# How get plot from nls in R?

In R I use nls to do a nonlinear least-squares fit. How then do I plot the model function using the values of the coefficients that the fit provided?

(Yes, this is a very naive question from an R relative newbie.)

• Scroll down near the bottom of ?nls and there's an example for you. Commented Mar 29, 2012 at 3:48
• Sorry, but the example there is of little help; I just don't understand what several of the arguments to plot and lines there mean. Please help! My data frame is called xy, with components x and y, and has dim(xy) being 17 2. And I've named fitted the result of the nls call. How do I plot the model function for the found values of the coefficients, along with the original data points? Commented Mar 29, 2012 at 13:22
• @Murray: Take a look at this line from an example: lines(x, predict(nlmod), col=2) . This works because predict knows how to calculate the predicted y-values from the output of nls . Alternatively, take a little time to sift through all the components of your fitted object, find the coefficients, and use them to write your own fit-function. That will give you some confidence that nls did what you want. Commented Mar 29, 2012 at 14:03

Using the first example from ?nls and following the example I pointed you to line by line achieves the following:

#This is just our data frame
DNase1 <- subset(DNase, Run == 1)
DNase1\$lconc <- log(DNase1\$conc)
#Fit the model
fm1DNase1 <- nls(density ~ SSlogis(lconc, Asym, xmid, scal), DNase1)

#Plot the original points
# first argument is the x values, second is the y values
plot(DNase1\$lconc,DNase1\$density)

# once again, first argument is x values, second is y values
lines(DNase1\$lconc,predict(fm1DNase1))

The predict method for a nls argument is automatically returning the fitted y values. Alternatively, you add a step and do

yFitted <- predict(fm1DNase1)

and pass yFitted in the second argument to lines instead. The result looks like this:

Or if you want a "smooth" curve, what you do is to simply repeat this but evaluate the function at more points:

r <- range(DNase1\$lconc)
xNew <- seq(r[1],r[2],length.out = 200)
yNew <- predict(fm1DNase1,list(lconc = xNew))

plot(DNase1\$lconc,DNase1\$density)
lines(xNew,yNew)
• No, the lines is \$not\$ what I wanted to plot (along with the original data points). Rather, I wanted to plot the model function using the values of the coefficients found from the call to nls. How to I extract those coefficients? And then how do I substitute them into the form of the model function? Specifically, the model is y ~ k * x^n. I now want to plot the (smooth) curve given by the equation y = k * x^n with the values of k and n as found from nls. Commented Mar 29, 2012 at 19:21
• @murray Um...calling lines(...,predict()) does exactly what you just described. Commented Mar 29, 2012 at 19:24
• @murray Namely, it evaluates the fitted function, using the estimated coefficients, as the original data points. If you want the function evaluated at different points, you'll have to supply them to predict. Commented Mar 29, 2012 at 19:25
• For the values of the coefficients found by nls, I want to plot the resulting model as a smooth function for those coefficients -- the same way I'd plot, say, y = 5*x^2. Is there no way to plot a function in R without explicitly giving a list of x-values? Commented Mar 29, 2012 at 19:55
• thanks for all the responses! I'm well aware that to a computer there's no such thing as a smooth curve for plotting -- that it's all just sampling points and drawing segments (and ultimately, mapping that to appropriate pixels). But with systems such as Mathematica, I don't have to think about that and instead can work at a "higher" level of abstraction, namely, simply asking for a plot of a function and letting the system do all the dirty work (including adaptive sampling of input values according to rapidity of change of values). Commented Mar 30, 2012 at 0:21

coef(x) returns the coefficients for regression results x.

model<-nls(y~a+b*x^k,my.data,list(a=0.,b=1.,k=1))
plot(y~x,my.data)
a<-coef(model)[1]
b<-coef(model)[2]
k<-coef(model)[3]
lines(x<-c(1:10),a+b*x^k,col='red')

For example.

I know what you want (I'm a Scientist). This isn't it, but at least shows how to use 'curve' to plot your fitting function over any range, and the curve will be smooth. Using the same data set as above:

nonlinFit <- nls(density ~ a - b*exp(-c*conc), data = DNase1, start = list(a=1, b=1, c=1) )

fitFnc <- function(x) predict(nonlinFit, list(conc=x))

curve(fitFnc, from=.5, to=10)

or,

curve(fitFnc, from=8.2, to=8.4)

or,

curve(fitFnc, from=.1, to=50) # well outside the data range

or whatever (without setting up a sequence of evaluation points first).

I'm a rudimentary R programmer, so I don't know how to implement (elegantly) something like ReplaceAll ( /. ) in Mathematica that one would use to replace occurrences of the symbolic parameters in the model, with the fitted parameters. This first step works although it looks horrible:

myModel <- "a - b*exp(-c*conc)"

nonlinFit <- nls(as.formula(paste("density ~", myModel)), data = DNase1, start = list(a=1, b=1, c=1) )

It leaves you with a separate 'model' (as a character string), that you might be able to make use of with the fitted parameters ... cleanly (NOT digging out a, b, c) would simply use nonlinFit ... not sure how though.

### To give some context:

there are two main approaches to get the predicted values to plot. Choose either one depending on what you want to have control over:

• specifying a interpolation vector of x values (tt) and predicting the y values using the model with the predict function
• pulling the coefficients from the model and running the right side of our model expression on them
# Data:
x = c(0,20,40,60,80,100,120,140) # sample timepoints
C = c(147.8,78.3,44.7,29.5,15.2,7.8,3.2,3.9) # concentratios
data <- data.frame(C,x) # data we got

# plot empirical data:
opar <- par(las = 1) # plot params to rotate ylabels
plot(C~x, data = data, col = 2, pch=3)

# modeling
mod <- formula(C ~ C0*exp(-k*x))
fit <- nls(mod, data, start=list(C0=100,k=0.1)) # fit model to data
# plot(profile(fit)) # profile iterations

## Plotting of the model:

# interpolation vector tt
t0 = min(data\$x)
tmax = max(data\$x)
niter = 301
tt <- seq(t0, tmax,length.out=niter)

#  using tt with predict to plot lines:
lines(tt, predict(fit, list(x = tt)),lty=4)

# using coefficents and curve (no tt vector nor niter needed) :
C0 <- coefficients(fit)["C0"] # extract coefficent initialC
k <-coefficients(fit)["k"] # extract coefficent k