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r - Extracting data used to make a smooth plot in mgcv

This thread from a couple of years ago describes how to extract data used to plot the smooth components of a fitted gam model. It works, but only when there is one smooth variable. I've got more than one smooth variable, and unfortunately I can only extract the smooths from the last of the series. Here is an example:

library(mgcv)
a = rnorm(100)
b = runif(100)
y = a*b/(a+b)

mod = gam(y~s(a)+s(b))
summary(mod)

plotData <- list()
trace(mgcv:::plot.gam, at=list(c(25,3,3,3)), 
        #this gets you to the location where plot.gam calls plot.mgcv.smooth (see ?trace)
        #plot.mgcv.smooth is the function that does the actual plotting and
        #we simply assign its main argument into the global workspace
        #so we can work with it later.....
        quote({
                    #browser()
                    plotData <<- c(plotData, pd[[i]])
                }))
plot(mod,pages=1)
plotData

I'm trying to get the estimated smooth functions for both a and b, but the list plotData only gives me estimates for b. I've looked into the guts of the plot.gam function, and I'm having a difficult time understanding how it works. If anybody has already solved this problem, I'd be grateful.

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Updated Answer for mgcv >= 1.8-6

As of version 1.8-6 of mgcv, plot.gam() now returns the plotting data invisibly (from the ChangeLog):

  • plot.gam now silently returns a list of plotting data, to help advanced users (Fabian Scheipl) to produce custimized plot.

As such, and using mod from the example shown below in the original answer, one can do

> plotdata <- plot(mod, pages = 1)
> str(plotdata)
List of 2
 $ :List of 11
  ..$ x      : num [1:100] -2.45 -2.41 -2.36 -2.31 -2.27 ...
  ..$ scale  : logi TRUE
  ..$ se     : num [1:100] 4.23 3.8 3.4 3.05 2.74 ...
  ..$ raw    : num [1:100] -0.8969 0.1848 1.5878 -1.1304 -0.0803 ...
  ..$ xlab   : chr "a"
  ..$ ylab   : chr "s(a,7.21)"
  ..$ main   : NULL
  ..$ se.mult: num 2
  ..$ xlim   : num [1:2] -2.45 2.09
  ..$ fit    : num [1:100, 1] -0.251 -0.242 -0.234 -0.228 -0.224 ...
  ..$ plot.me: logi TRUE
 $ :List of 11
  ..$ x      : num [1:100] 0.0126 0.0225 0.0324 0.0422 0.0521 ...
  ..$ scale  : logi TRUE
  ..$ se     : num [1:100] 1.25 1.22 1.18 1.15 1.11 ...
  ..$ raw    : num [1:100] 0.859 0.645 0.603 0.972 0.377 ...
  ..$ xlab   : chr "b"
  ..$ ylab   : chr "s(b,1.25)"
  ..$ main   : NULL
  ..$ se.mult: num 2
  ..$ xlim   : num [1:2] 0.0126 0.9906
  ..$ fit    : num [1:100, 1] -0.83 -0.818 -0.806 -0.794 -0.782 ...
  ..$ plot.me: logi TRUE

The data therein can be used for custom plots etc.

The original answer below still contains useful code for generating the same sort of data used to generate these plots.


Original Answer

There are a couple of ways to do this easily, and both involve predicting from the model over the range of the covariates. The trick however is to hold one variable at some value (say its sample mean) whilst varying the other over its range.

The two methods involve:

  1. Predicting fitted responses for the data, including the intercept and all model terms (with the other covariates held at fixed values), or
  2. Predict from the model as above, but return the contributions of each term

The second of these is closer to (if not exactly what) plot.gam does.

Here is some code that works with your example and implements the above ideas.

library("mgcv")
set.seed(2)
a <- rnorm(100)
b <- runif(100)
y <- a*b/(a+b)
dat <- data.frame(y = y, a = a, b = b)

mod <- gam(y~s(a)+s(b), data = dat)

Now produce the prediction data

pdat <- with(dat,
             data.frame(a = c(seq(min(a), max(a), length = 100),
                              rep(mean(a), 100)),
                        b = c(rep(mean(b), 100),
                              seq(min(b), max(b), length = 100))))

Predict fitted responses from the model for new data

This does bullet 1 from above

pred <- predict(mod, pdat, type = "response", se.fit = TRUE)

> lapply(pred, head)
$fit
        1         2         3         4         5         6 
0.5842966 0.5929591 0.6008068 0.6070248 0.6108644 0.6118970 

$se.fit
       1        2        3        4        5        6 
2.158220 1.947661 1.753051 1.579777 1.433241 1.318022

You can then plot $fit against the covariate in pdat - though do remember I have predictions holding b constant then holding a constant, so you only need the first 100 rows when plotting the fits against a or the second 100 rows against b. For example, first add fitted and upper and lower confidence interval data to the data frame of prediction data

pdat <- transform(pdat, fitted = pred$fit)
pdat <- transform(pdat, upper = fitted + (1.96 * pred$se.fit),
                        lower = fitted - (1.96 * pred$se.fit))

Then plot the smooths using rows 1:100 for variable a and 101:200 for variable b

layout(matrix(1:2, ncol = 2))
## plot 1
want <- 1:100
ylim <- with(pdat, range(fitted[want], upper[want], lower[want]))
plot(fitted ~ a, data = pdat, subset = want, type = "l", ylim = ylim)
lines(upper ~ a, data = pdat, subset = want, lty = "dashed")
lines(lower ~ a, data = pdat, subset = want, lty = "dashed")
## plot 2
want <- 101:200
ylim <- with(pdat, range(fitted[want], upper[want], lower[want]))
plot(fitted ~ b, data = pdat, subset = want, type = "l", ylim = ylim)
lines(upper ~ b, data = pdat, subset = want, lty = "dashed")
lines(lower ~ b, data = pdat, subset = want, lty = "dashed")
layout(1)

This produces

enter image description here

If you want a common y-axis scale then delete both ylim lines above, replacing the first with:

ylim <- with(pdat, range(fitted, upper, lower))

Predict the contributions to the fitted values for the individual smooth terms

The idea in 2 above is done in almost the same way, but we ask for type = "terms".

pred2 <- predict(mod, pdat, type = "terms", se.fit = TRUE)

This returns a matrix for $fit and $se.fit

> lapply(pred2, head)
$fit
        s(a)       s(b)
1 -0.2509313 -0.1058385
2 -0.2422688 -0.1058385
3 -0.2344211 -0.1058385
4 -0.2282031 -0.1058385
5 -0.2243635 -0.1058385
6 -0.2233309 -0.1058385

$se.fit
      s(a)      s(b)
1 2.115990 0.1880968
2 1.901272 0.1880968
3 1.701945 0.1880968
4 1.523536 0.1880968
5 1.371776 0.1880968
6 1.251803 0.1880968

Just plot the relevant column from $fit matrix against the same covariate from pdat, again using only the first or second set of 100 rows. Again, for example

pdat <- transform(pdat, fitted = c(pred2$fit[1:100, 1], 
                                   pred2$fit[101:200, 2]))
pdat <- transform(pdat, upper = fitted + (1.96 * c(pred2$se.fit[1:100, 1], 
                                                   pred2$se.fit[101:200, 2])),
                        lower = fitted - (1.96 * c(pred2$se.fit[1:100, 1], 
                                                   pred2$se.fit[101:200, 2])))

Then plot the smooths using rows 1:100 for variable a and 101:200 for variable b

layout(matrix(1:2, ncol = 2))
## plot 1
want <- 1:100
ylim <- with(pdat, range(fitted[want], upper[want], lower[want]))
plot(fitted ~ a, data = pdat, subset = want, type = "l", ylim = ylim)
lines(upper ~ a, data = pdat, subset = want, lty = "dashed")
lines(lower ~ a, data = pdat, subset = want, lty = "dashed")
## plot 2
want <- 101:200
ylim <- with(pdat, range(fitted[want], upper[want], lower[want]))
plot(fitted ~ b, data = pdat, subset = want, type = "l", ylim = ylim)
lines(upper ~ b, data = pdat, subset = want, lty = "dashed")
lines(lower ~ b, data = pdat, subset = want, lty = "dashed")
layout(1)

This produces

enter image description here

Notice the subtle difference here between this plot and the one produced earlier. The first plot include both the effect of the intercept term and the contribution from the mean of b. In the second plot, only the value of the smoother for a is shown.


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