Just in case `R`

is an option, here's a sketch of two methods you might use.

**First method: evaluate the goodness of fit of a set of candidate models** This is probably the best way as it takes advantage of what you might already know or expect about the relationship between the variables.

```
# read in the data
dat <- read.table(text= "x y
28 45
91 14
102 11
393 5
4492 1.77", header = TRUE)
# quick visual inspection
plot(dat); lines(dat)
```

```
# a smattering of possible models... just made up on the spot
# with more effort some better candidates should be added
# a smattering of possible models...
models <- list(lm(y~x, data = dat),
lm(y~I(1/x), data=dat),
lm(y ~ log(x), data = dat),
nls(y ~ I(1/x*a) + b*x, data = dat, start = list(a = 1, b = 1)),
nls(y ~ (a + b*log(x)), data=dat, start = setNames(coef(lm(y ~ log(x), data=dat)), c("a", "b"))),
nls(y ~ I(exp(1)^(a + b * x)), data=dat, start = list(a=0,b=0)),
nls(y ~ I(1/x*a)+b, data=dat, start = list(a=1,b=1))
)
# have a quick look at the visual fit of these models
library(ggplot2)
ggplot(dat, aes(x, y)) + geom_point(size = 5) +
stat_smooth(method = "lm", formula = as.formula(models[[1]]), size = 1, se = FALSE, colour = "black") +
stat_smooth(method = "lm", formula = as.formula(models[[2]]), size = 1, se = FALSE, colour = "blue") +
stat_smooth(method = "lm", formula = as.formula(models[[3]]), size = 1, se = FALSE, colour = "yellow") +
stat_smooth(method = "nls", formula = as.formula(models[[4]]), data=dat, start = list(a=0,b=0), size = 1, se = FALSE, colour = "red") +
stat_smooth(method = "nls", formula = as.formula(models[[5]]), data=dat, start = setNames(coef(lm(y ~ log(x), data=dat)), c("a", "b")), size = 1, se = FALSE, colour = "green") +
stat_smooth(method = "nls", formula = as.formula(models[[6]]), data=dat, start = list(a=0,b=0), size = 1, se = FALSE, colour = "violet") +
stat_smooth(method = "nls", formula = as.formula(models[[7]]), data=dat, start = list(a=0,b=0), size = 1, se = FALSE, colour = "orange")
```

The orange curve looks pretty good. Let's see how it ranks when we measure the relative goodness of fit of these models are...

```
# calculate the AIC and AICc (for small samples) for each
# model to see which one is best, ie has the lowest AIC
library(AICcmodavg); library(plyr); library(stringr)
ldply(models, function(mod){ data.frame(AICc = AICc(mod), AIC = AIC(mod), model = deparse(formula(mod))) })
AICc AIC model
1 70.23024 46.23024 y ~ x
2 44.37075 20.37075 y ~ I(1/x)
3 67.00075 43.00075 y ~ log(x)
4 43.82083 19.82083 y ~ I(1/x * a) + b * x
5 67.00075 43.00075 y ~ (a + b * log(x))
6 52.75748 28.75748 y ~ I(exp(1)^(a + b * x))
7 44.37075 20.37075 y ~ I(1/x * a) + b
# y ~ I(1/x * a) + b * x is the best model of those tried here for this curve
# it fits nicely on the plot and has the best goodness of fit statistic
# no doubt with a better understanding of nls and the data a better fitting
# function could be found. Perhaps the optimisation method here might be
# useful also: http://stats.stackexchange.com/a/21098/7744
```

**Second method: use genetic programming to search a vast amount of models** This seems to be a kind of wild shot in the dark approach to curve-fitting. You don't have to specify much at the start, though perhaps I'm doing it wrong...

```
# symbolic regression using Genetic Programming
# http://rsymbolic.org/projects/rgp/wiki/Symbolic_Regression
library(rgp)
# this will probably take some time and throw
# a lot of warnings...
result1 <- symbolicRegression(y ~ x,
data=dat, functionSet=mathFunctionSet,
stopCondition=makeStepsStopCondition(2000))
# inspect results, they'll be different every time...
(symbreg <- result1$population[[which.min(sapply(result1$population, result1$fitnessFunction))]])
function (x)
tan((x - x + tan(x)) * x)
# quite bizarre...
# inspect visual fit
ggplot() + geom_point(data=dat, aes(x,y), size = 3) +
geom_line(data=data.frame(symbx=dat$x, symby=sapply(dat$x, symbreg)), aes(symbx, symby), colour = "red")
```

Actually a very poor visual fit. Perhaps there's a bit more effort required to get quality results from genetic programming...

Credits: http://stackoverflow.com/a/15045035/1036500, http://stackoverflow.com/a/14659711/1036500