# scatterplot3d: regression plane with residuals

Using `scatterplot3d` in R, I'm trying to draw red lines from the observations to the regression plane:

``````wh <- iris\$Species != "setosa"
x  <- iris\$Sepal.Width[wh]
y  <- iris\$Sepal.Length[wh]
z  <- iris\$Petal.Width[wh]
df <- data.frame(x, y, z)

LM <- lm(y ~ x + z, df)
library(scatterplot3d)
G  <- scatterplot3d(x, z, y, highlight.3d = FALSE, type = "p")
G\$plane3d(LM, draw_polygon = TRUE, draw_lines = FALSE)
`````` To obtain the 3D equivalent of the following picture: In 2D, I could just use `segments`:

``````pred  <- predict(model)
segments(x, y, x, pred, col = 2)
``````

But in 3D I got confused with the coordinates.

Using the dataset from here, you can do

``````advertising_fit1 <- lm(sales~TV+radio, data = advertising)
angle = 45)
# polygon_args = list(col = rgb(.1, .2, .7, .5)) # Fill color
i.negpos <- 1 + (resid(advertising_fit1) > 0)
segments(orig\$x, orig\$y, plane\$x, plane\$y,
col = c("blue", "red")[i.negpos],
lty = 1) # (2:1)[i.negpos]
angle = 45,
grid = c("xy", "xz", "yz"))
`````` And another interactive version using `rgl` package

``````rgl::plot3d(advertising\$TV,
xlab = "TV",
zlab = "Sales", site = 5, lwd = 15)
advertising_fit1\$coefficients["(Intercept)"], alpha = 0.3, front = "line")
col = c("blue", "red")[i.negpos],
lty = 1) # (2:1)[i.negpos]
rgl::rgl.postscript("./pics/plot-advertising-rgl.pdf","pdf") # does not really work...
`````` • This is great! I fixed this eventually with some very ugly code. Thank you for this simpler solution, it will make it a lot easier to make an example for students. – Frans Rodenburg Aug 15 '18 at 15:23
• @FransRodenburg See my edit! I could get the plane filled in the first version. If you find a way, please let me know! – Christoph Aug 15 '18 at 17:18
• Sure, I will write my own adaptation as an answer. Unfortunately `scatterplot3d` forces several arguments such as `cex`, `cex.main`, `cex.lab`, cex.axis`, so in the actual document I ended up just copying the entire function from github and adjusting it from there. – Frans Rodenburg Aug 16 '18 at 1:33

I decided to include my own implementation as well, in case anyone else wants to use it.

## The Regression Plane

``````require("scatterplot3d")

# Data, linear regression with two explanatory variables
wh <- iris\$Species != "setosa"
x  <- iris\$Sepal.Width[wh]
y  <- iris\$Sepal.Length[wh]
z  <- iris\$Petal.Width[wh]
df <- data.frame(x, y, z)
LM <- lm(y ~ x + z, df)

# scatterplot
s3d <- scatterplot3d(x, z, y, pch = 19, type = "p", color = "darkgrey",
main = "Regression Plane", grid = TRUE, box = FALSE,
mar = c(2.5, 2.5, 2, 1.5), angle = 55)

# regression plane
s3d\$plane3d(LM, draw_polygon = TRUE, draw_lines = TRUE,
polygon_args = list(col = rgb(.1, .2, .7, .5)))

# overlay positive residuals
wh <- resid(LM) > 0
s3d\$points3d(x[wh], z[wh], y[wh], pch = 19)
`````` ## The Residuals

``````# scatterplot
s3d <- scatterplot3d(x, z, y, pch = 19, type = "p", color = "darkgrey",
main = "Regression Plane", grid = TRUE, box = FALSE,
mar = c(2.5, 2.5, 2, 1.5), angle = 55)

# compute locations of segments
orig     <- s3d\$xyz.convert(x, z, y)
plane    <- s3d\$xyz.convert(x, z, fitted(LM))
i.negpos <- 1 + (resid(LM) > 0) # which residuals are above the plane?

# draw residual distances to regression plane
segments(orig\$x, orig\$y, plane\$x, plane\$y, col = "red", lty = c(2, 1)[i.negpos],
lwd = 1.5)

# draw the regression plane
s3d\$plane3d(LM, draw_polygon = TRUE, draw_lines = TRUE,
polygon_args = list(col = rgb(0.8, 0.8, 0.8, 0.8)))

# redraw positive residuals and segments above the plane
wh <- resid(LM) > 0
segments(orig\$x[wh], orig\$y[wh], plane\$x[wh], plane\$y[wh], col = "red", lty = 1, lwd = 1.5)
s3d\$points3d(x[wh], z[wh], y[wh], pch = 19)
`````` ## The End Result:

While I really appreciate the convenience of the `scatterplot3d` function, in the end I ended up copying the entire function from github, since several arguments that are in base `plot` are either forced by or not properly passed to `scatterplot3d` (e.g. axis rotation with `las`, character expansion with `cex`, `cex.main`, etc.). I am not sure whether such a long and messy chunk of code would be appropriate here, so I included the MWE above.

Anyway, this is what I ended up including in my book: (Yes, that is actually just the iris data set, don't tell anyone.)