x + Offset   [web citation]
NIST Misra1b With Linear Growth And Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = y * x + Offset   [web citation]
NIST Misra1c With Linear Growth And Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = y * x + Offset   [web citation]
NIST Misra1d With Linear Growth And Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 y = y * x + Offset   [web citation]
NIST Rat42 With Linear Growth And Offset 2D		y = a / (1.0 + exp(b - c*x)) y = y * x + Offset   [web citation]
NIST Rat43 With Linear Growth And Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = y * x + Offset   [web citation]
NIST Thurber With Linear Growth And Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = y * (k * x) + Offset   [web citation]
Reciprocal NIST Bennett5 2D		y = a * (b+x)-1/c y = 1.0 / y   [web citation]
Reciprocal NIST BoxBOD 2D		y = a * (1.0-exp(-b*x)) y = 1.0 / y   [web citation]
Reciprocal NIST Chwirut 2D		y = exp(-a*x) / (b + c*x) y = 1.0 / y   [web citation]
Reciprocal NIST DanWood 2D		y = a*xb y = 1.0 / y   [web citation]
Reciprocal NIST ENSO 2D		y = a + b*cos(2*pi*x/12) + c*sin(2*pi*x/12) + f*cos(2*pi*x/d) + g*sin(2*pi*x/d) + i*cos(2*pi*x/h) + j*sin(2*pi*x/h) y = 1.0 / y   [web citation]
Reciprocal NIST Eckerle4 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = 1.0 / y   [web citation]
Reciprocal NIST Gauss 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = 1.0 / y   [web citation]
Reciprocal NIST Hahn 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = 1.0 / y   [web citation]
Reciprocal NIST Kirby 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = 1.0 / y   [web citation]
Reciprocal NIST Lanczos 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = 1.0 / y   [web citation]
Reciprocal NIST MGH09 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = 1.0 / y   [web citation]
Reciprocal NIST MGH10 2D		y = a * exp(b/(x+c)) y = 1.0 / y   [web citation]
Reciprocal NIST MGH17 2D		y = a + b*exp(-x*d) + c*exp(-x*f) y = 1.0 / y   [web citation]
Reciprocal NIST Misra1a 2D		y = a * (1.0 - exp(-b*x)) y = 1.0 / y   [web citation]
Reciprocal NIST Misra1b 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = 1.0 / y   [web citation]
Reciprocal NIST Misra1c 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = 1.0 / y   [web citation]
Reciprocal NIST Misra1d 2D		y = a * b * x * (1.0 + b*x)-1.0 y = 1.0 / y   [web citation]
Reciprocal NIST Rat42 2D		y = a / (1.0 + exp(b - c*x)) y = 1.0 / y   [web citation]
Reciprocal NIST Rat43 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = 1.0 / y   [web citation]
Reciprocal NIST Roszman 2D		y = a - bx - (arctan(c/(x-d)) / pi) y = 1.0 / y   [web citation]
Reciprocal NIST Thurber 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = 1.0 / y   [web citation]
Reciprocal NIST Bennett5 With Offset 2D		y = a * (b+x)-1/c y = 1.0 / y + Offset   [web citation]
Reciprocal NIST BoxBOD With Offset 2D		y = a * (1.0-exp(-b*x)) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Chwirut With Offset 2D		y = exp(-a*x) / (b + c*x) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST DanWood With Offset 2D		y = a*xb y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Eckerle4 With Offset 2D		y = (a/b) * exp(-0.5*((x-c)/b)2) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Gauss With Offset 2D		y = a*exp(-b*x) + c*exp(-(x-d)2 / f2) + g*exp(-(x-h)2 / i2) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Hahn With Offset 2D		y = (a + b*x + c*x2 + d*x3) / (1.0 + f*x + g*x2 + h*x3) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Kirby With Offset 2D		y = (a + b*x + c*x2) / (1.0 + d*x + f*x2) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Lanczos With Offset 2D		y = a*exp(-b*x) + c*exp(-d*x) + f*exp(-g*x) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST MGH09 With Offset 2D		y = a * (x2 + b*x) / (x2 + c*x + d) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST MGH10 With Offset 2D		y = a * exp(b/(x+c)) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Misra1a With Offset 2D		y = a * (1.0 - exp(-b*x)) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Misra1b With Offset 2D		y = a * (1.0 - (1.0+b*x/2.0)-2.0) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Misra1c With Offset 2D		y = a * (1.0 - 2.0*b*x)-0.5 y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Misra1d With Offset 2D		y = a * b * x * (1.0 + b*x)-1.0 y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Rat42 With Offset 2D		y = a / (1.0 + exp(b - c*x)) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Rat43 With Offset 2D		y = a / ((1.0 + exp(b - c*x))(1.0/d)) y = 1.0 / y + Offset   [web citation]
Reciprocal NIST Thurber With Offset 2D		y = (a + bx + cx2 + dx3) / (1.0 + fx + gx2 + hx3) y = 1.0 / y + Offset   [web citation]

2D Optical

CAUCHY 2D		n = A + B/x2 + C/x4   [web citation]
CONRADY1 2D		n = A + B/x + C/x3.5   [web citation]
CONRADY2 2D		n = A + B/x2 + C/x3.5   [web citation]
HARTMANN1 2D		n = A + B/(C - x)   [web citation]
HARTMANN2 2D		n = A + B/(C - x)2   [web citation]
HARTMANN3a 2D		n = A + B/(C - x)1.2   [web citation]
HARTMANN3b 2D		n = A/(x - B)1.2   [web citation]
HARTMANN4 2D		n = A + B/(C - x) + D/(E - x)   [web citation]
HERZBRGR2X2 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2   [web citation]
HERZBRGR3X2 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2   [web citation]
HERZBRGR3X3 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4   [web citation]
HERZBRGR4X2 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2   [web citation]
HERZBRGR5X2 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2   [web citation]
HERZBRGRJK 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2   [web citation]
HoO1 2D		n2 = A + Bx2 + C / (x2 - D2)   [web citation]
HoO2 2D		n2 = A + Bx2 + Cx2 / (x2 - D2)   [web citation]
KINGSLAKE1 2D		n2 = A + B/(x2-C2) + D/(x2-E2)   [web citation]
KINGSLAKE2 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2)   [web citation]
MISC01 2D		n2 = A + B/(x2-C2)   [web citation]
MISC02 2D		n2 = A + Bx2 + C/(x2-D2)   [web citation]
MISC03 2D		n2 = A + B/x2 + Cx2/(x2-D2)   [web citation]
MISC04 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F)))   [web citation]
SCHOTT2X3 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6   [web citation]
SCHOTT2X4 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8   [web citation]
SCHOTT2X5 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10   [web citation]
SCHOTT2X6 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12   [web citation]
SCHOTT3X3 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6   [web citation]
SCHOTT3X4 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8   [web citation]
SCHOTT3X5 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10   [web citation]
SCHOTT4X4 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8   [web citation]
SCHOTT5X5 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10   [web citation]
SELL1T 2D		n2 = 1 + Ax2 / (x2 - B2)   [web citation]
SELL1TA 2D		n2 = A + Bx2 / (x2 - C2)   [web citation]
SELL2T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2)   [web citation]
SELL2TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2)   [web citation]
SELL3T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2)   [web citation]
SELL3TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2)   [web citation]
SELL4T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2)   [web citation]
SELL4TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2)   [web citation]
SELL5T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2)   [web citation]
SELL5TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2)   [web citation]
SELL6TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2)   [web citation]
SELL7TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2)   [web citation]
SELLMOD1 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2)   [web citation]
SELLMOD1A 2D		n2 = A + Bx + Cx2 + D/(x2-E2)   [web citation]
SELLMOD2 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2)   [web citation]
SELLMOD2A 2D		n2 = A + Bx + Cx4 + D/(x2-E2)   [web citation]
SELLMOD3 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2)   [web citation]
SELLMOD4 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2)   [web citation]
SELLMOD4A 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2)   [web citation]
SELLMOD5 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2)   [web citation]
SELLMOD6 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2)   [web citation]
SELLMOD7 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2)   [web citation]
SELLMOD7A 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2)   [web citation]
SELLMOD8 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2)   [web citation]
SELLMOD9 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2)   [web citation]
HARTMANN3b With Offset 2D		n = A/(x - B)1.2 + Offset   [web citation]
SELLMOD3 With Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) + Offset   [web citation]
CAUCHY With Exponential Decay 2D		n = A + B/x2 + C/x4 n = n / (f * exp(x))   [web citation]
CONRADY1 With Exponential Decay 2D		n = A + B/x + C/x3.5 n = n / (f * exp(x))   [web citation]
CONRADY2 With Exponential Decay 2D		n = A + B/x2 + C/x3.5 n = n / (f * exp(x))   [web citation]
HARTMANN1 With Exponential Decay 2D		n = A + B/(C - x) n = n / (f * exp(x))   [web citation]
HARTMANN2 With Exponential Decay 2D		n = A + B/(C - x)2 n = n / (f * exp(x))   [web citation]
HARTMANN3a With Exponential Decay 2D		n = A + B/(C - x)1.2 n = n / (f * exp(x))   [web citation]
HARTMANN3b With Exponential Decay 2D		n = A/(x - B)1.2 n = n / exp(x)   [web citation]
HARTMANN4 With Exponential Decay 2D		n = A + B/(C - x) + D/(E - x) n = n / (h * exp(x))   [web citation]
HERZBRGR2X2 With Exponential Decay 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2 n = n / (g * exp(x))   [web citation]
HERZBRGR3X2 With Exponential Decay 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 n = n / (h * exp(x))   [web citation]
HERZBRGR3X3 With Exponential Decay 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4 n = n / (i * exp(x))   [web citation]
HERZBRGR4X2 With Exponential Decay 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2 n = n / (i * exp(x))   [web citation]
HERZBRGR5X2 With Exponential Decay 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2 n = n / (j * exp(x))   [web citation]
HERZBRGRJK With Exponential Decay 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2 n = n / (k * exp(x))   [web citation]
HoO1 With Exponential Decay 2D		n2 = A + Bx2 + C / (x2 - D2) n2 = n2 / (g * exp(x))   [web citation]
HoO2 With Exponential Decay 2D		n2 = A + Bx2 + Cx2 / (x2 - D2) n2 = n2 / (g * exp(x))   [web citation]
KINGSLAKE1 With Exponential Decay 2D		n2 = A + B/(x2-C2) + D/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
KINGSLAKE2 With Exponential Decay 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2) n2 = n2 / (j * exp(x))   [web citation]
MISC01 With Exponential Decay 2D		n2 = A + B/(x2-C2) n2 = n2 / (f * exp(x))   [web citation]
MISC02 With Exponential Decay 2D		n2 = A + Bx2 + C/(x2-D2) n2 = n2 / (g * exp(x))   [web citation]
MISC03 With Exponential Decay 2D		n2 = A + B/x2 + Cx2/(x2-D2) n2 = n2 / (g * exp(x))   [web citation]
MISC04 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F))) n2 = n2 / (j * exp(x))   [web citation]
SCHOTT2X3 With Exponential Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 n2 = n2 / (h * exp(x))   [web citation]
SCHOTT2X4 With Exponential Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 n2 = n2 / (i * exp(x))   [web citation]
SCHOTT2X5 With Exponential Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 n2 = n2 / (j * exp(x))   [web citation]
SCHOTT2X6 With Exponential Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12 n2 = n2 / (k * exp(x))   [web citation]
SCHOTT3X3 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 n2 = n2 / (i * exp(x))   [web citation]
SCHOTT3X4 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 n2 = n2 / (j * exp(x))   [web citation]
SCHOTT3X5 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10 n2 = n2 / (k * exp(x))   [web citation]
SCHOTT4X4 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8 n2 = n2 / (k * exp(x))   [web citation]
SCHOTT5X5 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10 n2 = n2 / (n * exp(x))   [web citation]
SELL1T With Exponential Decay 2D		n2 = 1 + Ax2 / (x2 - B2) n2 = n2 / (d * exp(x))   [web citation]
SELL1TA With Exponential Decay 2D		n2 = A + Bx2 / (x2 - C2) n2 = n2 / (f * exp(x))   [web citation]
SELL2T With Exponential Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) n2 = n2 / (g * exp(x))   [web citation]
SELL2TA With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELL3T With Exponential Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 / (i * exp(x))   [web citation]
SELL3TA With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 / (j * exp(x))   [web citation]
SELL4T With Exponential Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) n2 = n2 / (k * exp(x))   [web citation]
SELL4TA With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) n2 = n2 / (m * exp(x))   [web citation]
SELL5T With Exponential Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2) n2 = n2 / (n * exp(x))   [web citation]
SELL5TA With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) n2 = n2 / (p * exp(x))   [web citation]
SELL6TA With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) n2 = n2 / (r * exp(x))   [web citation]
SELL7TA With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2) n2 = n2 / (t * exp(x))   [web citation]
SELLMOD1 With Exponential Decay 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELLMOD1A With Exponential Decay 2D		n2 = A + Bx + Cx2 + D/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELLMOD2 With Exponential Decay 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELLMOD2A With Exponential Decay 2D		n2 = A + Bx + Cx4 + D/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELLMOD3 With Exponential Decay 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELLMOD4 With Exponential Decay 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 / (j * exp(x))   [web citation]
SELLMOD4A With Exponential Decay 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2) n2 = n2 / (j * exp(x))   [web citation]
SELLMOD5 With Exponential Decay 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 / (i * exp(x))   [web citation]
SELLMOD6 With Exponential Decay 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2) n2 = n2 / (h * exp(x))   [web citation]
SELLMOD7 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2) n2 = n2 / (i * exp(x))   [web citation]
SELLMOD7A With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2) n2 = n2 / (i * exp(x))   [web citation]
SELLMOD8 With Exponential Decay 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2) n2 = n2 / (j * exp(x))   [web citation]
SELLMOD9 With Exponential Decay 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2) n2 = n2 / (i * exp(x))   [web citation]
HARTMANN3b With Exponential Decay And Offset 2D		n = A/(x - B)1.2 n = n / exp(x) + Offset   [web citation]
SELLMOD3 With Exponential Decay And Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 / (i * exp(x)) + Offset   [web citation]
CAUCHY With Exponential Growth 2D		n = A + B/x2 + C/x4 n = n * (f * exp(x))   [web citation]
CONRADY1 With Exponential Growth 2D		n = A + B/x + C/x3.5 n = n * (f * exp(x))   [web citation]
CONRADY2 With Exponential Growth 2D		n = A + B/x2 + C/x3.5 n = n * (f * exp(x))   [web citation]
HARTMANN1 With Exponential Growth 2D		n = A + B/(C - x) n = n * (f * exp(x))   [web citation]
HARTMANN2 With Exponential Growth 2D		n = A + B/(C - x)2 n = n * (f * exp(x))   [web citation]
HARTMANN3a With Exponential Growth 2D		n = A + B/(C - x)1.2 n = n * (f * exp(x))   [web citation]
HARTMANN3b With Exponential Growth 2D		n = A/(x - B)1.2 n = n * exp(x)   [web citation]
HARTMANN4 With Exponential Growth 2D		n = A + B/(C - x) + D/(E - x) n = n * (h * exp(x))   [web citation]
HERZBRGR2X2 With Exponential Growth 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2 n = n * (g * exp(x))   [web citation]
HERZBRGR3X2 With Exponential Growth 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 n = n * (h * exp(x))   [web citation]
HERZBRGR3X3 With Exponential Growth 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4 n = n * (i * exp(x))   [web citation]
HERZBRGR4X2 With Exponential Growth 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2 n = n * (i * exp(x))   [web citation]
HERZBRGR5X2 With Exponential Growth 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2 n = n * (j * exp(x))   [web citation]
HERZBRGRJK With Exponential Growth 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2 n = n * (k * exp(x))   [web citation]
HoO1 With Exponential Growth 2D		n2 = A + Bx2 + C / (x2 - D2) n2 = n2 * (g * exp(x))   [web citation]
HoO2 With Exponential Growth 2D		n2 = A + Bx2 + Cx2 / (x2 - D2) n2 = n2 * (g * exp(x))   [web citation]
KINGSLAKE1 With Exponential Growth 2D		n2 = A + B/(x2-C2) + D/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
KINGSLAKE2 With Exponential Growth 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2) n2 = n2 * (j * exp(x))   [web citation]
MISC01 With Exponential Growth 2D		n2 = A + B/(x2-C2) n2 = n2 * (f * exp(x))   [web citation]
MISC02 With Exponential Growth 2D		n2 = A + Bx2 + C/(x2-D2) n2 = n2 * (g * exp(x))   [web citation]
MISC03 With Exponential Growth 2D		n2 = A + B/x2 + Cx2/(x2-D2) n2 = n2 * (g * exp(x))   [web citation]
MISC04 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F))) n2 = n2 * (j * exp(x))   [web citation]
SCHOTT2X3 With Exponential Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 n2 = n2 * (h * exp(x))   [web citation]
SCHOTT2X4 With Exponential Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 n2 = n2 * (i * exp(x))   [web citation]
SCHOTT2X5 With Exponential Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 n2 = n2 * (j * exp(x))   [web citation]
SCHOTT2X6 With Exponential Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12 n2 = n2 * (k * exp(x))   [web citation]
SCHOTT3X3 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 n2 = n2 * (i * exp(x))   [web citation]
SCHOTT3X4 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 n2 = n2 * (j * exp(x))   [web citation]
SCHOTT3X5 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10 n2 = n2 * (k * exp(x))   [web citation]
SCHOTT4X4 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8 n2 = n2 * (k * exp(x))   [web citation]
SCHOTT5X5 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10 n2 = n2 * (n * exp(x))   [web citation]
SELL1T With Exponential Growth 2D		n2 = 1 + Ax2 / (x2 - B2) n2 = n2 * (d * exp(x))   [web citation]
SELL1TA With Exponential Growth 2D		n2 = A + Bx2 / (x2 - C2) n2 = n2 * (f * exp(x))   [web citation]
SELL2T With Exponential Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) n2 = n2 * (g * exp(x))   [web citation]
SELL2TA With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELL3T With Exponential Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 * (i * exp(x))   [web citation]
SELL3TA With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 * (j * exp(x))   [web citation]
SELL4T With Exponential Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) n2 = n2 * (k * exp(x))   [web citation]
SELL4TA With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) n2 = n2 * (m * exp(x))   [web citation]
SELL5T With Exponential Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2) n2 = n2 * (n * exp(x))   [web citation]
SELL5TA With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) n2 = n2 * (p * exp(x))   [web citation]
SELL6TA With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) n2 = n2 * (r * exp(x))   [web citation]
SELL7TA With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2) n2 = n2 * (t * exp(x))   [web citation]
SELLMOD1 With Exponential Growth 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELLMOD1A With Exponential Growth 2D		n2 = A + Bx + Cx2 + D/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELLMOD2 With Exponential Growth 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELLMOD2A With Exponential Growth 2D		n2 = A + Bx + Cx4 + D/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELLMOD3 With Exponential Growth 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELLMOD4 With Exponential Growth 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 * (j * exp(x))   [web citation]
SELLMOD4A With Exponential Growth 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2) n2 = n2 * (j * exp(x))   [web citation]
SELLMOD5 With Exponential Growth 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 * (i * exp(x))   [web citation]
SELLMOD6 With Exponential Growth 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2) n2 = n2 * (h * exp(x))   [web citation]
SELLMOD7 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2) n2 = n2 * (i * exp(x))   [web citation]
SELLMOD7A With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2) n2 = n2 * (i * exp(x))   [web citation]
SELLMOD8 With Exponential Growth 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2) n2 = n2 * (j * exp(x))   [web citation]
SELLMOD9 With Exponential Growth 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2) n2 = n2 * (i * exp(x))   [web citation]
HARTMANN3b With Exponential Growth And Offset 2D		n = A/(x - B)1.2 n = n * exp(x) + Offset   [web citation]
SELLMOD3 With Exponential Growth And Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 * (i * exp(x)) + Offset   [web citation]
Inverse CAUCHY 2D		n = A + B/x2 + C/x4 n = x / n   [web citation]
Inverse CONRADY1 2D		n = A + B/x + C/x3.5 n = x / n   [web citation]
Inverse CONRADY2 2D		n = A + B/x2 + C/x3.5 n = x / n   [web citation]
Inverse HARTMANN1 2D		n = A + B/(C - x) n = x / n   [web citation]
Inverse HARTMANN2 2D		n = A + B/(C - x)2 n = x / n   [web citation]
Inverse HARTMANN3a 2D		n = A + B/(C - x)1.2 n = x / n   [web citation]
Inverse HARTMANN3b 2D		n = A/(x - B)1.2 n = x / n   [web citation]
Inverse HARTMANN4 2D		n = A + B/(C - x) + D/(E - x) n = x / n   [web citation]
Inverse HERZBRGR2X2 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2 n = x / n   [web citation]
Inverse HERZBRGR3X2 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 n = x / n   [web citation]
Inverse HERZBRGR3X3 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4 n = x / n   [web citation]
Inverse HERZBRGR4X2 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2 n = x / n   [web citation]
Inverse HERZBRGR5X2 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2 n = x / n   [web citation]
Inverse HERZBRGRJK 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2 n = x / n   [web citation]
Inverse HoO1 2D		n2 = A + Bx2 + C / (x2 - D2) n2 = x / n2   [web citation]
Inverse HoO2 2D		n2 = A + Bx2 + Cx2 / (x2 - D2) n2 = x / n2   [web citation]
Inverse KINGSLAKE1 2D		n2 = A + B/(x2-C2) + D/(x2-E2) n2 = x / n2   [web citation]
Inverse KINGSLAKE2 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2) n2 = x / n2   [web citation]
Inverse MISC01 2D		n2 = A + B/(x2-C2) n2 = x / n2   [web citation]
Inverse MISC02 2D		n2 = A + Bx2 + C/(x2-D2) n2 = x / n2   [web citation]
Inverse MISC03 2D		n2 = A + B/x2 + Cx2/(x2-D2) n2 = x / n2   [web citation]
Inverse MISC04 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F))) n2 = x / n2   [web citation]
Inverse SCHOTT2X3 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 n2 = x / n2   [web citation]
Inverse SCHOTT2X4 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 n2 = x / n2   [web citation]
Inverse SCHOTT2X5 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 n2 = x / n2   [web citation]
Inverse SCHOTT2X6 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12 n2 = x / n2   [web citation]
Inverse SCHOTT3X3 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 n2 = x / n2   [web citation]
Inverse SCHOTT3X4 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 n2 = x / n2   [web citation]
Inverse SCHOTT3X5 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10 n2 = x / n2   [web citation]
Inverse SCHOTT4X4 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8 n2 = x / n2   [web citation]
Inverse SCHOTT5X5 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10 n2 = x / n2   [web citation]
Inverse SELL1T 2D		n2 = 1 + Ax2 / (x2 - B2) n2 = x / n2   [web citation]
Inverse SELL1TA 2D		n2 = A + Bx2 / (x2 - C2) n2 = x / n2   [web citation]
Inverse SELL2T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) n2 = x / n2   [web citation]
Inverse SELL2TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) n2 = x / n2   [web citation]
Inverse SELL3T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = x / n2   [web citation]
Inverse SELL3TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = x / n2   [web citation]
Inverse SELL4T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) n2 = x / n2   [web citation]
Inverse SELL4TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) n2 = x / n2   [web citation]
Inverse SELL5T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2) n2 = x / n2   [web citation]
Inverse SELL5TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) n2 = x / n2   [web citation]
Inverse SELL6TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) n2 = x / n2   [web citation]
Inverse SELL7TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2) n2 = x / n2   [web citation]
Inverse SELLMOD1 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2) n2 = x / n2   [web citation]
Inverse SELLMOD1A 2D		n2 = A + Bx + Cx2 + D/(x2-E2) n2 = x / n2   [web citation]
Inverse SELLMOD2 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2) n2 = x / n2   [web citation]
Inverse SELLMOD2A 2D		n2 = A + Bx + Cx4 + D/(x2-E2) n2 = x / n2   [web citation]
Inverse SELLMOD3 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = x / n2   [web citation]
Inverse SELLMOD4 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = x / n2   [web citation]
Inverse SELLMOD4A 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2) n2 = x / n2   [web citation]
Inverse SELLMOD5 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = x / n2   [web citation]
Inverse SELLMOD6 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2) n2 = x / n2   [web citation]
Inverse SELLMOD7 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2) n2 = x / n2   [web citation]
Inverse SELLMOD7A 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2) n2 = x / n2   [web citation]
Inverse SELLMOD8 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2) n2 = x / n2   [web citation]
Inverse SELLMOD9 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2) n2 = x / n2   [web citation]
Inverse HARTMANN3b With Offset 2D		n = A/(x - B)1.2 n = x / n + Offset   [web citation]
Inverse SELLMOD3 With Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = x / n2 + Offset   [web citation]
CAUCHY With Linear Decay 2D		n = A + B/x2 + C/x4 n = n / (f * x)   [web citation]
CONRADY1 With Linear Decay 2D		n = A + B/x + C/x3.5 n = n / (f * x)   [web citation]
CONRADY2 With Linear Decay 2D		n = A + B/x2 + C/x3.5 n = n / (f * x)   [web citation]
HARTMANN1 With Linear Decay 2D		n = A + B/(C - x) n = n / (f * x)   [web citation]
HARTMANN2 With Linear Decay 2D		n = A + B/(C - x)2 n = n / (f * x)   [web citation]
HARTMANN3a With Linear Decay 2D		n = A + B/(C - x)1.2 n = n / (f * x)   [web citation]
HARTMANN3b With Linear Decay 2D		n = A/(x - B)1.2 n = n / x   [web citation]
HARTMANN4 With Linear Decay 2D		n = A + B/(C - x) + D/(E - x) n = n / (h * x)   [web citation]
HERZBRGR2X2 With Linear Decay 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2 n = n / (g * x)   [web citation]
HERZBRGR3X2 With Linear Decay 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 n = n / (h * x)   [web citation]
HERZBRGR3X3 With Linear Decay 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4 n = n / (i * x)   [web citation]
HERZBRGR4X2 With Linear Decay 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2 n = n / (i * x)   [web citation]
HERZBRGR5X2 With Linear Decay 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2 n = n / (j * x)   [web citation]
HERZBRGRJK With Linear Decay 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2 n = n / (k * x)   [web citation]
HoO1 With Linear Decay 2D		n2 = A + Bx2 + C / (x2 - D2) n2 = n2 / (g * x)   [web citation]
HoO2 With Linear Decay 2D		n2 = A + Bx2 + Cx2 / (x2 - D2) n2 = n2 / (g * x)   [web citation]
KINGSLAKE1 With Linear Decay 2D		n2 = A + B/(x2-C2) + D/(x2-E2) n2 = n2 / (h * x)   [web citation]
KINGSLAKE2 With Linear Decay 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2) n2 = n2 / (j * x)   [web citation]
MISC01 With Linear Decay 2D		n2 = A + B/(x2-C2) n2 = n2 / (f * x)   [web citation]
MISC02 With Linear Decay 2D		n2 = A + Bx2 + C/(x2-D2) n2 = n2 / (g * x)   [web citation]
MISC03 With Linear Decay 2D		n2 = A + B/x2 + Cx2/(x2-D2) n2 = n2 / (g * x)   [web citation]
MISC04 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F))) n2 = n2 / (j * x)   [web citation]
SCHOTT2X3 With Linear Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 n2 = n2 / (h * x)   [web citation]
SCHOTT2X4 With Linear Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 n2 = n2 / (i * x)   [web citation]
SCHOTT2X5 With Linear Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 n2 = n2 / (j * x)   [web citation]
SCHOTT2X6 With Linear Decay 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12 n2 = n2 / (k * x)   [web citation]
SCHOTT3X3 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 n2 = n2 / (i * x)   [web citation]
SCHOTT3X4 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 n2 = n2 / (j * x)   [web citation]
SCHOTT3X5 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10 n2 = n2 / (k * x)   [web citation]
SCHOTT4X4 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8 n2 = n2 / (k * x)   [web citation]
SCHOTT5X5 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10 n2 = n2 / (n * x)   [web citation]
SELL1T With Linear Decay 2D		n2 = 1 + Ax2 / (x2 - B2) n2 = n2 / (d * x)   [web citation]
SELL1TA With Linear Decay 2D		n2 = A + Bx2 / (x2 - C2) n2 = n2 / (f * x)   [web citation]
SELL2T With Linear Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) n2 = n2 / (g * x)   [web citation]
SELL2TA With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELL3T With Linear Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 / (i * x)   [web citation]
SELL3TA With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 / (j * x)   [web citation]
SELL4T With Linear Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) n2 = n2 / (k * x)   [web citation]
SELL4TA With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) n2 = n2 / (m * x)   [web citation]
SELL5T With Linear Decay 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2) n2 = n2 / (n * x)   [web citation]
SELL5TA With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) n2 = n2 / (p * x)   [web citation]
SELL6TA With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) n2 = n2 / (r * x)   [web citation]
SELL7TA With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2) n2 = n2 / (t * x)   [web citation]
SELLMOD1 With Linear Decay 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELLMOD1A With Linear Decay 2D		n2 = A + Bx + Cx2 + D/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELLMOD2 With Linear Decay 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELLMOD2A With Linear Decay 2D		n2 = A + Bx + Cx4 + D/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELLMOD3 With Linear Decay 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELLMOD4 With Linear Decay 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 / (j * x)   [web citation]
SELLMOD4A With Linear Decay 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2) n2 = n2 / (j * x)   [web citation]
SELLMOD5 With Linear Decay 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 / (i * x)   [web citation]
SELLMOD6 With Linear Decay 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2) n2 = n2 / (h * x)   [web citation]
SELLMOD7 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2) n2 = n2 / (i * x)   [web citation]
SELLMOD7A With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2) n2 = n2 / (i * x)   [web citation]
SELLMOD8 With Linear Decay 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2) n2 = n2 / (j * x)   [web citation]
SELLMOD9 With Linear Decay 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2) n2 = n2 / (i * x)   [web citation]
HARTMANN3b With Linear Decay And Offset 2D		n = A/(x - B)1.2 n = n / x + Offset   [web citation]
SELLMOD3 With Linear Decay And Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 / (i * x) + Offset   [web citation]
CAUCHY With Linear Growth 2D		n = A + B/x2 + C/x4 n = n * (f * x) + Offset   [web citation]
CONRADY1 With Linear Growth 2D		n = A + B/x + C/x3.5 n = n * (f * x) + Offset   [web citation]
CONRADY2 With Linear Growth 2D		n = A + B/x2 + C/x3.5 n = n * (f * x) + Offset   [web citation]
HARTMANN1 With Linear Growth 2D		n = A + B/(C - x) n = n * (f * x) + Offset   [web citation]
HARTMANN2 With Linear Growth 2D		n = A + B/(C - x)2 n = n * (f * x) + Offset   [web citation]
HARTMANN3a With Linear Growth 2D		n = A + B/(C - x)1.2 n = n * (f * x) + Offset   [web citation]
HARTMANN3b With Linear Growth 2D		n = A/(x - B)1.2 n = n * x   [web citation]
HARTMANN4 With Linear Growth 2D		n = A + B/(C - x) + D/(E - x) n = n * (h * x) + Offset   [web citation]
HERZBRGR2X2 With Linear Growth 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2 n = n * (g * x) + Offset   [web citation]
HERZBRGR3X2 With Linear Growth 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 n = n * (h * x) + Offset   [web citation]
HERZBRGR3X3 With Linear Growth 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4 n = n * (i * x) + Offset   [web citation]
HERZBRGR4X2 With Linear Growth 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2 n = n * (i * x) + Offset   [web citation]
HERZBRGR5X2 With Linear Growth 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2 n = n * (j * x) + Offset   [web citation]
HERZBRGRJK With Linear Growth 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2 n = n * (k * x) + Offset   [web citation]
HoO1 With Linear Growth 2D		n2 = A + Bx2 + C / (x2 - D2) n2 = n2 * (g * x) + Offset   [web citation]
HoO2 With Linear Growth 2D		n2 = A + Bx2 + Cx2 / (x2 - D2) n2 = n2 * (g * x) + Offset   [web citation]
KINGSLAKE1 With Linear Growth 2D		n2 = A + B/(x2-C2) + D/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
KINGSLAKE2 With Linear Growth 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2) n2 = n2 * (j * x) + Offset   [web citation]
MISC01 With Linear Growth 2D		n2 = A + B/(x2-C2) n2 = n2 * (f * x) + Offset   [web citation]
MISC02 With Linear Growth 2D		n2 = A + Bx2 + C/(x2-D2) n2 = n2 * (g * x) + Offset   [web citation]
MISC03 With Linear Growth 2D		n2 = A + B/x2 + Cx2/(x2-D2) n2 = n2 * (g * x) + Offset   [web citation]
MISC04 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F))) n2 = n2 * (j * x) + Offset   [web citation]
SCHOTT2X3 With Linear Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 n2 = n2 * (h * x) + Offset   [web citation]
SCHOTT2X4 With Linear Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 n2 = n2 * (i * x) + Offset   [web citation]
SCHOTT2X5 With Linear Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 n2 = n2 * (j * x) + Offset   [web citation]
SCHOTT2X6 With Linear Growth 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12 n2 = n2 * (k * x) + Offset   [web citation]
SCHOTT3X3 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 n2 = n2 * (i * x) + Offset   [web citation]
SCHOTT3X4 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 n2 = n2 * (j * x) + Offset   [web citation]
SCHOTT3X5 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10 n2 = n2 * (k * x) + Offset   [web citation]
SCHOTT4X4 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8 n2 = n2 * (k * x) + Offset   [web citation]
SCHOTT5X5 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10 n2 = n2 * (n * x) + Offset   [web citation]
SELL1T With Linear Growth 2D		n2 = 1 + Ax2 / (x2 - B2) n2 = n2 * (d * x) + Offset   [web citation]
SELL1TA With Linear Growth 2D		n2 = A + Bx2 / (x2 - C2) n2 = n2 * (f * x) + Offset   [web citation]
SELL2T With Linear Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) n2 = n2 * (g * x) + Offset   [web citation]
SELL2TA With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELL3T With Linear Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 * (i * x) + Offset   [web citation]
SELL3TA With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 * (j * x) + Offset   [web citation]
SELL4T With Linear Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) n2 = n2 * (k * x) + Offset   [web citation]
SELL4TA With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) n2 = n2 * (m * x) + Offset   [web citation]
SELL5T With Linear Growth 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2) n2 = n2 * (n * x) + Offset   [web citation]
SELL5TA With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) n2 = n2 * (p * x) + Offset   [web citation]
SELL6TA With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) n2 = n2 * (r * x) + Offset   [web citation]
SELL7TA With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2) n2 = n2 * (t * x) + Offset   [web citation]
SELLMOD1 With Linear Growth 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELLMOD1A With Linear Growth 2D		n2 = A + Bx + Cx2 + D/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELLMOD2 With Linear Growth 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELLMOD2A With Linear Growth 2D		n2 = A + Bx + Cx4 + D/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELLMOD3 With Linear Growth 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELLMOD4 With Linear Growth 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = n2 * (j * x) + Offset   [web citation]
SELLMOD4A With Linear Growth 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2) n2 = n2 * (j * x) + Offset   [web citation]
SELLMOD5 With Linear Growth 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = n2 * (i * x) + Offset   [web citation]
SELLMOD6 With Linear Growth 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2) n2 = n2 * (h * x) + Offset   [web citation]
SELLMOD7 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2) n2 = n2 * (i * x) + Offset   [web citation]
SELLMOD7A With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2) n2 = n2 * (i * x) + Offset   [web citation]
SELLMOD8 With Linear Growth 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2) n2 = n2 * (j * x) + Offset   [web citation]
SELLMOD9 With Linear Growth 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2) n2 = n2 * (i * x) + Offset   [web citation]
HARTMANN3b With Linear Growth And Offset 2D		n = A/(x - B)1.2 n = n * x + Offset   [web citation]
SELLMOD3 With Linear Growth And Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = n2 * (i * x) + Offset   [web citation]
Reciprocal CAUCHY 2D		n = A + B/x2 + C/x4 n = 1.0 / n   [web citation]
Reciprocal CONRADY1 2D		n = A + B/x + C/x3.5 n = 1.0 / n   [web citation]
Reciprocal CONRADY2 2D		n = A + B/x2 + C/x3.5 n = 1.0 / n   [web citation]
Reciprocal HARTMANN1 2D		n = A + B/(C - x) n = 1.0 / n   [web citation]
Reciprocal HARTMANN2 2D		n = A + B/(C - x)2 n = 1.0 / n   [web citation]
Reciprocal HARTMANN3a 2D		n = A + B/(C - x)1.2 n = 1.0 / n   [web citation]
Reciprocal HARTMANN3b 2D		n = A/(x - B)1.2 n = 1.0 / n   [web citation]
Reciprocal HARTMANN4 2D		n = A + B/(C - x) + D/(E - x) n = 1.0 / n   [web citation]
Reciprocal HERZBRGR2X2 2D		n = A + Bx2 + C / (x2 - 0.028) + D / (x2 - 0.028)2 n = 1.0 / n   [web citation]
Reciprocal HERZBRGR3X2 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 n = 1.0 / n   [web citation]
Reciprocal HERZBRGR3X3 2D		n = A + Bx2 + Cx4 + D / (x2 - 0.028) + E / (x2 - 0.028)2 + F / (x2 - 0.028)4 n = 1.0 / n   [web citation]
Reciprocal HERZBRGR4X2 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - 0.028) + F / (x2 - 0.028)2 n = 1.0 / n   [web citation]
Reciprocal HERZBRGR5X2 2D		n = A + Bx2 + Cx4 + Dx6 + Ex8 + F / (x2 - 0.028) + G / (x2 - 0.028)2 n = 1.0 / n   [web citation]
Reciprocal HERZBRGRJK 2D		n = A + Bx2 + Cx4 + Dx6 + E / (x2 - J) + F / (x2 - K)2 n = 1.0 / n   [web citation]
Reciprocal HoO1 2D		n2 = A + Bx2 + C / (x2 - D2) n2 = 1.0 / n2   [web citation]
Reciprocal HoO2 2D		n2 = A + Bx2 + Cx2 / (x2 - D2) n2 = 1.0 / n2   [web citation]
Reciprocal KINGSLAKE1 2D		n2 = A + B/(x2-C2) + D/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal KINGSLAKE2 2D		n2 = A + B/(x2-C2) + D/(x2-E2) + F/(x2-G2) n2 = 1.0 / n2   [web citation]
Reciprocal MISC01 2D		n2 = A + B/(x2-C2) n2 = 1.0 / n2   [web citation]
Reciprocal MISC02 2D		n2 = A + Bx2 + C/(x2-D2) n2 = 1.0 / n2   [web citation]
Reciprocal MISC03 2D		n2 = A + B/x2 + Cx2/(x2-D2) n2 = 1.0 / n2   [web citation]
Reciprocal MISC04 2D		n2 = A + Bx2 + Cx4 + D/x2 + Ex2/(x2-F+(Gx2/(x2-F))) n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT2X3 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT2X4 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT2X5 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT2X6 2D		n2 = A + Bx2 + C/x2 + D/x4 + E/x6 + F/x8 + G/x10 + H/x12 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT3X3 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT3X4 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT3X5 2D		n2 = A + Bx2 + Cx4 + D/x2 + E/x4 + F/x6 + G/x8 + H/x10 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT4X4 2D		n2 = A + Bx2 + Cx4 + Dx6 + E/x2 + F/x4 + G/x6 + H/x8 n2 = 1.0 / n2   [web citation]
Reciprocal SCHOTT5X5 2D		n2 = A + Bx2 + Cx4 + Dx6 + Ex8 + F/x2 + G/x4 + H/x6 + J/x8 + K/x10 n2 = 1.0 / n2   [web citation]
Reciprocal SELL1T 2D		n2 = 1 + Ax2 / (x2 - B2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL1TA 2D		n2 = A + Bx2 / (x2 - C2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL2T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL2TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL3T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL3TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL4T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL4TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL5T 2D		n2 = 1 + Ax2/(x2-B2) + Cx2/(x2-D2) + Ex2/(x2-F2) + Gx2/(x2-H2) + Jx2/(x2-K2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL5TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL6TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) n2 = 1.0 / n2   [web citation]
Reciprocal SELL7TA 2D		n2 = A + Bx2/(x2-C2) + Dx2/(x2-E2) + Fx2/(x2-G2) + Hx2/(x2-J2) + Kx2/(x2-M2) + Nx2/(x2-P2) + Qx2/(x2-R2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD1 2D		n2 = A + Bx + Cx2 + Dx2/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD1A 2D		n2 = A + Bx + Cx2 + D/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD2 2D		n2 = A + Bx + Cx4 + Dx2/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD2A 2D		n2 = A + Bx + Cx4 + D/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD3 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD4 2D		n2 = A + Bx2 + C/x2 + Dx2/(x2-E2) + Fx2/(x2-G2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD4A 2D		n2 = A + Bx2 + C/x2 + D/(x2-E2) + F/(x2-G2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD5 2D		n2 = A + Bx2 + Cx2/(x2-D2) + Ex2/(x2-F2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD6 2D		n2 = A + Bx2/(x2-C2) + D/(x2-E2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD7 2D		n2 = A + Bx2 + Cx4 + D/x6 + Ex2/(x2-F2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD7A 2D		n2 = A + Bx2 + Cx4 + D/x6 + E/(x2-F2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD8 2D		n2 = A + Bx2 + Cx4 + D/(x2-E2) + F/(x2-G2) n2 = 1.0 / n2   [web citation]
Reciprocal SELLMOD9 2D		n2 = A + B/x2 + C/x4 + D/x6 + Ex2/(x2-F2) n2 = 1.0 / n2   [web citation]
Reciprocal HARTMANN3b With Offset 2D		n = A/(x - B)1.2 n = 1.0 / n + Offset   [web citation]
Reciprocal SELLMOD3 With Offset 2D		n2 = (Ax2+B)/(x2-C2) + Dx2/(x2-E2) n2 = 1.0 / n2 + Offset   [web citation]

2D Peak

Arnold Cohen Log-Normal Peak Shifted 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g))
Arnold Cohen Two-Parameter Log-Normal Peak Shifted 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f))
Box Lucas A 2D		y = a * (1.0 - bx)
Box Lucas A Shifted 2D		y = a * (1.0 - bx-c)
Box Lucas B 2D		y = a * (1.0 - exp(-bx))
Box Lucas B Shifted 2D		y = a * (1.0 - exp(-b(x-c)))
Box Lucas C 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax))
Box Lucas C shifted 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c)))
Extreme Value Peak 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0)
Gaussian Peak 2D		y = a * exp(-0.5 * ((x-b)/c)2)
Gaussian Peak Modified 2D		y = a * exp(-0.5 * ((x-b)/c)d)
Hamilton 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b)
Log-Normal Peak 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2)
Log-Normal Peak Modified 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d)
Log-Normal Peak Modified Shifted 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d)
Log-Normal Peak Shifted 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2)
Logistic Peak 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c))
Lorentzian Modified Peak A 2D		y = 1.0 / (1.0 + (x-a)b)
Lorentzian Modified Peak B 2D		y = 1.0 / (a + (x-b)c)
Lorentzian Modified Peak C 2D		y = a / (b + (x-c)d)
Lorentzian Modified Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)c)
Lorentzian Modified Peak E 2D		y = 1.0 / (a + ((x-b)/c)d)
Lorentzian Modified Peak F 2D		y = a / (b + ((x-c)/d)f)
Lorentzian Peak A 2D		y = 1.0 / (1.0 + (x-a)2)
Lorentzian Peak B 2D		y = 1.0 / (a + (x-b)2)
Lorentzian Peak C 2D		y = a / (b + (x-c)2)
Lorentzian Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)2)
Lorentzian Peak E 2D		y = 1.0 / (a + ((x-b)/c)2)
Lorentzian Peak F 2D		y = a / (b + ((x-c)/d)2)
Pseudo-Voight Peak 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2))
Pseudo-Voight Peak Modified 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f))
Pulse Peak 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c))
Weibull Peak 2D		y = a * exp(-0.5 * (ln(x/b)/c)2)
Weibull Peak Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)d)
Weibull Peak Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d)
Weibull Peak Shifted 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2)
Arnold Cohen Log-Normal Peak Shifted With Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) + Offset
Box Lucas A Shifted With Offset 2D		y = a * (1.0 - bx-c) + Offset
Box Lucas A With Offset 2D		y = a * (1.0 - bx) + Offset
Box Lucas B Shifted With Offset 2D		y = a * (1.0 - exp(-b(x-c))) + Offset
Box Lucas B With Offset 2D		y = a * (1.0 - exp(-bx)) + Offset
Box Lucas C With Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) + Offset
Box Lucas C shifted With Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) + Offset
Extreme Value Peak With Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) + Offset
Gaussian Peak Modified With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) + Offset
Gaussian Peak With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) + Offset
Hamilton With Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) + Offset
Log-Normal Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) + Offset
Log-Normal Peak Modified With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) + Offset
Log-Normal Peak Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) + Offset
Log-Normal Peak With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) + Offset
Logistic Peak With Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) + Offset
Lorentzian Modified Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)b) + Offset
Lorentzian Modified Peak B With Offset 2D		y = 1.0 / (a + (x-b)c) + Offset
Lorentzian Modified Peak C With Offset 2D		y = a / (b + (x-c)d) + Offset
Lorentzian Modified Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) + Offset
Lorentzian Modified Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)d) + Offset
Lorentzian Modified Peak F With Offset 2D		y = a / (b + ((x-c)/d)f) + Offset
Lorentzian Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)2) + Offset
Lorentzian Peak B With Offset 2D		y = 1.0 / (a + (x-b)2) + Offset
Lorentzian Peak C With Offset 2D		y = a / (b + (x-c)2) + Offset
Lorentzian Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) + Offset
Lorentzian Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)2) + Offset
Lorentzian Peak F With Offset 2D		y = a / (b + ((x-c)/d)2) + Offset
Pseudo-Voight Peak Modified With Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) + Offset
Pseudo-Voight Peak With Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) + Offset
Pulse Peak With Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) + Offset
Weibull Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) + Offset
Weibull Peak Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) + Offset
Weibull Peak Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) + Offset
Weibull Peak With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) + Offset
Arnold Cohen Log-Normal Peak Shifted With Exponential Decay 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y / exp(x)
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Decay 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y / (g * exp(x))
Box Lucas A Shifted With Exponential Decay 2D		y = a * (1.0 - bx-c) y = y / exp(x)
Box Lucas A With Exponential Decay 2D		y = a * (1.0 - bx) y = y / exp(x)
Box Lucas B Shifted With Exponential Decay 2D		y = a * (1.0 - exp(-b(x-c))) y = y / exp(x)
Box Lucas B With Exponential Decay 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x)
Box Lucas C With Exponential Decay 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / exp(x)
Box Lucas C shifted With Exponential Decay 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / exp(x)
Extreme Value Peak With Exponential Decay 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / exp(x)
Gaussian Peak Modified With Exponential Decay 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y / exp(x)
Gaussian Peak With Exponential Decay 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y / exp(x)
Hamilton With Exponential Decay 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb / (h * exp(x))
Log-Normal Peak Modified Shifted With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y / exp(x)
Log-Normal Peak Modified With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y / exp(x)
Log-Normal Peak Shifted With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y / exp(x)
Log-Normal Peak With Exponential Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y / exp(x)
Logistic Peak With Exponential Decay 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y / exp(x)
Lorentzian Modified Peak A With Exponential Decay 2D		y = 1.0 / (1.0 + (x-a)b) y = y / (d * exp(x))
Lorentzian Modified Peak B With Exponential Decay 2D		y = 1.0 / (a + (x-b)c) y = y / (f * exp(x))
Lorentzian Modified Peak C With Exponential Decay 2D		y = a / (b + (x-c)d) y = y / exp(x)
Lorentzian Modified Peak D With Exponential Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y / (f * exp(x))
Lorentzian Modified Peak E With Exponential Decay 2D		y = 1.0 / (a + ((x-b)/c)d) y = y / (g * exp(x))
Lorentzian Modified Peak F With Exponential Decay 2D		y = a / (b + ((x-c)/d)f) y = y / exp(x)
Lorentzian Peak A With Exponential Decay 2D		y = 1.0 / (1.0 + (x-a)2) y = y / (c * exp(x))
Lorentzian Peak B With Exponential Decay 2D		y = 1.0 / (a + (x-b)2) y = y / (d * exp(x))
Lorentzian Peak C With Exponential Decay 2D		y = a / (b + (x-c)2) y = y / exp(x)
Lorentzian Peak D With Exponential Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y / (d * exp(x))
Lorentzian Peak E With Exponential Decay 2D		y = 1.0 / (a + ((x-b)/c)2) y = y / (f * exp(x))
Lorentzian Peak F With Exponential Decay 2D		y = a / (b + ((x-c)/d)2) y = y / exp(x)
Pseudo-Voight Peak Modified With Exponential Decay 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y / exp(x)
Pseudo-Voight Peak With Exponential Decay 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y / exp(x)
Pulse Peak With Exponential Decay 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / exp(x)
Weibull Peak Modified Shifted With Exponential Decay 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y / exp(x)
Weibull Peak Modified With Exponential Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y / exp(x)
Weibull Peak Shifted With Exponential Decay 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y / exp(x)
Weibull Peak With Exponential Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y / exp(x)
Arnold Cohen Log-Normal Peak Shifted With Exponential Decay And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y / exp(x) + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Decay And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y / (h * exp(x)) + Offset
Box Lucas A Shifted With Exponential Decay And Offset 2D		y = a * (1.0 - bx-c) y = y / exp(x) + Offset
Box Lucas A With Exponential Decay And Offset 2D		y = a * (1.0 - bx) y = y / exp(x) + Offset
Box Lucas B Shifted With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y / exp(x) + Offset
Box Lucas B With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / exp(x) + Offset
Box Lucas C With Exponential Decay And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / exp(x) + Offset
Box Lucas C shifted With Exponential Decay And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / exp(x) + Offset
Extreme Value Peak With Exponential Decay And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / exp(x) + Offset
Gaussian Peak Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y / exp(x) + Offset
Gaussian Peak With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y / exp(x) + Offset
Hamilton With Exponential Decay And Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb / (i * exp(x)) + Offset
Log-Normal Peak Modified Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y / exp(x) + Offset
Log-Normal Peak Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y / exp(x) + Offset
Log-Normal Peak Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y / exp(x) + Offset
Log-Normal Peak With Exponential Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y / exp(x) + Offset
Logistic Peak With Exponential Decay And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y / exp(x) + Offset
Lorentzian Modified Peak A With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)b) y = y / (f * exp(x)) + Offset
Lorentzian Modified Peak B With Exponential Decay And Offset 2D		y = 1.0 / (a + (x-b)c) y = y / (g * exp(x)) + Offset
Lorentzian Modified Peak C With Exponential Decay And Offset 2D		y = a / (b + (x-c)d) y = y / exp(x) + Offset
Lorentzian Modified Peak D With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y / (g * exp(x)) + Offset
Lorentzian Modified Peak E With Exponential Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)d) y = y / (h * exp(x)) + Offset
Lorentzian Modified Peak F With Exponential Decay And Offset 2D		y = a / (b + ((x-c)/d)f) y = y / exp(x) + Offset
Lorentzian Peak A With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)2) y = y / (d * exp(x)) + Offset
Lorentzian Peak B With Exponential Decay And Offset 2D		y = 1.0 / (a + (x-b)2) y = y / (f * exp(x)) + Offset
Lorentzian Peak C With Exponential Decay And Offset 2D		y = a / (b + (x-c)2) y = y / exp(x) + Offset
Lorentzian Peak D With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y / (f * exp(x)) + Offset
Lorentzian Peak E With Exponential Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)2) y = y / (g * exp(x)) + Offset
Lorentzian Peak F With Exponential Decay And Offset 2D		y = a / (b + ((x-c)/d)2) y = y / exp(x) + Offset
Pseudo-Voight Peak Modified With Exponential Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y / exp(x) + Offset
Pseudo-Voight Peak With Exponential Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y / exp(x) + Offset
Pulse Peak With Exponential Decay And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / exp(x) + Offset
Weibull Peak Modified Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y / exp(x) + Offset
Weibull Peak Modified With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y / exp(x) + Offset
Weibull Peak Shifted With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y / exp(x) + Offset
Weibull Peak With Exponential Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y / exp(x) + Offset
Arnold Cohen Log-Normal Peak Shifted With Exponential Growth 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y * exp(x)
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Growth 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y * (g * exp(x))
Box Lucas A Shifted With Exponential Growth 2D		y = a * (1.0 - bx-c) y = y * exp(x)
Box Lucas A With Exponential Growth 2D		y = a * (1.0 - bx) y = y * exp(x)
Box Lucas B Shifted With Exponential Growth 2D		y = a * (1.0 - exp(-b(x-c))) y = y * exp(x)
Box Lucas B With Exponential Growth 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x)
Box Lucas C With Exponential Growth 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * exp(x)
Box Lucas C shifted With Exponential Growth 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * exp(x)
Extreme Value Peak With Exponential Growth 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * exp(x)
Gaussian Peak Modified With Exponential Growth 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y * exp(x)
Gaussian Peak With Exponential Growth 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y * exp(x)
Hamilton With Exponential Growth 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb * (h * exp(x))
Log-Normal Peak Modified Shifted With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y * exp(x)
Log-Normal Peak Modified With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y * exp(x)
Log-Normal Peak Shifted With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y * exp(x)
Log-Normal Peak With Exponential Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y * exp(x)
Logistic Peak With Exponential Growth 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y * exp(x)
Lorentzian Modified Peak A With Exponential Growth 2D		y = 1.0 / (1.0 + (x-a)b) y = y * (d * exp(x))
Lorentzian Modified Peak B With Exponential Growth 2D		y = 1.0 / (a + (x-b)c) y = y * (f * exp(x))
Lorentzian Modified Peak C With Exponential Growth 2D		y = a / (b + (x-c)d) y = y * exp(x)
Lorentzian Modified Peak D With Exponential Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y * (f * exp(x))
Lorentzian Modified Peak E With Exponential Growth 2D		y = 1.0 / (a + ((x-b)/c)d) y = y * (g * exp(x))
Lorentzian Modified Peak F With Exponential Growth 2D		y = a / (b + ((x-c)/d)f) y = y * exp(x)
Lorentzian Peak A With Exponential Growth 2D		y = 1.0 / (1.0 + (x-a)2) y = y * (c * exp(x))
Lorentzian Peak B With Exponential Growth 2D		y = 1.0 / (a + (x-b)2) y = y * (d * exp(x))
Lorentzian Peak C With Exponential Growth 2D		y = a / (b + (x-c)2) y = y * exp(x)
Lorentzian Peak D With Exponential Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y * (d * exp(x))
Lorentzian Peak E With Exponential Growth 2D		y = 1.0 / (a + ((x-b)/c)2) y = y * (f * exp(x))
Lorentzian Peak F With Exponential Growth 2D		y = a / (b + ((x-c)/d)2) y = y * exp(x)
Pseudo-Voight Peak Modified With Exponential Growth 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y * exp(x)
Pseudo-Voight Peak With Exponential Growth 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y * exp(x)
Pulse Peak With Exponential Growth 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * exp(x)
Weibull Peak Modified Shifted With Exponential Growth 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y * exp(x)
Weibull Peak Modified With Exponential Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y * exp(x)
Weibull Peak Shifted With Exponential Growth 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y * exp(x)
Weibull Peak With Exponential Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y * exp(x)
Arnold Cohen Log-Normal Peak Shifted With Exponential Growth And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y * exp(x) + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Exponential Growth And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y * (h * exp(x)) + Offset
Box Lucas A Shifted With Exponential Growth And Offset 2D		y = a * (1.0 - bx-c) y = y * exp(x) + Offset
Box Lucas A With Exponential Growth And Offset 2D		y = a * (1.0 - bx) y = y * exp(x) + Offset
Box Lucas B Shifted With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y * exp(x) + Offset
Box Lucas B With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * exp(x) + Offset
Box Lucas C With Exponential Growth And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * exp(x) + Offset
Box Lucas C shifted With Exponential Growth And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * exp(x) + Offset
Extreme Value Peak With Exponential Growth And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * exp(x) + Offset
Gaussian Peak Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y * exp(x) + Offset
Gaussian Peak With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y * exp(x) + Offset
Hamilton With Exponential Growth And Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb * (i * exp(x)) + Offset
Log-Normal Peak Modified Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y * exp(x) + Offset
Log-Normal Peak Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y * exp(x) + Offset
Log-Normal Peak Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y * exp(x) + Offset
Log-Normal Peak With Exponential Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y * exp(x) + Offset
Logistic Peak With Exponential Growth And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y * exp(x) + Offset
Lorentzian Modified Peak A With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)b) y = y * (f * exp(x)) + Offset
Lorentzian Modified Peak B With Exponential Growth And Offset 2D		y = 1.0 / (a + (x-b)c) y = y * (g * exp(x)) + Offset
Lorentzian Modified Peak C With Exponential Growth And Offset 2D		y = a / (b + (x-c)d) y = y * exp(x) + Offset
Lorentzian Modified Peak D With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y * (g * exp(x)) + Offset
Lorentzian Modified Peak E With Exponential Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)d) y = y * (h * exp(x)) + Offset
Lorentzian Modified Peak F With Exponential Growth And Offset 2D		y = a / (b + ((x-c)/d)f) y = y * exp(x) + Offset
Lorentzian Peak A With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)2) y = y * (d * exp(x)) + Offset
Lorentzian Peak B With Exponential Growth And Offset 2D		y = 1.0 / (a + (x-b)2) y = y * (f * exp(x)) + Offset
Lorentzian Peak C With Exponential Growth And Offset 2D		y = a / (b + (x-c)2) y = y * exp(x) + Offset
Lorentzian Peak D With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y * (f * exp(x)) + Offset
Lorentzian Peak E With Exponential Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)2) y = y * (g * exp(x)) + Offset
Lorentzian Peak F With Exponential Growth And Offset 2D		y = a / (b + ((x-c)/d)2) y = y * exp(x) + Offset
Pseudo-Voight Peak Modified With Exponential Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y * exp(x) + Offset
Pseudo-Voight Peak With Exponential Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y * exp(x) + Offset
Pulse Peak With Exponential Growth And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * exp(x) + Offset
Weibull Peak Modified Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y * exp(x) + Offset
Weibull Peak Modified With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y * exp(x) + Offset
Weibull Peak Shifted With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y * exp(x) + Offset
Weibull Peak With Exponential Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y * exp(x) + Offset
Inverse Arnold Cohen Log-Normal Peak Shifted 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = x / y
Inverse Arnold Cohen Two-Parameter Log-Normal Peak Shifted 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = x / y
Inverse Box Lucas A 2D		y = a * (1.0 - bx) y = x / y
Inverse Box Lucas A Shifted 2D		y = a * (1.0 - bx-c) y = x / y
Inverse Box Lucas B 2D		y = a * (1.0 - exp(-bx)) y = x / y
Inverse Box Lucas B Shifted 2D		y = a * (1.0 - exp(-b(x-c))) y = x / y
Inverse Box Lucas C 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = x / y
Inverse Box Lucas C shifted 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = x / y
Inverse Extreme Value Peak 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = x / y
Inverse Gaussian Peak 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = x / y
Inverse Gaussian Peak Modified 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = x / y
Inverse Hamilton 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = x / Vb
Inverse Log-Normal Peak 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = x / y
Inverse Log-Normal Peak Modified 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = x / y
Inverse Log-Normal Peak Modified Shifted 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = x / y
Inverse Log-Normal Peak Shifted 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = x / y
Inverse Logistic Peak 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = x / y
Inverse Lorentzian Modified Peak A 2D		y = 1.0 / (1.0 + (x-a)b) y = x / y
Inverse Lorentzian Modified Peak B 2D		y = 1.0 / (a + (x-b)c) y = x / y
Inverse Lorentzian Modified Peak C 2D		y = a / (b + (x-c)d) y = x / y
Inverse Lorentzian Modified Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = x / y
Inverse Lorentzian Modified Peak E 2D		y = 1.0 / (a + ((x-b)/c)d) y = x / y
Inverse Lorentzian Modified Peak F 2D		y = a / (b + ((x-c)/d)f) y = x / y
Inverse Lorentzian Peak A 2D		y = 1.0 / (1.0 + (x-a)2) y = x / y
Inverse Lorentzian Peak B 2D		y = 1.0 / (a + (x-b)2) y = x / y
Inverse Lorentzian Peak C 2D		y = a / (b + (x-c)2) y = x / y
Inverse Lorentzian Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = x / y
Inverse Lorentzian Peak E 2D		y = 1.0 / (a + ((x-b)/c)2) y = x / y
Inverse Lorentzian Peak F 2D		y = a / (b + ((x-c)/d)2) y = x / y
Inverse Pseudo-Voight Peak 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = x / y
Inverse Pseudo-Voight Peak Modified 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = x / y
Inverse Pulse Peak 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = x / y
Inverse Weibull Peak 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = x / y
Inverse Weibull Peak Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = x / y
Inverse Weibull Peak Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = x / y
Inverse Weibull Peak Shifted 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = x / y
Inverse Arnold Cohen Log-Normal Peak Shifted With Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = x / y + Offset
Inverse Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = x / y + Offset
Inverse Box Lucas A Shifted With Offset 2D		y = a * (1.0 - bx-c) y = x / y + Offset
Inverse Box Lucas A With Offset 2D		y = a * (1.0 - bx) y = x / y + Offset
Inverse Box Lucas B Shifted With Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = x / y + Offset
Inverse Box Lucas B With Offset 2D		y = a * (1.0 - exp(-bx)) y = x / y + Offset
Inverse Box Lucas C With Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = x / y + Offset
Inverse Box Lucas C shifted With Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = x / y + Offset
Inverse Extreme Value Peak With Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = x / y + Offset
Inverse Gaussian Peak Modified With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = x / y + Offset
Inverse Gaussian Peak With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = x / y + Offset
Inverse Hamilton With Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = x / Vb + Offset
Inverse Log-Normal Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = x / y + Offset
Inverse Log-Normal Peak Modified With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = x / y + Offset
Inverse Log-Normal Peak Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = x / y + Offset
Inverse Log-Normal Peak With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = x / y + Offset
Inverse Logistic Peak With Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = x / y + Offset
Inverse Lorentzian Modified Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)b) y = x / y + Offset
Inverse Lorentzian Modified Peak B With Offset 2D		y = 1.0 / (a + (x-b)c) y = x / y + Offset
Inverse Lorentzian Modified Peak C With Offset 2D		y = a / (b + (x-c)d) y = x / y + Offset
Inverse Lorentzian Modified Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = x / y + Offset
Inverse Lorentzian Modified Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)d) y = x / y + Offset
Inverse Lorentzian Modified Peak F With Offset 2D		y = a / (b + ((x-c)/d)f) y = x / y + Offset
Inverse Lorentzian Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)2) y = x / y + Offset
Inverse Lorentzian Peak B With Offset 2D		y = 1.0 / (a + (x-b)2) y = x / y + Offset
Inverse Lorentzian Peak C With Offset 2D		y = a / (b + (x-c)2) y = x / y + Offset
Inverse Lorentzian Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = x / y + Offset
Inverse Lorentzian Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)2) y = x / y + Offset
Inverse Lorentzian Peak F With Offset 2D		y = a / (b + ((x-c)/d)2) y = x / y + Offset
Inverse Pseudo-Voight Peak Modified With Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = x / y + Offset
Inverse Pseudo-Voight Peak With Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = x / y + Offset
Inverse Pulse Peak With Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = x / y + Offset
Inverse Weibull Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = x / y + Offset
Inverse Weibull Peak Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = x / y + Offset
Inverse Weibull Peak Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = x / y + Offset
Inverse Weibull Peak With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = x / y + Offset
Arnold Cohen Log-Normal Peak Shifted With Linear Decay 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y / x
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Decay 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y / (g * x)
Box Lucas A Shifted With Linear Decay 2D		y = a * (1.0 - bx-c) y = y / x
Box Lucas A With Linear Decay 2D		y = a * (1.0 - bx) y = y / x
Box Lucas B Shifted With Linear Decay 2D		y = a * (1.0 - exp(-b(x-c))) y = y / x
Box Lucas B With Linear Decay 2D		y = a * (1.0 - exp(-bx)) y = y / x
Box Lucas C With Linear Decay 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / x
Box Lucas C shifted With Linear Decay 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / x
Extreme Value Peak With Linear Decay 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / x
Gaussian Peak Modified With Linear Decay 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y / x
Gaussian Peak With Linear Decay 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y / x
Hamilton With Linear Decay 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb / (h * x)
Log-Normal Peak Modified Shifted With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y / x
Log-Normal Peak Modified With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y / x
Log-Normal Peak Shifted With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y / x
Log-Normal Peak With Linear Decay 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y / x
Logistic Peak With Linear Decay 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y / x
Lorentzian Modified Peak A With Linear Decay 2D		y = 1.0 / (1.0 + (x-a)b) y = y / (d * x)
Lorentzian Modified Peak B With Linear Decay 2D		y = 1.0 / (a + (x-b)c) y = y / (f * x)
Lorentzian Modified Peak C With Linear Decay 2D		y = a / (b + (x-c)d) y = y / x
Lorentzian Modified Peak D With Linear Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y / (f * x)
Lorentzian Modified Peak E With Linear Decay 2D		y = 1.0 / (a + ((x-b)/c)d) y = y / (g * x)
Lorentzian Modified Peak F With Linear Decay 2D		y = a / (b + ((x-c)/d)f) y = y / x
Lorentzian Peak A With Linear Decay 2D		y = 1.0 / (1.0 + (x-a)2) y = y / (c * x)
Lorentzian Peak B With Linear Decay 2D		y = 1.0 / (a + (x-b)2) y = y / (d * x)
Lorentzian Peak C With Linear Decay 2D		y = a / (b + (x-c)2) y = y / x
Lorentzian Peak D With Linear Decay 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y / (d * x)
Lorentzian Peak E With Linear Decay 2D		y = 1.0 / (a + ((x-b)/c)2) y = y / (f * x)
Lorentzian Peak F With Linear Decay 2D		y = a / (b + ((x-c)/d)2) y = y / x
Pseudo-Voight Peak Modified With Linear Decay 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y / x
Pseudo-Voight Peak With Linear Decay 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y / x
Pulse Peak With Linear Decay 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / x
Weibull Peak Modified Shifted With Linear Decay 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y / x
Weibull Peak Modified With Linear Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y / x
Weibull Peak Shifted With Linear Decay 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y / x
Weibull Peak With Linear Decay 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y / x
Arnold Cohen Log-Normal Peak Shifted With Linear Decay And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y / x + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Decay And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y / (h * x) + Offset
Box Lucas A Shifted With Linear Decay And Offset 2D		y = a * (1.0 - bx-c) y = y / x + Offset
Box Lucas A With Linear Decay And Offset 2D		y = a * (1.0 - bx) y = y / x + Offset
Box Lucas B Shifted With Linear Decay And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y / x + Offset
Box Lucas B With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx)) y = y / x + Offset
Box Lucas C With Linear Decay And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y / x + Offset
Box Lucas C shifted With Linear Decay And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y / x + Offset
Extreme Value Peak With Linear Decay And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y / x + Offset
Gaussian Peak Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y / x + Offset
Gaussian Peak With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y / x + Offset
Hamilton With Linear Decay And Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb / (i * x) + Offset
Log-Normal Peak Modified Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y / x + Offset
Log-Normal Peak Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y / x + Offset
Log-Normal Peak Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y / x + Offset
Log-Normal Peak With Linear Decay And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y / x + Offset
Logistic Peak With Linear Decay And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y / x + Offset
Lorentzian Modified Peak A With Linear Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)b) y = y / (f * x) + Offset
Lorentzian Modified Peak B With Linear Decay And Offset 2D		y = 1.0 / (a + (x-b)c) y = y / (g * x) + Offset
Lorentzian Modified Peak C With Linear Decay And Offset 2D		y = a / (b + (x-c)d) y = y / x + Offset
Lorentzian Modified Peak D With Linear Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y / (g * x) + Offset
Lorentzian Modified Peak E With Linear Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)d) y = y / (h * x) + Offset
Lorentzian Modified Peak F With Linear Decay And Offset 2D		y = a / (b + ((x-c)/d)f) y = y / x + Offset
Lorentzian Peak A With Linear Decay And Offset 2D		y = 1.0 / (1.0 + (x-a)2) y = y / (d * x) + Offset
Lorentzian Peak B With Linear Decay And Offset 2D		y = 1.0 / (a + (x-b)2) y = y / (f * x) + Offset
Lorentzian Peak C With Linear Decay And Offset 2D		y = a / (b + (x-c)2) y = y / x + Offset
Lorentzian Peak D With Linear Decay And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y / (f * x) + Offset
Lorentzian Peak E With Linear Decay And Offset 2D		y = 1.0 / (a + ((x-b)/c)2) y = y / (g * x) + Offset
Lorentzian Peak F With Linear Decay And Offset 2D		y = a / (b + ((x-c)/d)2) y = y / x + Offset
Pseudo-Voight Peak Modified With Linear Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y / x + Offset
Pseudo-Voight Peak With Linear Decay And Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y / x + Offset
Pulse Peak With Linear Decay And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y / x + Offset
Weibull Peak Modified Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y / x + Offset
Weibull Peak Modified With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y / x + Offset
Weibull Peak Shifted With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y / x + Offset
Weibull Peak With Linear Decay And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y / x + Offset
Arnold Cohen Log-Normal Peak Shifted With Linear Growth 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y * x
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Growth 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y * (g * x) + Offset
Box Lucas A Shifted With Linear Growth 2D		y = a * (1.0 - bx-c) y = y * x
Box Lucas A With Linear Growth 2D		y = a * (1.0 - bx) y = y * x
Box Lucas B Shifted With Linear Growth 2D		y = a * (1.0 - exp(-b(x-c))) y = y * x
Box Lucas B With Linear Growth 2D		y = a * (1.0 - exp(-bx)) y = y * x
Box Lucas C With Linear Growth 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * x
Box Lucas C shifted With Linear Growth 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * x
Extreme Value Peak With Linear Growth 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * x
Gaussian Peak Modified With Linear Growth 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y * x
Gaussian Peak With Linear Growth 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y * x
Hamilton With Linear Growth 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb * (h * x) + Offset
Log-Normal Peak Modified Shifted With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y * x
Log-Normal Peak Modified With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y * x
Log-Normal Peak Shifted With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y * x
Log-Normal Peak With Linear Growth 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y * x
Logistic Peak With Linear Growth 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y * x
Lorentzian Modified Peak A With Linear Growth 2D		y = 1.0 / (1.0 + (x-a)b) y = y * (d * x) + Offset
Lorentzian Modified Peak B With Linear Growth 2D		y = 1.0 / (a + (x-b)c) y = y * (f * x) + Offset
Lorentzian Modified Peak C With Linear Growth 2D		y = a / (b + (x-c)d) y = y * x
Lorentzian Modified Peak D With Linear Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y * (f * x) + Offset
Lorentzian Modified Peak E With Linear Growth 2D		y = 1.0 / (a + ((x-b)/c)d) y = y * (g * x) + Offset
Lorentzian Modified Peak F With Linear Growth 2D		y = a / (b + ((x-c)/d)f) y = y * x
Lorentzian Peak A With Linear Growth 2D		y = 1.0 / (1.0 + (x-a)2) y = y * (c * x) + Offset
Lorentzian Peak B With Linear Growth 2D		y = 1.0 / (a + (x-b)2) y = y * (d * x) + Offset
Lorentzian Peak C With Linear Growth 2D		y = a / (b + (x-c)2) y = y * x
Lorentzian Peak D With Linear Growth 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y * (d * x) + Offset
Lorentzian Peak E With Linear Growth 2D		y = 1.0 / (a + ((x-b)/c)2) y = y * (f * x) + Offset
Lorentzian Peak F With Linear Growth 2D		y = a / (b + ((x-c)/d)2) y = y * x
Pseudo-Voight Peak Modified With Linear Growth 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y * x
Pseudo-Voight Peak With Linear Growth 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y * x
Pulse Peak With Linear Growth 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * x
Weibull Peak Modified Shifted With Linear Growth 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y * x
Weibull Peak Modified With Linear Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y * x
Weibull Peak Shifted With Linear Growth 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y * x
Weibull Peak With Linear Growth 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y * x
Arnold Cohen Log-Normal Peak Shifted With Linear Growth And Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = y * x + Offset
Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Linear Growth And Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = y * (h * x) + Offset
Box Lucas A Shifted With Linear Growth And Offset 2D		y = a * (1.0 - bx-c) y = y * x + Offset
Box Lucas A With Linear Growth And Offset 2D		y = a * (1.0 - bx) y = y * x + Offset
Box Lucas B Shifted With Linear Growth And Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = y * x + Offset
Box Lucas B With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx)) y = y * x + Offset
Box Lucas C With Linear Growth And Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = y * x + Offset
Box Lucas C shifted With Linear Growth And Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = y * x + Offset
Extreme Value Peak With Linear Growth And Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = y * x + Offset
Gaussian Peak Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = y * x + Offset
Gaussian Peak With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = y * x + Offset
Hamilton With Linear Growth And Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = Vb * (i * x) + Offset
Log-Normal Peak Modified Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = y * x + Offset
Log-Normal Peak Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = y * x + Offset
Log-Normal Peak Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = y * x + Offset
Log-Normal Peak With Linear Growth And Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = y * x + Offset
Logistic Peak With Linear Growth And Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = y * x + Offset
Lorentzian Modified Peak A With Linear Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)b) y = y * (f * x) + Offset
Lorentzian Modified Peak B With Linear Growth And Offset 2D		y = 1.0 / (a + (x-b)c) y = y * (g * x) + Offset
Lorentzian Modified Peak C With Linear Growth And Offset 2D		y = a / (b + (x-c)d) y = y * x + Offset
Lorentzian Modified Peak D With Linear Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = y * (g * x) + Offset
Lorentzian Modified Peak E With Linear Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)d) y = y * (h * x) + Offset
Lorentzian Modified Peak F With Linear Growth And Offset 2D		y = a / (b + ((x-c)/d)f) y = y * x + Offset
Lorentzian Peak A With Linear Growth And Offset 2D		y = 1.0 / (1.0 + (x-a)2) y = y * (d * x) + Offset
Lorentzian Peak B With Linear Growth And Offset 2D		y = 1.0 / (a + (x-b)2) y = y * (f * x) + Offset
Lorentzian Peak C With Linear Growth And Offset 2D		y = a / (b + (x-c)2) y = y * x + Offset
Lorentzian Peak D With Linear Growth And Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = y * (f * x) + Offset
Lorentzian Peak E With Linear Growth And Offset 2D		y = 1.0 / (a + ((x-b)/c)2) y = y * (g * x) + Offset
Lorentzian Peak F With Linear Growth And Offset 2D		y = a / (b + ((x-c)/d)2) y = y * x + Offset
Pseudo-Voight Peak Modified With Linear Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = y * x + Offset
Pseudo-Voight Peak With Linear Growth And Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = y * x + Offset
Pulse Peak With Linear Growth And Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = y * x + Offset
Weibull Peak Modified Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = y * x + Offset
Weibull Peak Modified With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = y * x + Offset
Weibull Peak Shifted With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = y * x + Offset
Weibull Peak With Linear Growth And Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = y * x + Offset
Reciprocal Arnold Cohen Log-Normal Peak Shifted 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = 1.0 / y
Reciprocal Arnold Cohen Two-Parameter Log-Normal Peak Shifted 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = 1.0 / y
Reciprocal Box Lucas A 2D		y = a * (1.0 - bx) y = 1.0 / y
Reciprocal Box Lucas A Shifted 2D		y = a * (1.0 - bx-c) y = 1.0 / y
Reciprocal Box Lucas B 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y
Reciprocal Box Lucas B Shifted 2D		y = a * (1.0 - exp(-b(x-c))) y = 1.0 / y
Reciprocal Box Lucas C 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = 1.0 / y
Reciprocal Box Lucas C shifted 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = 1.0 / y
Reciprocal Extreme Value Peak 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = 1.0 / y
Reciprocal Gaussian Peak 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = 1.0 / y
Reciprocal Gaussian Peak Modified 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = 1.0 / y
Reciprocal Hamilton 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = 1.0 / Vb
Reciprocal Log-Normal Peak 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = 1.0 / y
Reciprocal Log-Normal Peak Modified 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = 1.0 / y
Reciprocal Log-Normal Peak Modified Shifted 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = 1.0 / y
Reciprocal Log-Normal Peak Shifted 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = 1.0 / y
Reciprocal Logistic Peak 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = 1.0 / y
Reciprocal Lorentzian Modified Peak A 2D		y = 1.0 / (1.0 + (x-a)b) y = 1.0 / y
Reciprocal Lorentzian Modified Peak B 2D		y = 1.0 / (a + (x-b)c) y = 1.0 / y
Reciprocal Lorentzian Modified Peak C 2D		y = a / (b + (x-c)d) y = 1.0 / y
Reciprocal Lorentzian Modified Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = 1.0 / y
Reciprocal Lorentzian Modified Peak E 2D		y = 1.0 / (a + ((x-b)/c)d) y = 1.0 / y
Reciprocal Lorentzian Modified Peak F 2D		y = a / (b + ((x-c)/d)f) y = 1.0 / y
Reciprocal Lorentzian Peak A 2D		y = 1.0 / (1.0 + (x-a)2) y = 1.0 / y
Reciprocal Lorentzian Peak B 2D		y = 1.0 / (a + (x-b)2) y = 1.0 / y
Reciprocal Lorentzian Peak C 2D		y = a / (b + (x-c)2) y = 1.0 / y
Reciprocal Lorentzian Peak D 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = 1.0 / y
Reciprocal Lorentzian Peak E 2D		y = 1.0 / (a + ((x-b)/c)2) y = 1.0 / y
Reciprocal Lorentzian Peak F 2D		y = a / (b + ((x-c)/d)2) y = 1.0 / y
Reciprocal Pseudo-Voight Peak 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = 1.0 / y
Reciprocal Pseudo-Voight Peak Modified 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = 1.0 / y
Reciprocal Pulse Peak 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = 1.0 / y
Reciprocal Weibull Peak 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = 1.0 / y
Reciprocal Weibull Peak Modified 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = 1.0 / y
Reciprocal Weibull Peak Modified Shifted 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = 1.0 / y
Reciprocal Weibull Peak Shifted 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = 1.0 / y
Reciprocal Arnold Cohen Log-Normal Peak Shifted With Offset 2D		y = a * (exp(-0.5 * ((ln(x-f)-b)/c)2)) / (d * (x-g)) y = 1.0 / y + Offset
Reciprocal Arnold Cohen Two-Parameter Log-Normal Peak Shifted With Offset 2D		y = exp(-0.5 * ((ln(x-d)-b)/c)2) / (sqrt(2*pi) * c * (x-f)) y = 1.0 / y + Offset
Reciprocal Box Lucas A Shifted With Offset 2D		y = a * (1.0 - bx-c) y = 1.0 / y + Offset
Reciprocal Box Lucas A With Offset 2D		y = a * (1.0 - bx) y = 1.0 / y + Offset
Reciprocal Box Lucas B Shifted With Offset 2D		y = a * (1.0 - exp(-b(x-c))) y = 1.0 / y + Offset
Reciprocal Box Lucas B With Offset 2D		y = a * (1.0 - exp(-bx)) y = 1.0 / y + Offset
Reciprocal Box Lucas C With Offset 2D		y = (a / (a-b)) * (exp(-bx) - exp(-ax)) y = 1.0 / y + Offset
Reciprocal Box Lucas C shifted With Offset 2D		y = (a / (a-b)) * (exp(-b(x-c)) - exp(-a(x-c))) y = 1.0 / y + Offset
Reciprocal Extreme Value Peak With Offset 2D		y = a * exp(-exp(-((x-b)/c))-((x-b)/c)+1.0) y = 1.0 / y + Offset
Reciprocal Gaussian Peak Modified With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)d) y = 1.0 / y + Offset
Reciprocal Gaussian Peak With Offset 2D		y = a * exp(-0.5 * ((x-b)/c)2) y = 1.0 / y + Offset
Reciprocal Hamilton With Offset 2D		Vb = Gb * (I/mu)ln(mu/I)/(B*B) + (Vbmax * I)/(I + sigma_b) Vb = 1.0 / Vb + Offset
Reciprocal Log-Normal Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-e)-b)/c)d) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak Modified With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)d) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak Shifted With Offset 2D		y = a * exp(-0.5 * ((ln(x-d)-b)/c)2) y = 1.0 / y + Offset
Reciprocal Log-Normal Peak With Offset 2D		y = a * exp(-0.5 * ((ln(x)-b)/c)2) y = 1.0 / y + Offset
Reciprocal Logistic Peak With Offset 2D		y = 4a * exp(-1.0 * (x-b) / c) / (1.0 + exp(-1.0 * (x-b) / c)) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)b) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak B With Offset 2D		y = 1.0 / (a + (x-b)c) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak C With Offset 2D		y = a / (b + (x-c)d) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)c) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)d) y = 1.0 / y + Offset
Reciprocal Lorentzian Modified Peak F With Offset 2D		y = a / (b + ((x-c)/d)f) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak A With Offset 2D		y = 1.0 / (1.0 + (x-a)2) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak B With Offset 2D		y = 1.0 / (a + (x-b)2) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak C With Offset 2D		y = a / (b + (x-c)2) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak D With Offset 2D		y = 1.0 / (1.0 + ((x-a)/b)2) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak E With Offset 2D		y = 1.0 / (a + ((x-b)/c)2) y = 1.0 / y + Offset
Reciprocal Lorentzian Peak F With Offset 2D		y = a / (b + ((x-c)/d)2) y = 1.0 / y + Offset
Reciprocal Pseudo-Voight Peak Modified With Offset 2D		y = a * (d * (1/(1+((x-b)/c)e)) + (1-d) * exp(-0.5 * ((x-b)/c)f)) y = 1.0 / y + Offset
Reciprocal Pseudo-Voight Peak With Offset 2D		y = a * (d * (1/(1+((x-b)/c)2)) + (1-d) * exp(-0.5 * ((x-b)/c)2)) y = 1.0 / y + Offset
Reciprocal Pulse Peak With Offset 2D		y = 4a * exp(-(x-b)/c) * (1.0 - exp(-(x-b)/c)) y = 1.0 / y + Offset
Reciprocal Weibull Peak Modified Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-e)/b)/c)d) y = 1.0 / y + Offset
Reciprocal Weibull Peak Modified With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)d) y = 1.0 / y + Offset
Reciprocal Weibull Peak Shifted With Offset 2D		y = a * exp(-0.5 * (ln((x-d)/b)/c)2) y = 1.0 / y + Offset
Reciprocal Weibull Peak With Offset 2D		y = a * exp(-0.5 * (ln(x/b)/c)2) y = 1.0 / y + Offset

2D Polyfunctional

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

2D Polynomial

Cubic 2D		y = a + bx + cx2 + dx3
Linear 2D		y = a + bx
Marc Plante's Custom Quadratic 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a
Quadratic 2D		y = a + bx + cx2
Quartic 2D		y = a + bx + cx2 + dx3 + fx4
Quintic 2D		y = a + bx + cx2 + dx3 + fx4 + gx5
User-Selectable Polynomial 2D		y = user-selectable polynomial
Marc Plante's Custom Quadratic With Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a + Offset
Cubic With Exponential Decay 2D		y = a + bx + cx2 + dx3 y = y / (g * exp(x))
Linear With Exponential Decay 2D		y = a + bx y = y / (d * exp(x))
Marc Plante's Custom Quadratic With Exponential Decay 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y / exp(x)
Quadratic With Exponential Decay 2D		y = a + bx + cx2 y = y / (f * exp(x))
Quartic With Exponential Decay 2D		y = a + bx + cx2 + dx3 + fx4 y = y / (h * exp(x))
Quintic With Exponential Decay 2D		y = a + bx + cx2 + dx3 + fx4 + gx5 y = y / (i * exp(x))
Marc Plante's Custom Quadratic With Exponential Decay And Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y / exp(x) + Offset
Cubic With Exponential Growth 2D		y = a + bx + cx2 + dx3 y = y * (g * exp(x))
Linear With Exponential Growth 2D		y = a + bx y = y * (d * exp(x))
Marc Plante's Custom Quadratic With Exponential Growth 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y * exp(x)
Quadratic With Exponential Growth 2D		y = a + bx + cx2 y = y * (f * exp(x))
Quartic With Exponential Growth 2D		y = a + bx + cx2 + dx3 + fx4 y = y * (h * exp(x))
Quintic With Exponential Growth 2D		y = a + bx + cx2 + dx3 + fx4 + gx5 y = y * (i * exp(x))
Marc Plante's Custom Quadratic With Exponential Growth And Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y * exp(x) + Offset
Inverse Cubic 2D		y = a + bx + cx2 + dx3 y = x / y
Inverse Linear 2D		y = a + bx y = x / y
Inverse Marc Plante's Custom Quadratic 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = x / y
Inverse Quadratic 2D		y = a + bx + cx2 y = x / y
Inverse Quartic 2D		y = a + bx + cx2 + dx3 + fx4 y = x / y
Inverse Quintic 2D		y = a + bx + cx2 + dx3 + fx4 + gx5 y = x / y
Inverse Marc Plante's Custom Quadratic With Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = x / y + Offset
Cubic With Linear Decay 2D		y = a + bx + cx2 + dx3 y = y / (g * x)
Linear With Linear Decay 2D		y = a + bx y = y / (d * x)
Marc Plante's Custom Quadratic With Linear Decay 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y / x
Quadratic With Linear Decay 2D		y = a + bx + cx2 y = y / (f * x)
Quartic With Linear Decay 2D		y = a + bx + cx2 + dx3 + fx4 y = y / (h * x)
Quintic With Linear Decay 2D		y = a + bx + cx2 + dx3 + fx4 + gx5 y = y / (i * x)
Marc Plante's Custom Quadratic With Linear Decay And Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y / x + Offset
Cubic With Linear Growth 2D		y = a + bx + cx2 + dx3 y = y * (g * x) + Offset
Linear With Linear Growth 2D		y = a + bx y = y * (d * x) + Offset
Marc Plante's Custom Quadratic With Linear Growth 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y * x
Quadratic With Linear Growth 2D		y = a + bx + cx2 y = y * (f * x) + Offset
Quartic With Linear Growth 2D		y = a + bx + cx2 + dx3 + fx4 y = y * (h * x) + Offset
Quintic With Linear Growth 2D		y = a + bx + cx2 + dx3 + fx4 + gx5 y = y * (i * x) + Offset
Marc Plante's Custom Quadratic With Linear Growth And Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = y * x + Offset
Reciprocal Cubic 2D		y = a + bx + cx2 + dx3 y = 1.0 / y
Reciprocal Linear 2D		y = a + bx y = 1.0 / y
Reciprocal Marc Plante's Custom Quadratic 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = 1.0 / y
Reciprocal Quadratic 2D		y = a + bx + cx2 y = 1.0 / y
Reciprocal Quartic 2D		y = a + bx + cx2 + dx3 + fx4 y = 1.0 / y
Reciprocal Quintic 2D		y = a + bx + cx2 + dx3 + fx4 + gx5 y = 1.0 / y
Reciprocal Marc Plante's Custom Quadratic With Offset 2D		y = (-b + (b2 - 4 a (c - x))0.5) / 2 / a y = 1.0 / y + Offset

2D Power

Geometric Modified 2D		y = a * x(b/x)
Power A Modified 2D		y = a * bx
Power A Modified Transform 2D		y = a * bcx + d
Power B Modified 2D		y = aln(x)
Power B Modified Transform 2D		y = aln(bx + c)
Power C Modified 2D		y = (a + x)b
Power C Modified Transform 2D		y = (a + bx)c
Power Law With Exponential Cutoff 2D		p(k) = C * k(-T) * exp(-k/K)
Root 2D		y = a(1.0/x)
Simple Power 2D		y = xa
Standard Geometric 2D		y = a * xbx
Standard Power 2D		y = a * xb
X Shifted Power 2D		y = a * (x-b)c
Geometric Modified With Offset 2D		y = a * x(b/x) + Offset
Power A Modified Transform With Offset 2D		y = a * bcx + d + Offset
Power A Modified With Offset 2D		y = a * bx + Offset
Power B Modified Transform With Offset 2D		y = aln(bx + c) + Offset
Power B Modified With Offset 2D		y = aln(x) + Offset
Power C Modified Transform With Offset 2D		y = (a + bx)c + Offset
Power C Modified With Offset 2D		y = (a + x)b + Offset
Power Law With Exponential Cutoff With Offset 2D		p(k) = C * k(-T) * exp(-k/K) + Offset
Root With Offset 2D		y = a(1.0/x) + Offset
Simple Power With Offset 2D		y = xa + Offset
Standard Geometric With Offset 2D		y = a * xbx + Offset
Standard Power With Offset 2D		y = a * xb + Offset
X Shifted Power With Offset 2D		y = a * (x-b)c + Offset
Geometric Modified With Exponential Decay 2D		y = a * x(b/x) y = y / exp(x)
Power A Modified Transform With Exponential Decay 2D		y = a * bcx + d y = y / exp(x)
Power A Modified With Exponential Decay 2D		y = a * bx y = y / exp(x)
Power B Modified Transform With Exponential Decay 2D		y = aln(bx + c) y = y / (f * exp(x))
Power B Modified With Exponential Decay 2D		y = aln(x) y = y / (c * exp(x))
Power C Modified Transform With Exponential Decay 2D		y = (a + bx)c y = y / (f * exp(x))
Power C Modified With Exponential Decay 2D		y = (a + x)b y = y / (d * exp(x))
Power Law With Exponential Cutoff With Exponential Decay 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) / exp(x)
Root With Exponential Decay 2D		y = a(1.0/x) y = y / (c * exp(x))
Simple Power With Exponential Decay 2D		y = xa y = y / (c * exp(x))
Standard Geometric With Exponential Decay 2D		y = a * xbx y = y / exp(x)
Standard Power With Exponential Decay 2D		y = a * xb y = y / exp(x)
X Shifted Power With Exponential Decay 2D		y = a * (x-b)c y = y / exp(x)
Geometric Modified With Exponential Decay And Offset 2D		y = a * x(b/x) y = y / exp(x) + Offset
Power A Modified Transform With Exponential Decay And Offset 2D		y = a * bcx + d y = y / exp(x) + Offset
Power A Modified With Exponential Decay And Offset 2D		y = a * bx y = y / exp(x) + Offset
Power B Modified Transform With Exponential Decay And Offset 2D		y = aln(bx + c) y = y / (g * exp(x)) + Offset
Power B Modified With Exponential Decay And Offset 2D		y = aln(x) y = y / (d * exp(x)) + Offset
Power C Modified Transform With Exponential Decay And Offset 2D		y = (a + bx)c y = y / (g * exp(x)) + Offset
Power C Modified With Exponential Decay And Offset 2D		y = (a + x)b y = y / (f * exp(x)) + Offset
Power Law With Exponential Cutoff With Exponential Decay And Offset 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) / exp(x) + Offset
Root With Exponential Decay And Offset 2D		y = a(1.0/x) y = y / (d * exp(x)) + Offset
Simple Power With Exponential Decay And Offset 2D		y = xa y = y / (d * exp(x)) + Offset
Standard Geometric With Exponential Decay And Offset 2D		y = a * xbx y = y / exp(x) + Offset
Standard Power With Exponential Decay And Offset 2D		y = a * xb y = y / exp(x) + Offset
X Shifted Power With Exponential Decay And Offset 2D		y = a * (x-b)c y = y / exp(x) + Offset
Geometric Modified With Exponential Growth 2D		y = a * x(b/x) y = y * exp(x)
Power A Modified Transform With Exponential Growth 2D		y = a * bcx + d y = y * exp(x)
Power A Modified With Exponential Growth 2D		y = a * bx y = y * exp(x)
Power B Modified Transform With Exponential Growth 2D		y = aln(bx + c) y = y * (f * exp(x))
Power B Modified With Exponential Growth 2D		y = aln(x) y = y * (c * exp(x))
Power C Modified Transform With Exponential Growth 2D		y = (a + bx)c y = y * (f * exp(x))
Power C Modified With Exponential Growth 2D		y = (a + x)b y = y * (d * exp(x))
Power Law With Exponential Cutoff With Exponential Growth 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) * exp(x)
Root With Exponential Growth 2D		y = a(1.0/x) y = y * (c * exp(x))
Simple Power With Exponential Growth 2D		y = xa y = y * (c * exp(x))
Standard Geometric With Exponential Growth 2D		y = a * xbx y = y * exp(x)
Standard Power With Exponential Growth 2D		y = a * xb y = y * exp(x)
X Shifted Power With Exponential Growth 2D		y = a * (x-b)c y = y * exp(x)
Geometric Modified With Exponential Growth And Offset 2D		y = a * x(b/x) y = y * exp(x) + Offset
Power A Modified Transform With Exponential Growth And Offset 2D		y = a * bcx + d y = y * exp(x) + Offset
Power A Modified With Exponential Growth And Offset 2D		y = a * bx y = y * exp(x) + Offset
Power B Modified Transform With Exponential Growth And Offset 2D		y = aln(bx + c) y = y * (g * exp(x)) + Offset
Power B Modified With Exponential Growth And Offset 2D		y = aln(x) y = y * (d * exp(x)) + Offset
Power C Modified Transform With Exponential Growth And Offset 2D		y = (a + bx)c y = y * (g * exp(x)) + Offset
Power C Modified With Exponential Growth And Offset 2D		y = (a + x)b y = y * (f * exp(x)) + Offset
Power Law With Exponential Cutoff With Exponential Growth And Offset 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) * exp(x) + Offset
Root With Exponential Growth And Offset 2D		y = a(1.0/x) y = y * (d * exp(x)) + Offset
Simple Power With Exponential Growth And Offset 2D		y = xa y = y * (d * exp(x)) + Offset
Standard Geometric With Exponential Growth And Offset 2D		y = a * xbx y = y * exp(x) + Offset
Standard Power With Exponential Growth And Offset 2D		y = a * xb y = y * exp(x) + Offset
X Shifted Power With Exponential Growth And Offset 2D		y = a * (x-b)c y = y * exp(x) + Offset
Inverse Geometric Modified 2D		y = a * x(b/x) y = x / y
Inverse Power A Modified 2D		y = a * bx y = x / y
Inverse Power A Modified Transform 2D		y = a * bcx + d y = x / y
Inverse Power B Modified 2D		y = aln(x) y = x / y
Inverse Power B Modified Transform 2D		y = aln(bx + c) y = x / y
Inverse Power C Modified 2D		y = (a + x)b y = x / y
Inverse Power C Modified Transform 2D		y = (a + bx)c y = x / y
Inverse Power Law With Exponential Cutoff 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = x / p(k)
Inverse Root 2D		y = a(1.0/x) y = x / y
Inverse Standard Geometric 2D		y = a * xbx y = x / y
Inverse X Shifted Power 2D		y = a * (x-b)c y = x / y
Inverse Geometric Modified With Offset 2D		y = a * x(b/x) y = x / y + Offset
Inverse Power A Modified Transform With Offset 2D		y = a * bcx + d y = x / y + Offset
Inverse Power A Modified With Offset 2D		y = a * bx y = x / y + Offset
Inverse Power B Modified Transform With Offset 2D		y = aln(bx + c) y = x / y + Offset
Inverse Power B Modified With Offset 2D		y = aln(x) y = x / y + Offset
Inverse Power C Modified Transform With Offset 2D		y = (a + bx)c y = x / y + Offset
Inverse Power C Modified With Offset 2D		y = (a + x)b y = x / y + Offset
Inverse Power Law With Exponential Cutoff With Offset 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = x / p(k) + Offset
Inverse Root With Offset 2D		y = a(1.0/x) y = x / y + Offset
Inverse Standard Geometric With Offset 2D		y = a * xbx y = x / y + Offset
Inverse X Shifted Power With Offset 2D		y = a * (x-b)c y = x / y + Offset
Geometric Modified With Linear Decay 2D		y = a * x(b/x) y = y / x
Power A Modified Transform With Linear Decay 2D		y = a * bcx + d y = y / x
Power A Modified With Linear Decay 2D		y = a * bx y = y / x
Power B Modified Transform With Linear Decay 2D		y = aln(bx + c) y = y / (f * x)
Power B Modified With Linear Decay 2D		y = aln(x) y = y / (c * x)
Power C Modified Transform With Linear Decay 2D		y = (a + bx)c y = y / (f * x)
Power C Modified With Linear Decay 2D		y = (a + x)b y = y / (d * x)
Power Law With Exponential Cutoff With Linear Decay 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) / x
Root With Linear Decay 2D		y = a(1.0/x) y = y / (c * x)
Simple Power With Linear Decay 2D		y = xa y = y / (c * x)
Standard Geometric With Linear Decay 2D		y = a * xbx y = y / x
Standard Power With Linear Decay 2D		y = a * xb y = y / x
X Shifted Power With Linear Decay 2D		y = a * (x-b)c y = y / x
Geometric Modified With Linear Decay And Offset 2D		y = a * x(b/x) y = y / x + Offset
Power A Modified Transform With Linear Decay And Offset 2D		y = a * bcx + d y = y / x + Offset
Power A Modified With Linear Decay And Offset 2D		y = a * bx y = y / x + Offset
Power B Modified Transform With Linear Decay And Offset 2D		y = aln(bx + c) y = y / (g * x) + Offset
Power B Modified With Linear Decay And Offset 2D		y = aln(x) y = y / (d * x) + Offset
Power C Modified Transform With Linear Decay And Offset 2D		y = (a + bx)c y = y / (g * x) + Offset
Power C Modified With Linear Decay And Offset 2D		y = (a + x)b y = y / (f * x) + Offset
Power Law With Exponential Cutoff With Linear Decay And Offset 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) / x + Offset
Root With Linear Decay And Offset 2D		y = a(1.0/x) y = y / (d * x) + Offset
Simple Power With Linear Decay And Offset 2D		y = xa y = y / (d * x) + Offset
Standard Geometric With Linear Decay And Offset 2D		y = a * xbx y = y / x + Offset
Standard Power With Linear Decay And Offset 2D		y = a * xb y = y / x + Offset
X Shifted Power With Linear Decay And Offset 2D		y = a * (x-b)c y = y / x + Offset
Geometric Modified With Linear Growth 2D		y = a * x(b/x) y = y * x
Power A Modified Transform With Linear Growth 2D		y = a * bcx + d y = y * x
Power A Modified With Linear Growth 2D		y = a * bx y = y * x
Power B Modified Transform With Linear Growth 2D		y = aln(bx + c) y = y * (f * x) + Offset
Power B Modified With Linear Growth 2D		y = aln(x) y = y * (c * x) + Offset
Power C Modified Transform With Linear Growth 2D		y = (a + bx)c y = y * (f * x) + Offset
Power C Modified With Linear Growth 2D		y = (a + x)b y = y * (d * x) + Offset
Power Law With Exponential Cutoff With Linear Growth 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) * x
Root With Linear Growth 2D		y = a(1.0/x) y = y * (c * x) + Offset
Simple Power With Linear Growth 2D		y = xa y = y * (c * x) + Offset
Standard Geometric With Linear Growth 2D		y = a * xbx y = y * x
Standard Power With Linear Growth 2D		y = a * xb y = y * x
X Shifted Power With Linear Growth 2D		y = a * (x-b)c y = y * x
Geometric Modified With Linear Growth And Offset 2D		y = a * x(b/x) y = y * x + Offset
Power A Modified Transform With Linear Growth And Offset 2D		y = a * bcx + d y = y * x + Offset
Power A Modified With Linear Growth And Offset 2D		y = a * bx y = y * x + Offset
Power B Modified Transform With Linear Growth And Offset 2D		y = aln(bx + c) y = y * (g * x) + Offset
Power B Modified With Linear Growth And Offset 2D		y = aln(x) y = y * (d * x) + Offset
Power C Modified Transform With Linear Growth And Offset 2D		y = (a + bx)c y = y * (g * x) + Offset
Power C Modified With Linear Growth And Offset 2D		y = (a + x)b y = y * (f * x) + Offset
Power Law With Exponential Cutoff With Linear Growth And Offset 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = p(k) * x + Offset
Root With Linear Growth And Offset 2D		y = a(1.0/x) y = y * (d * x) + Offset
Simple Power With Linear Growth And Offset 2D		y = xa y = y * (d * x) + Offset
Standard Geometric With Linear Growth And Offset 2D		y = a * xbx y = y * x + Offset
Standard Power With Linear Growth And Offset 2D		y = a * xb y = y * x + Offset
X Shifted Power With Linear Growth And Offset 2D		y = a * (x-b)c y = y * x + Offset
Reciprocal Geometric Modified 2D		y = a * x(b/x) y = 1.0 / y
Reciprocal Power A Modified 2D		y = a * bx y = 1.0 / y
Reciprocal Power A Modified Transform 2D		y = a * bcx + d y = 1.0 / y
Reciprocal Power B Modified 2D		y = aln(x) y = 1.0 / y
Reciprocal Power B Modified Transform 2D		y = aln(bx + c) y = 1.0 / y
Reciprocal Power C Modified 2D		y = (a + x)b y = 1.0 / y
Reciprocal Power C Modified Transform 2D		y = (a + bx)c y = 1.0 / y
Reciprocal Power Law With Exponential Cutoff 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = 1.0 / p(k)
Reciprocal Root 2D		y = a(1.0/x) y = 1.0 / y
Reciprocal Simple Power 2D		y = xa y = 1.0 / y
Reciprocal Standard Geometric 2D		y = a * xbx y = 1.0 / y
Reciprocal Standard Power 2D		y = a * xb y = 1.0 / y
Reciprocal X Shifted Power 2D		y = a * (x-b)c y = 1.0 / y
Reciprocal Geometric Modified With Offset 2D		y = a * x(b/x) y = 1.0 / y + Offset
Reciprocal Power A Modified Transform With Offset 2D		y = a * bcx + d y = 1.0 / y + Offset
Reciprocal Power A Modified With Offset 2D		y = a * bx y = 1.0 / y + Offset
Reciprocal Power B Modified Transform With Offset 2D		y = aln(bx + c) y = 1.0 / y + Offset
Reciprocal Power B Modified With Offset 2D		y = aln(x) y = 1.0 / y + Offset
Reciprocal Power C Modified Transform With Offset 2D		y = (a + bx)c y = 1.0 / y + Offset
Reciprocal Power C Modified With Offset 2D		y = (a + x)b y = 1.0 / y + Offset
Reciprocal Power Law With Exponential Cutoff With Offset 2D		p(k) = C * k(-T) * exp(-k/K) p(k) = 1.0 / p(k) + Offset
Reciprocal Root With Offset 2D		y = a(1.0/x) y = 1.0 / y + Offset
Reciprocal Simple Power With Offset 2D		y = xa y = 1.0 / y + Offset
Reciprocal Standard Geometric With Offset 2D		y = a * xbx y = 1.0 / y + Offset
Reciprocal Standard Power With Offset 2D		y = a * xb y = 1.0 / y + Offset
Reciprocal X Shifted Power With Offset 2D		y = a * (x-b)c y = 1.0 / y + Offset

2D Rational

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

2D Sigmoidal

BET Sigmoidal A 2D		y = x / (a + bx - (a+b)x2)
BET Sigmoidal B 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2)
Boltzmann Sigmoid 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b
Chapman 2D		y = a * (1.0 - exp(-bx))c
Don Levin Sigmoid 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3))
Five-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)b)e
Four-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)b)
Generalised Logistic 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T   [web citation]
Gompertz A 2D		y = a * exp(-exp(b - cx))
Gompertz B 2D		y = a * exp(-exp((x-b)/c))
Gompertz C 2D		y = a * exp(b * exp(c * x))
Hill 2D		y = axb / (cb + xb)
Janoschek Growth 2D		w = a - (1.0 - exp(-b * tc))   [web citation]
Janoschek Growth Modified 2D		w = a - (a - w0) * (1.0 - exp(-b * tc))   [web citation]
Logistic A 2D		y = a / (1.0 + b*exp(-cx))
Logistic B 2D		y = a / (1.0 + (x/b)c)
Magnetic Saturation 2D		y = ax * (1.0 + b*exp(cx))
Morgan-Mercer-Flodin (MMF) 2D		y = (a * b + c * xd) / (b + xd)
Peters-Baskin Step-Stool: y (1) 2D		y = ln(c + exp(b*d*x)) / d   [web citation]
Peters-Baskin Step-Stool: yI (2) 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1   [web citation]
Peters-Baskin Step-Stool: yII (3) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1   [web citation]
Peters-Baskin Step-Stool: yIII (6) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2   [web citation]
Peters-Baskin Step-Stool: yIV (9) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0   [web citation]
Peters-Baskin Step-Stool: yV (10) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q   [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q   [web citation]
Richards 2D		y = 1.0 / (a + b * e(c*x))d
Sigmoid A 2D		y = 1.0 / (1.0 + exp(-a(x-b)))
Sigmoid A Modified 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c
Sigmoid B 2D		y = a / (1.0 + exp(-(x-b)/c))
Sigmoid B Modified 2D		y = a / (1.0 + exp(-(x-b)/c))d
Weibull 2D		y = a - b*exp(-cxd)
Weibull CDF 2D		y = 1.0 - exp(-(x/b)a)
Weibull PDF 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a)
BET Sigmoidal A With Offset 2D		y = x / (a + bx - (a+b)x2) + Offset
BET Sigmoidal B With Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) + Offset
Chapman With Offset 2D		y = a * (1.0 - exp(-bx))c + Offset
Don Levin Sigmoid With Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) + Offset
Gompertz A With Offset 2D		y = a * exp(-exp(b - cx)) + Offset
Gompertz B With Offset 2D		y = a * exp(-exp((x-b)/c)) + Offset
Gompertz C With Offset 2D		y = a * exp(b * exp(c * x)) + Offset
Hill With Offset 2D		y = axb / (cb + xb) + Offset
Logistic A With Offset 2D		y = a / (1.0 + b*exp(-cx)) + Offset
Logistic B With Offset 2D		y = a / (1.0 + (x/b)c) + Offset
Magnetic Saturation With Offset 2D		y = ax * (1.0 + b*exp(cx)) + Offset
Morgan-Mercer-Flodin (MMF) With Offset 2D		y = (a * b + c * xd) / (b + xd) + Offset
Peters-Baskin Step-Stool: y (1) With Offset 2D		y = ln(c + exp(b*d*x)) / d + Offset   [web citation]
Peters-Baskin Step-Stool: yI (2) With Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 + Offset   [web citation]
Peters-Baskin Step-Stool: yII (3) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 + Offset   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 + Offset   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + Offset   [web citation]
Richards With Offset 2D		y = 1.0 / (a + b * e(c*x))d + Offset
Sigmoid A Modified With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c + Offset
Sigmoid A With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) + Offset
Sigmoid B Modified With Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d + Offset
Sigmoid B With Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) + Offset
Weibull CDF With Offset 2D		y = 1.0 - exp(-(x/b)a) + Offset
Weibull PDF With Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) + Offset
BET Sigmoidal A With Exponential Decay 2D		y = x / (a + bx - (a+b)x2) y = y / (d * exp(x))
BET Sigmoidal B With Exponential Decay 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y / exp(x)
Boltzmann Sigmoid With Exponential Decay 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y / (g * exp(x))
Chapman With Exponential Decay 2D		y = a * (1.0 - exp(-bx))c y = y / exp(x)
Don Levin Sigmoid With Exponential Decay 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (m * exp(x))
Five-Parameter Logistic With Exponential Decay 2D		y = d + (a-d) / (1.0 + (x/c)b)e y = y / (h * exp(x))
Four-Parameter Logistic With Exponential Decay 2D		y = d + (a-d) / (1.0 + (x/c)b) y = y / (g * exp(x))
Generalised Logistic With Exponential Decay 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T y = y / (h * exp(x))   [web citation]
Gompertz A With Exponential Decay 2D		y = a * exp(-exp(b - cx)) y = y / exp(x)
Gompertz B With Exponential Decay 2D		y = a * exp(-exp((x-b)/c)) y = y / exp(x)
Gompertz C With Exponential Decay 2D		y = a * exp(b * exp(c * x)) y = y / exp(x)
Hill With Exponential Decay 2D		y = axb / (cb + xb) y = y / (f * exp(x))
Janoschek Growth Modified With Exponential Decay 2D		w = a - (a - w0) * (1.0 - exp(-b * tc)) w = w / (g * exp(x))   [web citation]
Janoschek Growth With Exponential Decay 2D		w = a - (1.0 - exp(-b * tc)) w = w / (f * exp(x))   [web citation]
Logistic A With Exponential Decay 2D		y = a / (1.0 + b*exp(-cx)) y = y / exp(x)
Logistic B With Exponential Decay 2D		y = a / (1.0 + (x/b)c) y = y / exp(x)
Magnetic Saturation With Exponential Decay 2D		y = ax * (1.0 + b*exp(cx)) y = y / exp(x)
Morgan-Mercer-Flodin (MMF) With Exponential Decay 2D		y = (a * b + c * xd) / (b + xd) y = y / (g * exp(x))
Peters-Baskin Step-Stool: y (1) With Exponential Decay 2D		y = ln(c + exp(b*d*x)) / d y = y / exp(x)   [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Decay 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI / (f * exp(x))   [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII / (g * exp(x))   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII / (i * exp(x))   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (i * exp(x))   [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Exponential Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q yIV = yIV / (k * exp(x))   [web citation]
Peters-Baskin Step-Stool: yV (10) With Exponential Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV / (j * exp(x))   [web citation]
Richards With Exponential Decay 2D		y = 1.0 / (a + b * e(c*x))d y = y / (g * exp(x))
Sigmoid A Modified With Exponential Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y / (f * exp(x))
Sigmoid A With Exponential Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (d * exp(x))
Sigmoid B Modified With Exponential Decay 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y / exp(x)
Sigmoid B With Exponential Decay 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / exp(x)
Weibull CDF With Exponential Decay 2D		y = 1.0 - exp(-(x/b)a) y = y / (d * exp(x))
Weibull PDF With Exponential Decay 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y / (d * exp(x))
Weibull With Exponential Decay 2D		y = a - b*exp(-cxd) y = y / (g * exp(x))
BET Sigmoidal A With Exponential Decay And Offset 2D		y = x / (a + bx - (a+b)x2) y = y / (f * exp(x)) + Offset
BET Sigmoidal B With Exponential Decay And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y / exp(x) + Offset
Chapman With Exponential Decay And Offset 2D		y = a * (1.0 - exp(-bx))c y = y / exp(x) + Offset
Don Levin Sigmoid With Exponential Decay And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (n * exp(x)) + Offset
Gompertz A With Exponential Decay And Offset 2D		y = a * exp(-exp(b - cx)) y = y / exp(x) + Offset
Gompertz B With Exponential Decay And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y / exp(x) + Offset
Gompertz C With Exponential Decay And Offset 2D		y = a * exp(b * exp(c * x)) y = y / exp(x) + Offset
Hill With Exponential Decay And Offset 2D		y = axb / (cb + xb) y = y / (g * exp(x)) + Offset
Logistic A With Exponential Decay And Offset 2D		y = a / (1.0 + b*exp(-cx)) y = y / exp(x) + Offset
Logistic B With Exponential Decay And Offset 2D		y = a / (1.0 + (x/b)c) y = y / exp(x) + Offset
Magnetic Saturation With Exponential Decay And Offset 2D		y = ax * (1.0 + b*exp(cx)) y = y / exp(x) + Offset
Morgan-Mercer-Flodin (MMF) With Exponential Decay And Offset 2D		y = (a * b + c * xd) / (b + xd) y = y / (h * exp(x)) + Offset
Peters-Baskin Step-Stool: y (1) With Exponential Decay And Offset 2D		y = ln(c + exp(b*d*x)) / d y = y / exp(x) + Offset   [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Decay And Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI / (g * exp(x)) + Offset   [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Decay And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII / (h * exp(x)) + Offset   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Decay And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII / (j * exp(x)) + Offset   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Decay And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (j * exp(x)) + Offset   [web citation]
Richards With Exponential Decay And Offset 2D		y = 1.0 / (a + b * e(c*x))d y = y / (h * exp(x)) + Offset
Sigmoid A Modified With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y / (g * exp(x)) + Offset
Sigmoid A With Exponential Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (f * exp(x)) + Offset
Sigmoid B Modified With Exponential Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y / exp(x) + Offset
Sigmoid B With Exponential Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / exp(x) + Offset
Weibull CDF With Exponential Decay And Offset 2D		y = 1.0 - exp(-(x/b)a) y = y / (f * exp(x)) + Offset
Weibull PDF With Exponential Decay And Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y / (f * exp(x)) + Offset
BET Sigmoidal A With Exponential Growth 2D		y = x / (a + bx - (a+b)x2) y = y * (d * exp(x))
BET Sigmoidal B With Exponential Growth 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y * exp(x)
Boltzmann Sigmoid With Exponential Growth 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y * (g * exp(x))
Chapman With Exponential Growth 2D		y = a * (1.0 - exp(-bx))c y = y * exp(x)
Don Levin Sigmoid With Exponential Growth 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (m * exp(x))
Five-Parameter Logistic With Exponential Growth 2D		y = d + (a-d) / (1.0 + (x/c)b)e y = y * (h * exp(x))
Four-Parameter Logistic With Exponential Growth 2D		y = d + (a-d) / (1.0 + (x/c)b) y = y * (g * exp(x))
Generalised Logistic With Exponential Growth 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T y = y * (h * exp(x))   [web citation]
Gompertz A With Exponential Growth 2D		y = a * exp(-exp(b - cx)) y = y * exp(x)
Gompertz B With Exponential Growth 2D		y = a * exp(-exp((x-b)/c)) y = y * exp(x)
Gompertz C With Exponential Growth 2D		y = a * exp(b * exp(c * x)) y = y * exp(x)
Hill With Exponential Growth 2D		y = axb / (cb + xb) y = y * (f * exp(x))
Janoschek Growth Modified With Exponential Growth 2D		w = a - (a - w0) * (1.0 - exp(-b * tc)) w = w * (g * exp(x))   [web citation]
Janoschek Growth With Exponential Growth 2D		w = a - (1.0 - exp(-b * tc)) w = w * (f * exp(x))   [web citation]
Logistic A With Exponential Growth 2D		y = a / (1.0 + b*exp(-cx)) y = y * exp(x)
Logistic B With Exponential Growth 2D		y = a / (1.0 + (x/b)c) y = y * exp(x)
Magnetic Saturation With Exponential Growth 2D		y = ax * (1.0 + b*exp(cx)) y = y * exp(x)
Morgan-Mercer-Flodin (MMF) With Exponential Growth 2D		y = (a * b + c * xd) / (b + xd) y = y * (g * exp(x))
Peters-Baskin Step-Stool: y (1) With Exponential Growth 2D		y = ln(c + exp(b*d*x)) / d y = y * exp(x)   [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Growth 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI * (f * exp(x))   [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII * (g * exp(x))   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII * (i * exp(x))   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV * (i * exp(x))   [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Exponential Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q yIV = yIV * (k * exp(x))   [web citation]
Peters-Baskin Step-Stool: yV (10) With Exponential Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV * (j * exp(x))   [web citation]
Richards With Exponential Growth 2D		y = 1.0 / (a + b * e(c*x))d y = y * (g * exp(x))
Sigmoid A Modified With Exponential Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y * (f * exp(x))
Sigmoid A With Exponential Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (d * exp(x))
Sigmoid B Modified With Exponential Growth 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y * exp(x)
Sigmoid B With Exponential Growth 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * exp(x)
Weibull CDF With Exponential Growth 2D		y = 1.0 - exp(-(x/b)a) y = y * (d * exp(x))
Weibull PDF With Exponential Growth 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y * (d * exp(x))
Weibull With Exponential Growth 2D		y = a - b*exp(-cxd) y = y * (g * exp(x))
BET Sigmoidal A With Exponential Growth And Offset 2D		y = x / (a + bx - (a+b)x2) y = y * (f * exp(x)) + Offset
BET Sigmoidal B With Exponential Growth And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y * exp(x) + Offset
Chapman With Exponential Growth And Offset 2D		y = a * (1.0 - exp(-bx))c y = y * exp(x) + Offset
Don Levin Sigmoid With Exponential Growth And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (n * exp(x)) + Offset
Gompertz A With Exponential Growth And Offset 2D		y = a * exp(-exp(b - cx)) y = y * exp(x) + Offset
Gompertz B With Exponential Growth And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y * exp(x) + Offset
Gompertz C With Exponential Growth And Offset 2D		y = a * exp(b * exp(c * x)) y = y * exp(x) + Offset
Hill With Exponential Growth And Offset 2D		y = axb / (cb + xb) y = y * (g * exp(x)) + Offset
Logistic A With Exponential Growth And Offset 2D		y = a / (1.0 + b*exp(-cx)) y = y * exp(x) + Offset
Logistic B With Exponential Growth And Offset 2D		y = a / (1.0 + (x/b)c) y = y * exp(x) + Offset
Magnetic Saturation With Exponential Growth And Offset 2D		y = ax * (1.0 + b*exp(cx)) y = y * exp(x) + Offset
Morgan-Mercer-Flodin (MMF) With Exponential Growth And Offset 2D		y = (a * b + c * xd) / (b + xd) y = y * (h * exp(x)) + Offset
Peters-Baskin Step-Stool: y (1) With Exponential Growth And Offset 2D		y = ln(c + exp(b*d*x)) / d y = y * exp(x) + Offset   [web citation]
Peters-Baskin Step-Stool: yI (2) With Exponential Growth And Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI * (g * exp(x)) + Offset   [web citation]
Peters-Baskin Step-Stool: yII (3) With Exponential Growth And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII * (h * exp(x)) + Offset   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Exponential Growth And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII * (j * exp(x)) + Offset   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Exponential Growth And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV * (j * exp(x)) + Offset   [web citation]
Richards With Exponential Growth And Offset 2D		y = 1.0 / (a + b * e(c*x))d y = y * (h * exp(x)) + Offset
Sigmoid A Modified With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y * (g * exp(x)) + Offset
Sigmoid A With Exponential Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (f * exp(x)) + Offset
Sigmoid B Modified With Exponential Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y * exp(x) + Offset
Sigmoid B With Exponential Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * exp(x) + Offset
Weibull CDF With Exponential Growth And Offset 2D		y = 1.0 - exp(-(x/b)a) y = y * (f * exp(x)) + Offset
Weibull PDF With Exponential Growth And Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y * (f * exp(x)) + Offset
Inverse Boltzmann Sigmoid 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = x / y
Inverse Chapman 2D		y = a * (1.0 - exp(-bx))c y = x / y
Inverse Don Levin Sigmoid 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = x / y
Inverse Five-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)b)e y = x / y
Inverse Four-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)b) y = x / y
Inverse Generalised Logistic 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T y = x / y   [web citation]
Inverse Gompertz A 2D		y = a * exp(-exp(b - cx)) y = x / y
Inverse Gompertz B 2D		y = a * exp(-exp((x-b)/c)) y = x / y
Inverse Gompertz C 2D		y = a * exp(b * exp(c * x)) y = x / y
Inverse Hill 2D		y = axb / (cb + xb) y = x / y
Inverse Janoschek Growth 2D		w = a - (1.0 - exp(-b * tc)) w = x / w   [web citation]
Inverse Janoschek Growth Modified 2D		w = a - (a - w0) * (1.0 - exp(-b * tc)) w = x / w   [web citation]
Inverse Logistic A 2D		y = a / (1.0 + b*exp(-cx)) y = x / y
Inverse Logistic B 2D		y = a / (1.0 + (x/b)c) y = x / y
Inverse Morgan-Mercer-Flodin (MMF) 2D		y = (a * b + c * xd) / (b + xd) y = x / y
Inverse Peters-Baskin Step-Stool: y (1) 2D		y = ln(c + exp(b*d*x)) / d y = x / y   [web citation]
Inverse Peters-Baskin Step-Stool: yI (2) 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = x / yI   [web citation]
Inverse Peters-Baskin Step-Stool: yII (3) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = x / yII   [web citation]
Inverse Peters-Baskin Step-Stool: yIII (6) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = x / yIII   [web citation]
Inverse Peters-Baskin Step-Stool: yIV (9) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = x / yIV   [web citation]
Inverse Peters-Baskin Step-Stool: yV (10) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = x / yIV   [web citation]
Inverse Peters-Baskin Step-Stool: yV (10) Scaled 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q yIV = x / yIV   [web citation]
Inverse Richards 2D		y = 1.0 / (a + b * e(c*x))d y = x / y
Inverse Sigmoid A 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = x / y
Inverse Sigmoid A Modified 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = x / y
Inverse Sigmoid B 2D		y = a / (1.0 + exp(-(x-b)/c)) y = x / y
Inverse Sigmoid B Modified 2D		y = a / (1.0 + exp(-(x-b)/c))d y = x / y
Inverse Weibull 2D		y = a - b*exp(-cxd) y = x / y
Inverse Weibull CDF 2D		y = 1.0 - exp(-(x/b)a) y = x / y
Inverse Weibull PDF 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = x / y
Inverse Chapman With Offset 2D		y = a * (1.0 - exp(-bx))c y = x / y + Offset
Inverse Don Levin Sigmoid With Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = x / y + Offset
Inverse Gompertz A With Offset 2D		y = a * exp(-exp(b - cx)) y = x / y + Offset
Inverse Gompertz B With Offset 2D		y = a * exp(-exp((x-b)/c)) y = x / y + Offset
Inverse Gompertz C With Offset 2D		y = a * exp(b * exp(c * x)) y = x / y + Offset
Inverse Hill With Offset 2D		y = axb / (cb + xb) y = x / y + Offset
Inverse Logistic A With Offset 2D		y = a / (1.0 + b*exp(-cx)) y = x / y + Offset
Inverse Logistic B With Offset 2D		y = a / (1.0 + (x/b)c) y = x / y + Offset
Inverse Morgan-Mercer-Flodin (MMF) With Offset 2D		y = (a * b + c * xd) / (b + xd) y = x / y + Offset
Inverse Peters-Baskin Step-Stool: y (1) With Offset 2D		y = ln(c + exp(b*d*x)) / d y = x / y + Offset   [web citation]
Inverse Peters-Baskin Step-Stool: yI (2) With Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = x / yI + Offset   [web citation]
Inverse Peters-Baskin Step-Stool: yII (3) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = x / yII + Offset   [web citation]
Inverse Peters-Baskin Step-Stool: yIII (6) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = x / yIII + Offset   [web citation]
Inverse Peters-Baskin Step-Stool: yIV (9) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = x / yIV + Offset   [web citation]
Inverse Richards With Offset 2D		y = 1.0 / (a + b * e(c*x))d y = x / y + Offset
Inverse Sigmoid A Modified With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = x / y + Offset
Inverse Sigmoid A With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = x / y + Offset
Inverse Sigmoid B Modified With Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d y = x / y + Offset
Inverse Sigmoid B With Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = x / y + Offset
Inverse Weibull CDF With Offset 2D		y = 1.0 - exp(-(x/b)a) y = x / y + Offset
Inverse Weibull PDF With Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = x / y + Offset
BET Sigmoidal A With Linear Decay 2D		y = x / (a + bx - (a+b)x2) y = y / (d * x)
BET Sigmoidal B With Linear Decay 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y / x
Boltzmann Sigmoid With Linear Decay 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y / (g * x)
Chapman With Linear Decay 2D		y = a * (1.0 - exp(-bx))c y = y / x
Don Levin Sigmoid With Linear Decay 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (m * x)
Five-Parameter Logistic With Linear Decay 2D		y = d + (a-d) / (1.0 + (x/c)b)e y = y / (h * x)
Four-Parameter Logistic With Linear Decay 2D		y = d + (a-d) / (1.0 + (x/c)b) y = y / (g * x)
Generalised Logistic With Linear Decay 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T y = y / (h * x)   [web citation]
Gompertz A With Linear Decay 2D		y = a * exp(-exp(b - cx)) y = y / x
Gompertz B With Linear Decay 2D		y = a * exp(-exp((x-b)/c)) y = y / x
Gompertz C With Linear Decay 2D		y = a * exp(b * exp(c * x)) y = y / x
Hill With Linear Decay 2D		y = axb / (cb + xb) y = y / (f * x)
Janoschek Growth Modified With Linear Decay 2D		w = a - (a - w0) * (1.0 - exp(-b * tc)) w = w / (g * x)   [web citation]
Janoschek Growth With Linear Decay 2D		w = a - (1.0 - exp(-b * tc)) w = w / (f * x)   [web citation]
Logistic A With Linear Decay 2D		y = a / (1.0 + b*exp(-cx)) y = y / x
Logistic B With Linear Decay 2D		y = a / (1.0 + (x/b)c) y = y / x
Magnetic Saturation With Linear Decay 2D		y = ax * (1.0 + b*exp(cx)) y = y / x
Morgan-Mercer-Flodin (MMF) With Linear Decay 2D		y = (a * b + c * xd) / (b + xd) y = y / (g * x)
Peters-Baskin Step-Stool: y (1) With Linear Decay 2D		y = ln(c + exp(b*d*x)) / d y = y / x   [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Decay 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI / (f * x)   [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII / (g * x)   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII / (i * x)   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (i * x)   [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Linear Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q yIV = yIV / (k * x)   [web citation]
Peters-Baskin Step-Stool: yV (10) With Linear Decay 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV / (j * x)   [web citation]
Richards With Linear Decay 2D		y = 1.0 / (a + b * e(c*x))d y = y / (g * x)
Sigmoid A Modified With Linear Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y / (f * x)
Sigmoid A With Linear Decay 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (d * x)
Sigmoid B Modified With Linear Decay 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y / x
Sigmoid B With Linear Decay 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / x
Weibull CDF With Linear Decay 2D		y = 1.0 - exp(-(x/b)a) y = y / (d * x)
Weibull PDF With Linear Decay 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y / (d * x)
Weibull With Linear Decay 2D		y = a - b*exp(-cxd) y = y / (g * x)
BET Sigmoidal A With Linear Decay And Offset 2D		y = x / (a + bx - (a+b)x2) y = y / (f * x) + Offset
BET Sigmoidal B With Linear Decay And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y / x + Offset
Chapman With Linear Decay And Offset 2D		y = a * (1.0 - exp(-bx))c y = y / x + Offset
Don Levin Sigmoid With Linear Decay And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y / (n * x) + Offset
Gompertz A With Linear Decay And Offset 2D		y = a * exp(-exp(b - cx)) y = y / x + Offset
Gompertz B With Linear Decay And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y / x + Offset
Gompertz C With Linear Decay And Offset 2D		y = a * exp(b * exp(c * x)) y = y / x + Offset
Hill With Linear Decay And Offset 2D		y = axb / (cb + xb) y = y / (g * x) + Offset
Logistic A With Linear Decay And Offset 2D		y = a / (1.0 + b*exp(-cx)) y = y / x + Offset
Logistic B With Linear Decay And Offset 2D		y = a / (1.0 + (x/b)c) y = y / x + Offset
Magnetic Saturation With Linear Decay And Offset 2D		y = ax * (1.0 + b*exp(cx)) y = y / x + Offset
Morgan-Mercer-Flodin (MMF) With Linear Decay And Offset 2D		y = (a * b + c * xd) / (b + xd) y = y / (h * x) + Offset
Peters-Baskin Step-Stool: y (1) With Linear Decay And Offset 2D		y = ln(c + exp(b*d*x)) / d y = y / x + Offset   [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Decay And Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI / (g * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Decay And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII / (h * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Decay And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII / (j * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Decay And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV / (j * x) + Offset   [web citation]
Richards With Linear Decay And Offset 2D		y = 1.0 / (a + b * e(c*x))d y = y / (h * x) + Offset
Sigmoid A Modified With Linear Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y / (g * x) + Offset
Sigmoid A With Linear Decay And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y / (f * x) + Offset
Sigmoid B Modified With Linear Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y / x + Offset
Sigmoid B With Linear Decay And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y / x + Offset
Weibull CDF With Linear Decay And Offset 2D		y = 1.0 - exp(-(x/b)a) y = y / (f * x) + Offset
Weibull PDF With Linear Decay And Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y / (f * x) + Offset
BET Sigmoidal A With Linear Growth 2D		y = x / (a + bx - (a+b)x2) y = y * (d * x) + Offset
BET Sigmoidal B With Linear Growth 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y * x
Boltzmann Sigmoid With Linear Growth 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = y * (g * x) + Offset
Chapman With Linear Growth 2D		y = a * (1.0 - exp(-bx))c y = y * x
Don Levin Sigmoid With Linear Growth 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (m * x) + Offset
Five-Parameter Logistic With Linear Growth 2D		y = d + (a-d) / (1.0 + (x/c)b)e y = y * (h * x) + Offset
Four-Parameter Logistic With Linear Growth 2D		y = d + (a-d) / (1.0 + (x/c)b) y = y * (g * x) + Offset
Generalised Logistic With Linear Growth 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T y = y * (h * x) + Offset   [web citation]
Gompertz A With Linear Growth 2D		y = a * exp(-exp(b - cx)) y = y * x
Gompertz B With Linear Growth 2D		y = a * exp(-exp((x-b)/c)) y = y * x
Gompertz C With Linear Growth 2D		y = a * exp(b * exp(c * x)) y = y * x
Hill With Linear Growth 2D		y = axb / (cb + xb) y = y * (f * x) + Offset
Janoschek Growth Modified With Linear Growth 2D		w = a - (a - w0) * (1.0 - exp(-b * tc)) w = w * (g * x) + Offset   [web citation]
Janoschek Growth With Linear Growth 2D		w = a - (1.0 - exp(-b * tc)) w = w * (f * x) + Offset   [web citation]
Logistic A With Linear Growth 2D		y = a / (1.0 + b*exp(-cx)) y = y * x
Logistic B With Linear Growth 2D		y = a / (1.0 + (x/b)c) y = y * x
Magnetic Saturation With Linear Growth 2D		y = ax * (1.0 + b*exp(cx)) y = y * x
Morgan-Mercer-Flodin (MMF) With Linear Growth 2D		y = (a * b + c * xd) / (b + xd) y = y * (g * x) + Offset
Peters-Baskin Step-Stool: y (1) With Linear Growth 2D		y = ln(c + exp(b*d*x)) / d y = y * x   [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Growth 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI * (f * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII * (g * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII * (i * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV * (i * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yV (10) Scaled With Linear Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q yIV = yIV * (k * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yV (10) With Linear Growth 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = yIV * (j * x) + Offset   [web citation]
Richards With Linear Growth 2D		y = 1.0 / (a + b * e(c*x))d y = y * (g * x) + Offset
Sigmoid A Modified With Linear Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y * (f * x) + Offset
Sigmoid A With Linear Growth 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (d * x) + Offset
Sigmoid B Modified With Linear Growth 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y * x
Sigmoid B With Linear Growth 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * x
Weibull CDF With Linear Growth 2D		y = 1.0 - exp(-(x/b)a) y = y * (d * x) + Offset
Weibull PDF With Linear Growth 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y * (d * x) + Offset
Weibull With Linear Growth 2D		y = a - b*exp(-cxd) y = y * (g * x) + Offset
BET Sigmoidal A With Linear Growth And Offset 2D		y = x / (a + bx - (a+b)x2) y = y * (f * x) + Offset
BET Sigmoidal B With Linear Growth And Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = y * x + Offset
Chapman With Linear Growth And Offset 2D		y = a * (1.0 - exp(-bx))c y = y * x + Offset
Don Levin Sigmoid With Linear Growth And Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = y * (n * x) + Offset
Gompertz A With Linear Growth And Offset 2D		y = a * exp(-exp(b - cx)) y = y * x + Offset
Gompertz B With Linear Growth And Offset 2D		y = a * exp(-exp((x-b)/c)) y = y * x + Offset
Gompertz C With Linear Growth And Offset 2D		y = a * exp(b * exp(c * x)) y = y * x + Offset
Hill With Linear Growth And Offset 2D		y = axb / (cb + xb) y = y * (g * x) + Offset
Logistic A With Linear Growth And Offset 2D		y = a / (1.0 + b*exp(-cx)) y = y * x + Offset
Logistic B With Linear Growth And Offset 2D		y = a / (1.0 + (x/b)c) y = y * x + Offset
Magnetic Saturation With Linear Growth And Offset 2D		y = ax * (1.0 + b*exp(cx)) y = y * x + Offset
Morgan-Mercer-Flodin (MMF) With Linear Growth And Offset 2D		y = (a * b + c * xd) / (b + xd) y = y * (h * x) + Offset
Peters-Baskin Step-Stool: y (1) With Linear Growth And Offset 2D		y = ln(c + exp(b*d*x)) / d y = y * x + Offset   [web citation]
Peters-Baskin Step-Stool: yI (2) With Linear Growth And Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = yI * (g * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yII (3) With Linear Growth And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = yII * (h * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yIII (6) With Linear Growth And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = yIII * (j * x) + Offset   [web citation]
Peters-Baskin Step-Stool: yIV (9) With Linear Growth And Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = yIV * (j * x) + Offset   [web citation]
Richards With Linear Growth And Offset 2D		y = 1.0 / (a + b * e(c*x))d y = y * (h * x) + Offset
Sigmoid A Modified With Linear Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = y * (g * x) + Offset
Sigmoid A With Linear Growth And Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = y * (f * x) + Offset
Sigmoid B Modified With Linear Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d y = y * x + Offset
Sigmoid B With Linear Growth And Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = y * x + Offset
Weibull CDF With Linear Growth And Offset 2D		y = 1.0 - exp(-(x/b)a) y = y * (f * x) + Offset
Weibull PDF With Linear Growth And Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = y * (f * x) + Offset
Reciprocal BET Sigmoidal A 2D		y = x / (a + bx - (a+b)x2) y = 1.0 / y
Reciprocal BET Sigmoidal B 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = 1.0 / y
Reciprocal Boltzmann Sigmoid 2D		y = (a - b) / (1.0 + exp((x-c)/d)) + b y = 1.0 / y
Reciprocal Chapman 2D		y = a * (1.0 - exp(-bx))c y = 1.0 / y
Reciprocal Don Levin Sigmoid 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = 1.0 / y
Reciprocal Five-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)b)e y = 1.0 / y
Reciprocal Four-Parameter Logistic 2D		y = d + (a-d) / (1.0 + (x/c)b) y = 1.0 / y
Reciprocal Generalised Logistic 2D		y = A + C / (1 + T * exp(-B * (x - M)))1/T y = 1.0 / y   [web citation]
Reciprocal Gompertz A 2D		y = a * exp(-exp(b - cx)) y = 1.0 / y
Reciprocal Gompertz B 2D		y = a * exp(-exp((x-b)/c)) y = 1.0 / y
Reciprocal Gompertz C 2D		y = a * exp(b * exp(c * x)) y = 1.0 / y
Reciprocal Hill 2D		y = axb / (cb + xb) y = 1.0 / y
Reciprocal Janoschek Growth 2D		w = a - (1.0 - exp(-b * tc)) w = 1.0 / w   [web citation]
Reciprocal Janoschek Growth Modified 2D		w = a - (a - w0) * (1.0 - exp(-b * tc)) w = 1.0 / w   [web citation]
Reciprocal Logistic A 2D		y = a / (1.0 + b*exp(-cx)) y = 1.0 / y
Reciprocal Logistic B 2D		y = a / (1.0 + (x/b)c) y = 1.0 / y
Reciprocal Magnetic Saturation 2D		y = ax * (1.0 + b*exp(cx)) y = 1.0 / y
Reciprocal Morgan-Mercer-Flodin (MMF) 2D		y = (a * b + c * xd) / (b + xd) y = 1.0 / y
Reciprocal Peters-Baskin Step-Stool: y (1) 2D		y = ln(c + exp(b*d*x)) / d y = 1.0 / y   [web citation]
Reciprocal Peters-Baskin Step-Stool: yI (2) 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = 1.0 / yI   [web citation]
Reciprocal Peters-Baskin Step-Stool: yII (3) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = 1.0 / yII   [web citation]
Reciprocal Peters-Baskin Step-Stool: yIII (6) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = 1.0 / yIII   [web citation]
Reciprocal Peters-Baskin Step-Stool: yIV (9) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = 1.0 / yIV   [web citation]
Reciprocal Peters-Baskin Step-Stool: yV (10) 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 + q yIV = 1.0 / yIV   [web citation]
Reciprocal Peters-Baskin Step-Stool: yV (10) Scaled 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = scale * (yIII - yIII,0 )+ q yIV = 1.0 / yIV   [web citation]
Reciprocal Richards 2D		y = 1.0 / (a + b * e(c*x))d y = 1.0 / y
Reciprocal Sigmoid A 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = 1.0 / y
Reciprocal Sigmoid A Modified 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = 1.0 / y
Reciprocal Sigmoid B 2D		y = a / (1.0 + exp(-(x-b)/c)) y = 1.0 / y
Reciprocal Sigmoid B Modified 2D		y = a / (1.0 + exp(-(x-b)/c))d y = 1.0 / y
Reciprocal Weibull 2D		y = a - b*exp(-cxd) y = 1.0 / y
Reciprocal Weibull CDF 2D		y = 1.0 - exp(-(x/b)a) y = 1.0 / y
Reciprocal Weibull PDF 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = 1.0 / y
Reciprocal BET Sigmoidal A With Offset 2D		y = x / (a + bx - (a+b)x2) y = 1.0 / y + Offset
Reciprocal BET Sigmoidal B With Offset 2D		y = abx / (1.0 + (b-2.0)x - (b-1.0)x2) y = 1.0 / y + Offset
Reciprocal Chapman With Offset 2D		y = a * (1.0 - exp(-bx))c y = 1.0 / y + Offset
Reciprocal Don Levin Sigmoid With Offset 2D		y = a1 / (1.0 + exp(-(x-b1)/c1)) + a2 / (1.0 + exp(-(x-b2)/c2)) + a3 / (1.0 + exp(-(x-b3)/c3)) y = 1.0 / y + Offset
Reciprocal Gompertz A With Offset 2D		y = a * exp(-exp(b - cx)) y = 1.0 / y + Offset
Reciprocal Gompertz B With Offset 2D		y = a * exp(-exp((x-b)/c)) y = 1.0 / y + Offset
Reciprocal Gompertz C With Offset 2D		y = a * exp(b * exp(c * x)) y = 1.0 / y + Offset
Reciprocal Hill With Offset 2D		y = axb / (cb + xb) y = 1.0 / y + Offset
Reciprocal Logistic A With Offset 2D		y = a / (1.0 + b*exp(-cx)) y = 1.0 / y + Offset
Reciprocal Logistic B With Offset 2D		y = a / (1.0 + (x/b)c) y = 1.0 / y + Offset
Reciprocal Magnetic Saturation With Offset 2D		y = ax * (1.0 + b*exp(cx)) y = 1.0 / y + Offset
Reciprocal Morgan-Mercer-Flodin (MMF) With Offset 2D		y = (a * b + c * xd) / (b + xd) y = 1.0 / y + Offset
Reciprocal Peters-Baskin Step-Stool: y (1) With Offset 2D		y = ln(c + exp(b*d*x)) / d y = 1.0 / y + Offset   [web citation]
Reciprocal Peters-Baskin Step-Stool: yI (2) With Offset 2D		yI = ln(exp(b2*c1*d1) + exp(b2*d1*x)) / d1 yI = 1.0 / yI + Offset   [web citation]
Reciprocal Peters-Baskin Step-Stool: yII (3) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 yII = 1.0 / yII + Offset   [web citation]
Reciprocal Peters-Baskin Step-Stool: yIII (6) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c1 + L/d1)) + exp(d2*yII) ) / d2 yIII = 1.0 / yIII + Offset   [web citation]
Reciprocal Peters-Baskin Step-Stool: yIV (9) With Offset 2D		K = ln( exp(b2*c1*d1) + exp(b2*d1*x) ) yII = b1*x + K/d1 L = ln( exp(b2*c1*d1) + exp(b2*c2*d1) ) yIII = yII - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII) ) / d2 yII,0 = ln(exp(b2*c1*d1) + 1.0 ) / d1 yIII,0 = yII,0 - ln( exp(d2*(b1*c2 + L/d1)) + exp(d2*yII,0) ) / d2 yIV = yIII - yIII,0 yIV = 1.0 / yIV + Offset   [web citation]
Reciprocal Richards With Offset 2D		y = 1.0 / (a + b * e(c*x))d y = 1.0 / y + Offset
Reciprocal Sigmoid A Modified With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b)))c y = 1.0 / y + Offset
Reciprocal Sigmoid A With Offset 2D		y = 1.0 / (1.0 + exp(-a(x-b))) y = 1.0 / y + Offset
Reciprocal Sigmoid B Modified With Offset 2D		y = a / (1.0 + exp(-(x-b)/c))d y = 1.0 / y + Offset
Reciprocal Sigmoid B With Offset 2D		y = a / (1.0 + exp(-(x-b)/c)) y = 1.0 / y + Offset
Reciprocal Weibull CDF With Offset 2D		y = 1.0 - exp(-(x/b)a) y = 1.0 / y + Offset
Reciprocal Weibull PDF With Offset 2D		y = (a/b) * (x/b)(a-1.0) * exp(-(x/b)a) y = 1.0 / y + Offset

2D Trigonometric

Cardinal Sine (sinc) 2D		y = a * sin(x) / x
Cardinal Sine (sinc) Transform 2D		y = a * sin(bx + c) / (bx + c)
Cardinal Sine Squared (sinc squared) 2D		y = a * (sin(x))2 / x
Cardinal Sine Squared (sinc squared) Transform 2D		y = a * (sin(bx + c))2 / (bx + c)
Hyperbolic Cosine A [radians] 2D		y = a * cosh(x)
Hyperbolic Cosine B [radians] 2D		y = a * cosh(x + b)
Hyperbolic Cosine C [radians] 2D		y = a / cosh(x)
Hyperbolic Cosine D [radians] 2D		y = a / cosh(x + b)
Hyperbolic Cosine E [radians] 2D		y = a / cosh(x / a)
Sine A [radians] 2D		y = a * sin(x)
Sine B [radians] 2D		y = a * sin(b*x)
Sine C [radians] 2D		y = a * sin(bx + c)
Sine D [radians] 2D		y = a * sin(x + b)
Tangent A [radians] 2D		y = a * tan(x)
Tangent B [radians] 2D		y = a * tan(b*x)
Tangent C [radians] 2D		y = a * tan(bx + c)
Tangent D [radians] 2D		y = a * tan(x + b)
Cardinal Sine (sinc) Transform With Offset 2D		y = a * sin(bx + c) / (bx + c) + Offset
Cardinal Sine (sinc) With Offset 2D		y = a * sin(x) / x + Offset
Cardinal Sine Squared (sinc squared) Transform With Offset 2D		y = a * (sin(bx + c))2 / (bx + c) + Offset
Cardinal Sine Squared (sinc squared) With Offset 2D		y = a * (sin(x))2 / x + Offset
Hyperbolic Cosine A [radians] With Offset 2D		y = a * cosh(x) + Offset
Hyperbolic Cosine B [radians] With Offset 2D		y = a * cosh(x + b) + Offset
Hyperbolic Cosine C [radians] With Offset 2D		y = a / cosh(x) + Offset
Hyperbolic Cosine D [radians] With Offset 2D		y = a / cosh(x + b) + Offset
Hyperbolic Cosine E [radians] With Offset 2D		y = a / cosh(x / a) + Offset
Sine A [radians] With Offset 2D		y = a * sin(x) + Offset
Sine B [radians] With Offset 2D		y = a * sin(b*x) + Offset
Sine C [radians] With Offset 2D		y = a * sin(bx + c) + Offset
Sine D [radians] With Offset 2D		y = a * sin(x + b) + Offset
Tangent A [radians] With Offset 2D		y = a * tan(x) + Offset
Tangent B [radians] With Offset 2D		y = a * tan(b*x) + Offset
Tangent C [radians] With Offset 2D		y = a * tan(bx + c) + Offset
Tangent D [radians] With Offset 2D		y = a * tan(x + b) + Offset
Cardinal Sine (sinc) Transform With Exponential Decay 2D		y = a * sin(bx + c) / (bx + c) y = y / exp(x)
Cardinal Sine (sinc) With Exponential Decay 2D		y = a * sin(x) / x y = y / exp(x)
Cardinal Sine Squared (sinc squared) Transform With Exponential Decay 2D		y = a * (sin(bx + c))2 / (bx + c) y = y / exp(x)
Cardinal Sine Squared (sinc squared) With Exponential Decay 2D		y = a * (sin(x))2 / x y = y / exp(x)
Hyperbolic Cosine A [radians] With Exponential Decay 2D		y = a * cosh(x) y = y / exp(x)
Hyperbolic Cosine B [radians] With Exponential Decay 2D		y = a * cosh(x + b) y = y / exp(x)
Hyperbolic Cosine C [radians] With Exponential Decay 2D		y = a / cosh(x) y = y / exp(x)
Hyperbolic Cosine D [radians] With Exponential Decay 2D		y = a / cosh(x + b) y = y / exp(x)
Hyperbolic Cosine E [radians] With Exponential Decay 2D		y = a / cosh(x / a) y = y / (c * exp(x))
Sine A [radians] With Exponential Decay 2D		y = a * sin(x) y = y / exp(x)
Sine B [radians] With Exponential Decay 2D		y = a * sin(b*x) y = y / exp(x)
Sine C [radians] With Exponential Decay 2D		y = a * sin(bx + c) y = y / exp(x)
Sine D [radians] With Exponential Decay 2D		y = a * sin(x + b) y = y / exp(x)
Tangent A [radians] With Exponential Decay 2D		y = a * tan(x) y = y / exp(x)
Tangent B [radians] With Exponential Decay 2D		y = a * tan(b*x) y = y / exp(x)
Tangent C [radians] With Exponential Decay 2D		y = a * tan(bx + c) y = y / exp(x)
Tangent D [radians] With Exponential Decay 2D		y = a * tan(x + b) y = y / exp(x)
Cardinal Sine (sinc) Transform With Exponential Decay And Offset 2D		y = a * sin(bx + c) / (bx + c) y = y / exp(x) + Offset
Cardinal Sine (sinc) With Exponential Decay And Offset 2D		y = a * sin(x) / x y = y / exp(x) + Offset
Cardinal Sine Squared (sinc squared) Transform With Exponential Decay And Offset 2D		y = a * (sin(bx + c))2 / (bx + c) y = y / exp(x) + Offset
Cardinal Sine Squared (sinc squared) With Exponential Decay And Offset 2D		y = a * (sin(x))2 / x y = y / exp(x) + Offset
Hyperbolic Cosine A [radians] With Exponential Decay And Offset 2D		y = a * cosh(x) y = y / exp(x) + Offset
Hyperbolic Cosine B [radians] With Exponential Decay And Offset 2D		y = a * cosh(x + b) y = y / exp(x) + Offset
Hyperbolic Cosine C [radians] With Exponential Decay And Offset 2D		y = a / cosh(x) y = y / exp(x) + Offset
Hyperbolic Cosine D [radians] With Exponential Decay And Offset 2D		y = a / cosh(x + b) y = y / exp(x) + Offset
Hyperbolic Cosine E [radians] With Exponential Decay And Offset 2D		y = a / cosh(x / a) y = y / (d * exp(x)) + Offset
Sine A [radians] With Exponential Decay And Offset 2D		y = a * sin(x) y = y / exp(x) + Offset
Sine B [radians] With Exponential Decay And Offset 2D		y = a * sin(b*x) y = y / exp(x) + Offset
Sine C [radians] With Exponential Decay And Offset 2D		y = a * sin(bx + c) y = y / exp(x) + Offset
Sine D [radians] With Exponential Decay And Offset 2D		y = a * sin(x + b) y = y / exp(x) + Offset
Tangent A [radians] With Exponential Decay And Offset 2D		y = a * tan(x) y = y / exp(x) + Offset
Tangent B [radians] With Exponential Decay And Offset 2D		y = a * tan(b*x) y = y / exp(x) + Offset
Tangent C [radians] With Exponential Decay And Offset 2D		y = a * tan(bx + c) y = y / exp(x) + Offset
Tangent D [radians] With Exponential Decay And Offset 2D		y = a * tan(x + b) y = y / exp(x) + Offset
Cardinal Sine (sinc) Transform With Exponential Growth 2D		y = a * sin(bx + c) / (bx + c) y = y * exp(x)
Cardinal Sine (sinc) With Exponential Growth 2D		y = a * sin(x) / x y = y * exp(x)
Cardinal Sine Squared (sinc squared) Transform With Exponential Growth 2D		y = a * (sin(bx + c))2 / (bx + c) y = y * exp(x)
Cardinal Sine Squared (sinc squared) With Exponential Growth 2D		y = a * (sin(x))2 / x y = y * exp(x)
Hyperbolic Cosine A [radians] With Exponential Growth 2D		y = a * cosh(x) y = y * exp(x)
Hyperbolic Cosine B [radians] With Exponential Growth 2D		y = a * cosh(x + b) y = y * exp(x)
Hyperbolic Cosine C [radians] With Exponential Growth 2D		y = a / cosh(x) y = y * exp(x)
Hyperbolic Cosine D [radians] With Exponential Growth 2D		y = a / cosh(x + b) y = y * exp(x)
Hyperbolic Cosine E [radians] With Exponential Growth 2D		y = a / cosh(x / a) y = y * (c * exp(x))
Sine A [radians] With Exponential Growth 2D		y = a * sin(x) y = y * exp(x)
Sine B [radians] With Exponential Growth 2D		y = a * sin(b*x) y = y * exp(x)
Sine C [radians] With Exponential Growth 2D		y = a * sin(bx + c) y = y * exp(x)
Sine D [radians] With Exponential Growth 2D		y = a * sin(x + b) y = y * exp(x)
Tangent A [radians] With Exponential Growth 2D		y = a * tan(x) y = y * exp(x)
Tangent B [radians] With Exponential Growth 2D		y = a * tan(b*x) y = y * exp(x)
Tangent C [radians] With Exponential Growth 2D		y = a * tan(bx + c) y = y * exp(x)
Tangent D [radians] With Exponential Growth 2D		y = a * tan(x + b) y = y * exp(x)
Cardinal Sine (sinc) Transform With Exponential Growth And Offset 2D		y = a * sin(bx + c) / (bx + c) y = y * exp(x) + Offset
Cardinal Sine (sinc) With Exponential Growth And Offset 2D		y = a * sin(x) / x y = y * exp(x) + Offset
Cardinal Sine Squared (sinc squared) Transform With Exponential Growth And Offset 2D		y = a * (sin(bx + c))2 / (bx + c) y = y * exp(x) + Offset
Cardinal Sine Squared (sinc squared) With Exponential Growth And Offset 2D		y = a * (sin(x))2 / x y = y * exp(x) + Offset
Hyperbolic Cosine A [radians] With Exponential Growth And Offset 2D		y = a * cosh(x) y = y * exp(x) + Offset
Hyperbolic Cosine B [radians] With Exponential Growth And Offset 2D		y = a * cosh(x + b) y = y * exp(x) + Offset
Hyperbolic Cosine C [radians] With Exponential Growth And Offset 2D		y = a / cosh(x) y = y * exp(x) + Offset
Hyperbolic Cosine D [radians] With Exponential Growth And Offset 2D		y = a / cosh(x + b) y = y * exp(x) + Offset
Hyperbolic Cosine E [radians] With Exponential Growth And Offset 2D		y = a / cosh(x / a) y = y * (d * exp(x)) + Offset
Sine A [radians] With Exponential Growth And Offset 2D		y = a * sin(x) y = y * exp(x) + Offset
Sine B [radians] With Exponential Growth And Offset 2D		y = a * sin(b*x) y = y * exp(x) + Offset
Sine C [radians] With Exponential Growth And Offset 2D		y = a * sin(bx + c) y = y * exp(x) + Offset
Sine D [radians] With Exponential Growth And Offset 2D		y = a * sin(x + b) y = y * exp(x) + Offset
Tangent A [radians] With Exponential Growth And Offset 2D		y = a * tan(x) y = y * exp(x) + Offset
Tangent B [radians] With Exponential Growth And Offset 2D		y = a * tan(b*x) y = y * exp(x) + Offset
Tangent C [radians] With Exponential Growth And Offset 2D		y = a * tan(bx + c) y = y * exp(x) + Offset
Tangent D [radians] With Exponential Growth And Offset 2D		y = a * tan(x + b) y = y * exp(x) + Offset
Inverse Cardinal Sine (sinc) Transform 2D		y = a * sin(bx + c) / (bx + c) y = x / y
Inverse Cardinal Sine Squared (sinc squared) Transform 2D		y = a * (sin(bx + c))2 / (bx + c) y = x / y
Inverse Hyperbolic Cosine A [radians] 2D		y = a * cosh(x) y = x / y
Inverse Hyperbolic Cosine B [radians] 2D		y = a * cosh(x + b) y = x / y
Inverse Hyperbolic Cosine C [radians] 2D		y = a / cosh(x) y = x / y
Inverse Hyperbolic Cosine D [radians] 2D		y = a / cosh(x + b) y = x / y
Inverse Hyperbolic Cosine E [radians] 2D		y = a / cosh(x / a) y = x / y
Inverse Sine A [radians] 2D		y = a * sin(x) y = x / y
Inverse Sine B [radians] 2D		y = a * sin(b*x) y = x / y
Inverse Sine C [radians] 2D		y = a * sin(bx + c) y = x / y
Inverse Sine D [radians] 2D		y = a * sin(x + b) y = x / y
Inverse Tangent A [radians] 2D		y = a * tan(x) y = x / y
Inverse Tangent B [radians] 2D		y = a * tan(b*x) y = x / y
Inverse Tangent C [radians] 2D		y = a * tan(bx + c) y = x / y
Inverse Tangent D [radians] 2D		y = a * tan(x + b) y = x / y
Inverse Cardinal Sine (sinc) Transform With Offset 2D		y = a * sin(bx + c) / (bx + c) y = x / y + Offset
Inverse Cardinal Sine Squared (sinc squared) Transform With Offset 2D		y = a * (sin(bx + c))2 / (bx + c) y = x / y + Offset
Inverse Hyperbolic Cosine A [radians] With Offset 2D		y = a * cosh(x) y = x / y + Offset
Inverse Hyperbolic Cosine B [radians] With Offset 2D		y = a * cosh(x + b) y = x / y + Offset
Inverse Hyperbolic Cosine C [radians] With Offset 2D		y = a / cosh(x) y = x / y + Offset
Inverse Hyperbolic Cosine D [radians] With Offset 2D		y = a / cosh(x + b) y = x / y + Offset
Inverse Hyperbolic Cosine E [radians] With Offset 2D		y = a / cosh(x / a) y = x / y + Offset
Inverse Sine A [radians] With Offset 2D		y = a * sin(x) y = x / y + Offset
Inverse Sine B [radians] With Offset 2D		y = a * sin(b*x) y = x / y + Offset
Inverse Sine C [radians] With Offset 2D		y = a * sin(bx + c) y = x / y + Offset
Inverse Sine D [radians] With Offset 2D		y = a * sin(x + b) y = x / y + Offset
Inverse Tangent A [radians] With Offset 2D		y = a * tan(x) y = x / y + Offset
Inverse Tangent B [radians] With Offset 2D		y = a * tan(b*x) y = x / y + Offset
Inverse Tangent C [radians] With Offset 2D		y = a * tan(bx + c) y = x / y + Offset
Inverse Tangent D [radians] With Offset 2D		y = a * tan(x + b) y = x / y + Offset
Cardinal Sine (sinc) Transform With Linear Decay 2D		y = a * sin(bx + c) / (bx + c) y = y / x
Cardinal Sine (sinc) With Linear Decay 2D		y = a * sin(x) / x y = y / x
Cardinal Sine Squared (sinc squared) Transform With Linear Decay 2D		y = a * (sin(bx + c))2 / (bx + c) y = y / x
Cardinal Sine Squared (sinc squared) With Linear Decay 2D		y = a * (sin(x))2 / x y = y / x
Hyperbolic Cosine A [radians] With Linear Decay 2D		y = a * cosh(x) y = y / x
Hyperbolic Cosine B [radians] With Linear Decay 2D		y = a * cosh(x + b) y = y / x
Hyperbolic Cosine C [radians] With Linear Decay 2D		y = a / cosh(x) y = y / x
Hyperbolic Cosine D [radians] With Linear Decay 2D		y = a / cosh(x + b) y = y / x
Hyperbolic Cosine E [radians] With Linear Decay 2D		y = a / cosh(x / a) y = y / (c * x)
Sine A [radians] With Linear Decay 2D		y = a * sin(x) y = y / x
Sine B [radians] With Linear Decay 2D		y = a * sin(b*x) y = y / x
Sine C [radians] With Linear Decay 2D		y = a * sin(bx + c) y = y / x
Sine D [radians] With Linear Decay 2D		y = a * sin(x + b) y = y / x
Tangent A [radians] With Linear Decay 2D		y = a * tan(x) y = y / x
Tangent B [radians] With Linear Decay 2D		y = a * tan(b*x) y = y / x
Tangent C [radians] With Linear Decay 2D		y = a * tan(bx + c) y = y / x
Tangent D [radians] With Linear Decay 2D		y = a * tan(x + b) y = y / x
Cardinal Sine (sinc) Transform With Linear Decay And Offset 2D		y = a * sin(bx + c) / (bx + c) y = y / x + Offset
Cardinal Sine (sinc) With Linear Decay And Offset 2D		y = a * sin(x) / x y = y / x + Offset
Cardinal Sine Squared (sinc squared) Transform With Linear Decay And Offset 2D		y = a * (sin(bx + c))2 / (bx + c) y = y / x + Offset
Cardinal Sine Squared (sinc squared) With Linear Decay And Offset 2D		y = a * (sin(x))2 / x y = y / x + Offset
Hyperbolic Cosine A [radians] With Linear Decay And Offset 2D		y = a * cosh(x) y = y / x + Offset
Hyperbolic Cosine B [radians] With Linear Decay And Offset 2D		y = a * cosh(x + b) y = y / x + Offset
Hyperbolic Cosine C [radians] With Linear Decay And Offset 2D		y = a / cosh(x) y = y / x + Offset
Hyperbolic Cosine D [radians] With Linear Decay And Offset 2D		y = a / cosh(x + b) y = y / x + Offset
Hyperbolic Cosine E [radians] With Linear Decay And Offset 2D		y = a / cosh(x / a) y = y / (d * x) + Offset
Sine A [radians] With Linear Decay And Offset 2D		y = a * sin(x) y = y / x + Offset
Sine B [radians] With Linear Decay And Offset 2D		y = a * sin(b*x) y = y / x + Offset
Sine C [radians] With Linear Decay And Offset 2D		y = a * sin(bx + c) y = y / x + Offset
Sine D [radians] With Linear Decay And Offset 2D		y = a * sin(x + b) y = y / x + Offset
Tangent A [radians] With Linear Decay And Offset 2D		y = a * tan(x) y = y / x + Offset
Tangent B [radians] With Linear Decay And Offset 2D		y = a * tan(b*x) y = y / x + Offset
Tangent C [radians] With Linear Decay And Offset 2D		y = a * tan(bx + c) y = y / x + Offset
Tangent D [radians] With Linear Decay And Offset 2D		y = a * tan(x + b) y = y / x + Offset
Cardinal Sine (sinc) Transform With Linear Growth 2D		y = a * sin(bx + c) / (bx + c) y = y * x
Cardinal Sine (sinc) With Linear Growth 2D		y = a * sin(x) / x y = y * x
Cardinal Sine Squared (sinc squared) Transform With Linear Growth 2D		y = a * (sin(bx + c))2 / (bx + c) y = y * x
Cardinal Sine Squared (sinc squared) With Linear Growth 2D		y = a * (sin(x))2 / x y = y * x
Hyperbolic Cosine A [radians] With Linear Growth 2D		y = a * cosh(x) y = y * x
Hyperbolic Cosine B [radians] With Linear Growth 2D		y = a * cosh(x + b) y = y * x
Hyperbolic Cosine C [radians] With Linear Growth 2D		y = a / cosh(x) y = y * x
Hyperbolic Cosine D [radians] With Linear Growth 2D		y = a / cosh(x + b) y = y * x
Hyperbolic Cosine E [radians] With Linear Growth 2D		y = a / cosh(x / a) y = y * (c * x) + Offset
Sine A [radians] With Linear Growth 2D		y = a * sin(x) y = y * x
Sine B [radians] With Linear Growth 2D		y = a * sin(b*x) y = y * x
Sine C [radians] With Linear Growth 2D		y = a * sin(bx + c) y = y * x
Sine D [radians] With Linear Growth 2D		y = a * sin(x + b) y = y * x
Tangent A [radians] With Linear Growth 2D		y = a * tan(x) y = y * x
Tangent B [radians] With Linear Growth 2D		y = a * tan(b*x) y = y * x
Tangent C [radians] With Linear Growth 2D		y = a * tan(bx + c) y = y * x
Tangent D [radians] With Linear Growth 2D		y = a * tan(x + b) y = y * x
Cardinal Sine (sinc) Transform With Linear Growth And Offset 2D		y = a * sin(bx + c) / (bx + c) y = y * x + Offset
Cardinal Sine (sinc) With Linear Growth And Offset 2D		y = a * sin(x) / x y = y * x + Offset
Cardinal Sine Squared (sinc squared) Transform With Linear Growth And Offset 2D		y = a * (sin(bx + c))2 / (bx + c) y = y * x + Offset
Cardinal Sine Squared (sinc squared) With Linear Growth And Offset 2D		y = a * (sin(x))2 / x y = y * x + Offset
Hyperbolic Cosine A [radians] With Linear Growth And Offset 2D		y = a * cosh(x) y = y * x + Offset
Hyperbolic Cosine B [radians] With Linear Growth And Offset 2D		y = a * cosh(x + b) y = y * x + Offset
Hyperbolic Cosine C [radians] With Linear Growth And Offset 2D		y = a / cosh(x) y = y * x + Offset
Hyperbolic Cosine D [radians] With Linear Growth And Offset 2D		y = a / cosh(x + b) y = y * x + Offset
Hyperbolic Cosine E [radians] With Linear Growth And Offset 2D		y = a / cosh(x / a) y = y * (d * x) + Offset
Sine A [radians] With Linear Growth And Offset 2D		y = a * sin(x) y = y * x + Offset
Sine B [radians] With Linear Growth And Offset 2D		y = a * sin(b*x) y = y * x + Offset
Sine C [radians] With Linear Growth And Offset 2D		y = a * sin(bx + c) y = y * x + Offset
Sine D [radians] With Linear Growth And Offset 2D		y = a * sin(x + b) y = y * x + Offset
Tangent A [radians] With Linear Growth And Offset 2D		y = a * tan(x) y = y * x + Offset
Tangent B [radians] With Linear Growth And Offset 2D		y = a * tan(b*x) y = y * x + Offset
Tangent C [radians] With Linear Growth And Offset 2D		y = a * tan(bx + c) y = y * x + Offset
Tangent D [radians] With Linear Growth And Offset 2D		y = a * tan(x + b) y = y * x + Offset
Reciprocal Cardinal Sine (sinc) 2D		y = a * sin(x) / x y = 1.0 / y
Reciprocal Cardinal Sine (sinc) Transform 2D		y = a * sin(bx + c) / (bx + c) y = 1.0 / y
Reciprocal Cardinal Sine Squared (sinc squared) 2D		y = a * (sin(x))2 / x y = 1.0 / y
Reciprocal Cardinal Sine Squared (sinc squared) Transform 2D		y = a * (sin(bx + c))2 / (bx + c) y = 1.0 / y
Reciprocal Hyperbolic Cosine A [radians] 2D		y = a * cosh(x) y = 1.0 / y
Reciprocal Hyperbolic Cosine B [radians] 2D		y = a * cosh(x + b) y = 1.0 / y
Reciprocal Hyperbolic Cosine C [radians] 2D		y = a / cosh(x) y = 1.0 / y
Reciprocal Hyperbolic Cosine D [radians] 2D		y = a / cosh(x + b) y = 1.0 / y
Reciprocal Hyperbolic Cosine E [radians] 2D		y = a / cosh(x / a) y = 1.0 / y
Reciprocal Sine A [radians] 2D		y = a * sin(x) y = 1.0 / y
Reciprocal Sine B [radians] 2D		y = a * sin(b*x) y = 1.0 / y
Reciprocal Sine C [radians] 2D		y = a * sin(bx + c) y = 1.0 / y
Reciprocal Sine D [radians] 2D		y = a * sin(x + b) y = 1.0 / y
Reciprocal Tangent A [radians] 2D		y = a * tan(x) y = 1.0 / y
Reciprocal Tangent B [radians] 2D		y = a * tan(b*x) y = 1.0 / y
Reciprocal Tangent C [radians] 2D		y = a * tan(bx + c) y = 1.0 / y
Reciprocal Tangent D [radians] 2D		y = a * tan(x + b) y = 1.0 / y
Reciprocal Cardinal Sine (sinc) Transform With Offset 2D		y = a * sin(bx + c) / (bx + c) y = 1.0 / y + Offset
Reciprocal Cardinal Sine (sinc) With Offset 2D		y = a * sin(x) / x y = 1.0 / y + Offset
Reciprocal Cardinal Sine Squared (sinc squared) Transform With Offset 2D		y = a * (sin(bx + c))2 / (bx + c) y = 1.0 / y + Offset
Reciprocal Cardinal Sine Squared (sinc squared) With Offset 2D		y = a * (sin(x))2 / x y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine A [radians] With Offset 2D		y = a * cosh(x) y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine B [radians] With Offset 2D		y = a * cosh(x + b) y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine C [radians] With Offset 2D		y = a / cosh(x) y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine D [radians] With Offset 2D		y = a / cosh(x + b) y = 1.0 / y + Offset
Reciprocal Hyperbolic Cosine E [radians] With Offset 2D		y = a / cosh(x / a) y = 1.0 / y + Offset
Reciprocal Sine A [radians] With Offset 2D		y = a * sin(x) y = 1.0 / y + Offset
Reciprocal Sine B [radians] With Offset 2D		y = a * sin(b*x) y = 1.0 / y + Offset
Reciprocal Sine C [radians] With Offset 2D		y = a * sin(bx + c) y = 1.0 / y + Offset
Reciprocal Sine D [radians] With Offset 2D		y = a * sin(x + b) y = 1.0 / y + Offset
Reciprocal Tangent A [radians] With Offset 2D		y = a * tan(x) y = 1.0 / y + Offset
Reciprocal Tangent B [radians] With Offset 2D		y = a * tan(b*x) y = 1.0 / y + Offset
Reciprocal Tangent C [radians] With Offset 2D		y = a * tan(bx + c) y = 1.0 / y + Offset
Reciprocal Tangent D [radians] With Offset 2D		y = a * tan(x + b) y = 1.0 / y + Offset

2D YieldDensity

Bleasdale 2D		y = 1.0 / (a + bx)(-1.0/c)
Extended Holliday 2D		y = a / (a + bx + cx2)
Harris 2D		y = 1.0 / (a + bxc)
Holliday 2D		y = 1.0 / (a + bx + cx2)
Inverse Bleasdale 2D		y = x / (a + bx)(-1.0/c)
InverseHarris 2D		y = x / (a + bxc)
Bleasdale With Offset 2D		y = 1.0 / (a + bx)(-1.0/c) + Offset
Extended Holliday With Offset 2D		y = a / (a + bx + cx2) + Offset
Harris With Offset 2D		y = 1.0 / (a + bxc) + Offset
Holliday With Offset 2D		y = 1.0 / (a + bx + cx2) + Offset
Inverse Bleasdale With Offset 2D		y = x / (a + bx)(-1.0/c) + Offset
InverseHarris With Offset 2D		y = x / (a + bxc) + Offset
Bleasdale With Exponential Decay 2D		y = 1.0 / (a + bx)(-1.0/c) y = y / (f * exp(x))
Extended Holliday With Exponential Decay 2D		y = a / (a + bx + cx2) y = y / (f * exp(x))
Harris With Exponential Decay 2D		y = 1.0 / (a + bxc) y = y / (f * exp(x))
Holliday With Exponential Decay 2D		y = 1.0 / (a + bx + cx2) y = y / (f * exp(x))
Inverse Bleasdale With Exponential Decay 2D		y = x / (a + bx)(-1.0/c) y = y / (f * exp(x))
InverseHarris With Exponential Decay 2D		y = x / (a + bxc) y = y / (f * exp(x))
Bleasdale With Exponential Decay And Offset 2D		y = 1.0 / (a + bx)(-1.0/c) y = y / (g * exp(x)) + Offset
Extended Holliday With Exponential Decay And Offset 2D		y = a / (a + bx + cx2) y = y / (g * exp(x)) + Offset
Harris With Exponential Decay And Offset 2D		y = 1.0 / (a + bxc) y = y / (g * exp(x)) + Offset
Holliday With Exponential Decay And Offset 2D		y = 1.0 / (a + bx + cx2) y = y / (g * exp(x)) + Offset
Inverse Bleasdale With Exponential Decay And Offset 2D		y = x / (a + bx)(-1.0/c) y = y / (g * exp(x)) + Offset
InverseHarris With Exponential Decay And Offset 2D		y = x / (a + bxc) y = y / (g * exp(x)) + Offset
Bleasdale With Exponential Growth 2D		y = 1.0 / (a + bx)(-1.0/c) y = y * (f * exp(x))
Extended Holliday With Exponential Growth 2D		y = a / (a + bx + cx2) y = y * (f * exp(x))
Harris With Exponential Growth 2D		y = 1.0 / (a + bxc) y = y * (f * exp(x))
Holliday With Exponential Growth 2D		y = 1.0 / (a + bx + cx2) y = y * (f * exp(x))
Inverse Bleasdale With Exponential Growth 2D		y = x / (a + bx)(-1.0/c) y = y * (f * exp(x))
InverseHarris With Exponential Growth 2D		y = x / (a + bxc) y = y * (f * exp(x))
Bleasdale With Exponential Growth And Offset 2D		y = 1.0 / (a + bx)(-1.0/c) y = y * (g * exp(x)) + Offset
Extended Holliday With Exponential Growth And Offset 2D		y = a / (a + bx + cx2) y = y * (g * exp(x)) + Offset
Harris With Exponential Growth And Offset 2D		y = 1.0 / (a + bxc) y = y * (g * exp(x)) + Offset
Holliday With Exponential Growth And Offset 2D		y = 1.0 / (a + bx + cx2) y = y * (g * exp(x)) + Offset
Inverse Bleasdale With Exponential Growth And Offset 2D		y = x / (a + bx)(-1.0/c) y = y * (g * exp(x)) + Offset
InverseHarris With Exponential Growth And Offset 2D		y = x / (a + bxc) y = y * (g * exp(x)) + Offset
Inverse Bleasdale 2D		y = 1.0 / (a + bx)(-1.0/c) y = x / y
Inverse Extended Holliday 2D		y = a / (a + bx + cx2) y = x / y
Inverse Harris 2D		y = 1.0 / (a + bxc) y = x / y
Inverse Holliday 2D		y = 1.0 / (a + bx + cx2) y = x / y
Inverse Bleasdale With Offset 2D		y = 1.0 / (a + bx)(-1.0/c) y = x / y + Offset
Inverse Extended Holliday With Offset 2D		y = a / (a + bx + cx2) y = x / y + Offset
Inverse Harris With Offset 2D		y = 1.0 / (a + bxc) y = x / y + Offset
Inverse Holliday With Offset 2D		y = 1.0 / (a + bx + cx2) y = x / y + Offset
Bleasdale With Linear Decay 2D		y = 1.0 / (a + bx)(-1.0/c) y = y / (f * x)
Extended Holliday With Linear Decay 2D		y = a / (a + bx + cx2) y = y / (f * x)
Harris With Linear Decay 2D		y = 1.0 / (a + bxc) y = y / (f * x)
Holliday With Linear Decay 2D		y = 1.0 / (a + bx + cx2) y = y / (f * x)
Inverse Bleasdale With Linear Decay 2D		y = x / (a + bx)(-1.0/c) y = y / (f * x)
InverseHarris With Linear Decay 2D		y = x / (a + bxc) y = y / (f * x)
Bleasdale With Linear Decay And Offset 2D		y = 1.0 / (a + bx)(-1.0/c) y = y / (g * x) + Offset
Extended Holliday With Linear Decay And Offset 2D		y = a / (a + bx + cx2) y = y / (g * x) + Offset
Harris With Linear Decay And Offset 2D		y = 1.0 / (a + bxc) y = y / (g * x) + Offset
Holliday With Linear Decay And Offset 2D		y = 1.0 / (a + bx + cx2) y = y / (g * x) + Offset
Inverse Bleasdale With Linear Decay And Offset 2D		y = x / (a + bx)(-1.0/c) y = y / (g * x) + Offset
InverseHarris With Linear Decay And Offset 2D		y = x / (a + bxc) y = y / (g * x) + Offset
Bleasdale With Linear Growth 2D		y = 1.0 / (a + bx)(-1.0/c) y = y * (f * x) + Offset
Extended Holliday With Linear Growth 2D		y = a / (a + bx + cx2) y = y * (f * x) + Offset
Harris With Linear Growth 2D		y = 1.0 / (a + bxc) y = y * (f * x) + Offset
Holliday With Linear Growth 2D		y = 1.0 / (a + bx + cx2) y = y * (f * x) + Offset
Inverse Bleasdale With Linear Growth 2D		y = x / (a + bx)(-1.0/c) y = y * (f * x) + Offset
InverseHarris With Linear Growth 2D		y = x / (a + bxc) y = y * (f * x) + Offset
Bleasdale With Linear Growth And Offset 2D		y = 1.0 / (a + bx)(-1.0/c) y = y * (g * x) + Offset
Extended Holliday With Linear Growth And Offset 2D		y = a / (a + bx + cx2) y = y * (g * x) + Offset
Harris With Linear Growth And Offset 2D		y = 1.0 / (a + bxc) y = y * (g * x) + Offset
Holliday With Linear Growth And Offset 2D		y = 1.0 / (a + bx + cx2) y = y * (g * x) + Offset
Inverse Bleasdale With Linear Growth And Offset 2D		y = x / (a + bx)(-1.0/c) y = y * (g * x) + Offset
InverseHarris With Linear Growth And Offset 2D		y = x / (a + bxc) y = y * (g * x) + Offset
Reciprocal Bleasdale 2D		y = 1.0 / (a + bx)(-1.0/c) y = 1.0 / y
Reciprocal Extended Holliday 2D		y = a / (a + bx + cx2) y = 1.0 / y
Reciprocal Harris 2D		y = 1.0 / (a + bxc) y = 1.0 / y
Reciprocal Holliday 2D		y = 1.0 / (a + bx + cx2) y = 1.0 / y
Reciprocal Inverse Bleasdale 2D		y = x / (a + bx)(-1.0/c) y = 1.0 / y
Reciprocal InverseHarris 2D		y = x / (a + bxc) y = 1.0 / y
Reciprocal Bleasdale With Offset 2D		y = 1.0 / (a + bx)(-1.0/c) y = 1.0 / y + Offset
Reciprocal Extended Holliday With Offset 2D		y = a / (a + bx + cx2) y = 1.0 / y + Offset
Reciprocal Harris With Offset 2D		y = 1.0 / (a + bxc) y = 1.0 / y + Offset
Reciprocal Holliday With Offset 2D		y = 1.0 / (a + bx + cx2) y = 1.0 / y + Offset
Reciprocal Inverse Bleasdale With Offset 2D		y = x / (a + bx)(-1.0/c) y = 1.0 / y + Offset
Reciprocal InverseHarris With Offset 2D		y = x / (a + bxc) y = 1.0 / y + Offset

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The fitting source code for the site software is at the Python Equations II Google Code Repository.

Superior quality PDF on practical curve fitting: Fitting Models to Experimental Data

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