I want to graphically show the assumptions of linear (and later other type) regression. How can I add to my plot small Gaussian densities (or any type of densities) on a regression line just like in this figure:

enter image description here

  • you might get some help from stats.stackexchange.com too Aug 3, 2015 at 19:36
  • 1
    This question is pretty related. If you modified the hist in my answer to use dnorm instead of data, it might get you kinda close using base plots. Aug 3, 2015 at 20:13
  • Did you want it to be based on the underlying data (even if simulated)? Or are you content to plot perfect little dnorms at regularly spaced intervals? Aug 3, 2015 at 20:13
  • I am thinking about perfect little 'dnorm'. In next step I want to do the same for GLM and GAMLSS models.
    – Maju116
    Aug 3, 2015 at 21:02

1 Answer 1


You can compute the empirical densities of the residuals for sections along a fitted line. Then, it is just a matter of drawing the lines at the positions of your choosing in each interval using geom_path. To add theoretical distribution, generate some densities along the range of the residuals for each section (here using normal density). For the Normal densities below, the standard deviation for each one is determined for each section from the residuals, but you could just choose a standard deviation for all of them and use that instead.

## Sample data
dat <- data.frame(x=(x=runif(100, 0, 50)),
                  y=rnorm(100, 10*x, 100))

## breaks: where you want to compute densities
breaks <- seq(0, max(dat$x), len=5)
dat$section <- cut(dat$x, breaks)

## Get the residuals
dat$res <- residuals(lm(y ~ x, data=dat))

## Compute densities for each section, and flip the axes, and add means of sections
## Note: the densities need to be scaled in relation to the section size (2000 here)
dens <- do.call(rbind, lapply(split(dat, dat$section), function(x) {
    d <- density(x$res, n=50)
    res <- data.frame(x=max(x$x)- d$y*2000, y=d$x+mean(x$y))
    res <- res[order(res$y), ]
    ## Get some data for normal lines as well
    xs <- seq(min(x$res), max(x$res), len=50)
    res <- rbind(res, data.frame(y=xs + mean(x$y),
                                 x=max(x$x) - 2000*dnorm(xs, 0, sd(x$res))))
    res$type <- rep(c("empirical", "normal"), each=50)
dens$section <- rep(levels(dat$section), each=100)

## Plot both empirical and theoretical
ggplot(dat, aes(x, y)) +
  geom_point() +
  geom_smooth(method="lm", fill=NA, lwd=2) +
  geom_path(data=dens, aes(x, y, group=interaction(section,type), color=type), lwd=1.1) +
  theme_bw() +
  geom_vline(xintercept=breaks, lty=2)

enter image description here

Or, just gaussian curves

## Just normal
ggplot(dat, aes(x, y)) +
  geom_point() +
  geom_smooth(method="lm", fill=NA, lwd=2) +
  geom_path(data=dens[dens$type=="normal",], aes(x, y, group=section), color="salmon", lwd=1.1) +
  theme_bw() +
  geom_vline(xintercept=breaks, lty=2)

enter image description here

  • this is great code, thanks!! I have one remark: Linear regression assumes homogeneity of variance. Those gaussian distributions must be forced to have equal variance but they dont. This can be misleading when the goal is to illustrate regression.
    – Jaynes01
    Jul 8, 2022 at 13:48

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