# Calculating R^2 for a nonlinear least squares fit

Suppose I have `x` values, `y` values, and expected y values `f` (from some nonlinear best fit curve).

How can I compute R^2 in R? Note that this function is not a linear model, but a nonlinear least squares (`nls`) fit, so not an `lm` fit.

• It is hard for me to see if you are talking about a linear system of some sort or not. Title says nonlinear and f is "some best fit line"? Maybe a clarification could get you a better answer. – Seth Jan 25 '13 at 21:57
• @Seth, I edited the title based on the text of the question and the comments. I think the OP means "best fit curve", and I suspect that your answer is exactly what they want. Of course the OP is free to roll back my edit if it's wrong, or further edit for clarity ... – Ben Bolker Jan 25 '13 at 21:59
• @BenBolker your edit is correct. Sorry about that. – CodeGuy Jan 25 '13 at 22:23
• This sounds more like a statistics question than an R question. – hadley Jan 26 '13 at 13:54
• "how can I ... ?" is an R question. "Should I?" is a statistics question. – Ben Bolker Jan 26 '13 at 16:57

You just use the `lm` function to fit a linear model:

``````x = runif(100)
y = runif(100)
spam = summary(lm(x~y))
> spam\$r.squared
 0.0008532386
``````

Note that the r squared is not defined for non-linear models, or at least very tricky, quote from R-help:

There is a good reason that an nls model fit in R does not provide r-squared - r-squared doesn't make sense for a general nls model.

One way of thinking of r-squared is as a comparison of the residual sum of squares for the fitted model to the residual sum of squares for a trivial model that consists of a constant only. You cannot guarantee that this is a comparison of nested models when dealing with an nls model. If the models aren't nested this comparison is not terribly meaningful.

So the answer is that you probably don't want to do this in the first place.

If you want peer-reviewed evidence, see this article for example; it's not that you can't compute the R^2 value, it's just that it may not mean the same thing/have the same desirable properties as in the linear-model case.

• True, except this isn't a linear model :) – CodeGuy Jan 25 '13 at 21:38
• Sure there is. You can generalize R^2 to nonlinear in some way. How else could one measure the fit? – CodeGuy Jan 25 '13 at 21:39
• The R^2 in the way it is defined for linear models does not have the same meaning for non-linear models, see my answer. – Paul Hiemstra Jan 25 '13 at 21:44
• @flodel, that's the article linked from the answer. – Ben Bolker Jan 25 '13 at 21:50
• I think your answer could be improved if you used my deleted solution for the first part. The OP is not interested in a linear model, instead he has his own prediction `f`. Feel free to use it. – flodel Jan 25 '13 at 22:18

Sounds like f are your predicted values. So the distance from them to the actual values devided by n * variance of y

so something like

`1-sum((y-f)^2)/(length(y)*var(y))`

should give you a quasi rsquared value, so long as your model is reasonably close to a linear model and n is pretty big.

• note that this is the same as @Flodel's (now deleted) answer, with the tiny exception that `var(y)` is computed with a denominator of `length(y)-1` (unbiased estimate), so the denominator is not quite the same as `sum((y-mean(y))^2)`. I agree with all the cautionary notes here. I also think that if someone asks for rope to hang themselves, it's fine to give it to them (while performing due diligence by asking "are you sure you want to do this?") – Ben Bolker Jan 25 '13 at 21:50
• @Paul but most of us would miss. – Carl Witthoft Jan 25 '13 at 23:03

Another quasi-R-squared for non-linear models is to square the correlation between the actual y-values and the predicted y-values. For linear models this is the regular R-squared.

• is this actually numerically different from @Seth's/@Flodel's answer? I think they might come out identical, at least up to factors of n-1 vs n (but too lazy to check) – Ben Bolker Jan 26 '13 at 1:12
• @BenBolker, Mine divides by sd(y-hat) and sd(y) where Seth's answer divides by sd(y) twice (var(y)), so when the variability of y-hat and y is similar (high r-squared) they should be pretty similar, but would probably tend to differ more. If for some strange reason the fitted model was opposite the true relationship (model says y increases with x when truth is that it decreases with x) then Seth's answer would give a negative R-squared while mine would give a value closer to 1, which is the more useless in this strange situation is another debate. – Greg Snow Jan 26 '13 at 16:29
• To avoid the pathological example you describe would it not make more sense then to use max(cor(y,yfitted),0)^2 as your pseudo R2? So that it would come out at 0 if the relationship went in the wrong direction? – Tom Wenseleers Mar 14 '18 at 14:53
• @TomWenseleers, I think that would hide the issue rather that aiding in understanding. Not using R^2 or at least understanding that it can give silly results is probably more helpful than just forcing it to fit a specific range. See fortunes 233, 252, 253, and 254. – Greg Snow Mar 14 '18 at 16:41
• Well R2 just measures how much better you can predict your y values compared to just drawing a flat line through them (which can be OK also for nls if your nls model allows for an intercept only model). But your predictions of course also have to go in the right direction, so it would seem to me that you can simply take this into account in the way I mentioned, without altering the interpretation really... – Tom Wenseleers Mar 14 '18 at 16:45

As a direct answer to the question asked (rather than argue that R2/pseudo R2 aren't useful) the `nagelkerke` function in the `rcompanion` package will report various pseudo R2 values for nonlinear least square (nls) models as proposed by McFadden, Cox and Snell, and Nagelkerke, e.g.

``````require(nls)
data(BrendonSmall)
quadplat = function(x, a, b, clx) {
ifelse(x  < clx, a + b * x   + (-0.5*b/clx) * x   * x,
a + b * clx + (-0.5*b/clx) * clx * clx)}
model = nls(Sodium ~ quadplat(Calories, a, b, clx),
data = BrendonSmall,
start = list(a   = 519,
b   = 0.359,
clx = 2304))
nullfunct = function(x, m){m}
null.model = nls(Sodium ~ nullfunct(Calories, m),
data = BrendonSmall,
start = list(m   = 1346))
nagelkerke(model, null=null.model)
``````

The `soilphysics` package also reports Efron's pseudo R2 and adjusted pseudo R2 value for `nls` models as 1 - RSS/TSS:

``````pred <- predict(model)
n <- length(pred)
res <- resid(model)
w <- weights(model)
if (is.null(w)) w <- rep(1, n)
rss <- sum(w * res ^ 2)
resp <- pred + res
center <- weighted.mean(resp, w)
r.df <- summary(model)\$df
int.df <- 1
tss <- sum(w * (resp - center)^2)
adj.r.sq <- 1 - (1 - r.sq) * (n - int.df) / r.df
out <- list(pseudo.R.squared = r.sq,
``````

which is also the `pseudo R2` as calculated by the `accuracy` function in the `rcompanion` package. Basically, this R2 measures how much better your fit becomes compared to if you would just draw a flat horizontal line through them. This can make sense for `nls` models if your null model is one that allows for an intercept only model. Also for particular other nonlinear models it can make sense. E.g. for a scam model that uses stricly increasing splines (bs="mpi" in the spline term), the fitted model for the worst possible scenario (e.g. where your data was strictly decreasing) would be a flat line, and hence would result in an `R2` of zero. Adjusted R2 then also penalize models with higher nrs of fitted parameters. Using the adjusted R2 value would already address a lot of the criticisms of the paper linked above, http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2892436/ (besides if one swears by using information criteria to do model selection the question becomes which one to use - AIC, BIC, EBIC, AICc, QIC, etc).

Just using

``````r.sq <- max(cor(y,yfitted),0)^2
adj.r.sq <- 1 - (1 - r.sq) * (n - int.df) / r.df
``````

I think would also make sense if you have normal Gaussian errors - i.e. the correlation between the observed and fitted y (clipped at zero, so that a negative relationship would imply zero predictive power) squared, and then adjusted for the nr of fitted parameters in the adjusted version. If `y` and `yfitted` go in the same direction this would be the `R2` and `adjusted R2` value as reported for a regular linear model. To me this would make perfect sense at least, so I don't agree with outright rejecting the usefulness of `pseudo R2` values for `nls` models as the answer above seems to imply.

For non-normal error structures (e.g. if you were using a GAM with non-normal errors) the `McFadden pseudo R2` is defined analogously as

``````1-residual deviance/null deviance
``````

See here and here for some useful discussion.

As an alternative to this problem I used at several times the following procedure:

1. compute a fit on data with the nls function
2. using the resulting model make predictions
3. Trace (plot...) the data against the values predicted by the model (if the model is good, points should be near the bissectrix).
4. Compute the R2 of the linear régression.

Best wishes to all. Patrick.