Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I used svm to find a hyperplane best fit regression dependent on q, where I have 4 dimensions: x, y, z, q.

fit <- svm(q ~ ., data=data,kernel='linear')

and here is my fit object:

svm(formula = q ~ ., data = data, kernel = "linear")

   SVM-Type:  C-classification 
 SVM-Kernel:  linear 
       cost:  1 
      gamma:  0.3333333 

Number of Support Vectors:  1800

I have a 3d plot of my data, where the 4th dimension is color, using plot3d. How can I overlay the hyperplane that svm found? How can I plot the hyperplane? I'd like to visualize the regress hyperplane.

share|improve this question
Um....1 response, 1 covariate: best fit line. 1 response, 2 covariates: best fit plane. 1 response, 3 covariates: ?. – joran Nov 5 '11 at 2:46
@joran: I would say the answer is "small multiples" or coplots: supposing we have predictors (x,y,z) and response w, plot the (x,y,w) dividing plane in a number of subplots for regions (z1,z2), (z2,z3) ... -- not trivial though. That or use dynamic graphics a la ggobi ... – Ben Bolker Nov 5 '11 at 12:45
I wonder, who minused CodeGuy. Even, if it is 10-dimensional, this question could be meant as how should I visualize this, etc.. more over, there are publications devoted to high-dimensinal visualization. – Max Nov 5 '11 at 16:31
@joran: This isn't too odd nor unusual given a classification context. In a 2-D plane, one can have positive and negative instances that are split by a line, so there is 1 response, 2 predictors, and one can color the points based on whether these are negative/positive (or 0/1) outcomes. For 3 predictors, 3 dimensional space to plot the predictors and one can color or shade the points based on the response. In other words, the response need not increase the algebraic dimensionality. – Iterator Nov 5 '11 at 20:59
@CodeGuy Like Max, I think you are doing classification, not regression. If this is not the case, can you please include the output of str(data) and summary(data)? – Iterator Nov 5 '11 at 21:03
up vote 34 down vote accepted

You wrote:

I used svm to find a hyperplane best fit regression

But according to:

svm(formula = q ~ ., data = data, kernel = "linear")

SVM-Type:  C-classification

you are doing classification.

So, first of all decide what you need: to classify or to fit regression, from ?svm, we see:

type: ‘svm’ can be used as a classification machine, as a
      regression machine, or for novelty detection.  Depending of
      whether ‘y’ is a factor or not, the default setting for
      ‘type’ is ‘C-classification’ or ‘eps-regression’,
      respectively, but may be overwritten by setting an explicit

As I believe you didn't change the parameter type from its default value, you are probably solving classification, so, I will show how to visualize this for classification.

Let's assume there are 2 classes, generate some data:

> require(e1071) # for svm()                                                                                                                                                          
> require(rgl) # for 3d graphics.                                                                                                                                                                                    
> set.seed(12345)                                                                                                                                                                     
> seed <- .Random.seed                                                                                                                                                                
> t <- data.frame(x=runif(100), y=runif(100), z=runif(100), cl=NA)
> t$cl <- 2 * t$x + 3 * t$y - 5 * t$z                                                                                                                                                 
> t$cl <- as.factor(ifelse(t$cl>0,1,-1))
> t[1:4,]
           x         y         z cl
 1 0.7209039 0.2944654 0.5885923 -1
 2 0.8757732 0.6172537 0.8925918 -1
 3 0.7609823 0.9742741 0.1237949  1
 4 0.8861246 0.6182120 0.5133090  1

Since you want kernel='linear' the boundary must be w1*x + w2*y + w3*z - w0 - hyperplane. Our task divides to 2 subtasks: 1) to evaluate equation of this boundary plane 2) draw this plane.

1) Evaluating the equation of boundary plane

First, let's run svm():

> svm_model <- svm(cl~x+y+z, t, type='C-classification', kernel='linear',scale=FALSE)

I wrote here explicitly type=C-classification just for emphasis we want do classification. scale=FALSE means that we want svm() to run directly with provided data without scaling data (as it does by default). I did it for future evaluations that become simpler.

Unfortunately, svm_model doesn't store the equation of boundary plane (or just, normal vector of it), so we must evaluate it. From svm-algorithm we know that we can evaluate such weights with following formula:

w <- t(svm_model$coefs) %*% svm_model$SV

The negative intercept is stored in svm_model, and accessed via svm_model$rho.

2) Drawing plane.

I didn't find any helpful function plane3d, so, again we should do some handy work. We just take grid of pairs (x,y) and evaluate the appropriate value of z of the boundary plane.

detalization <- 100                                                                                                                                                                 
grid <- expand.grid(seq(from=min(t$x),to=max(t$x),length.out=detalization),                                                                                                         
z <- (svm_model$rho- w[1,1]*grid[,1] - w[1,2]*grid[,2]) / w[1,3]

plot3d(grid[,1],grid[,2],z)  # this will draw plane.
# adding of points to the graphics.
points3d(t$x[which(t$cl==-1)], t$y[which(t$cl==-1)], t$z[which(t$cl==-1)], col='red')
points3d(t$x[which(t$cl==1)], t$y[which(t$cl==1)], t$z[which(t$cl==1)], col='blue')

We did it with rgl package, you can rotate this image and enjoy it :)

enter image description here

share|improve this answer
+1 Excellent job. This is the way to do it. – Iterator Nov 5 '11 at 21:02
Hi Thank you so much. However, I wanted to do a regression. Could you provide code for this? Again, thank you so much – CodeGuy Nov 7 '11 at 23:55

I'm just starting out in R myself, but there's a decent tutorial on using the e1071 package in R for regression rather than classification:


with a zip file of the test dataset and R script in:


Skip the first section on Tanagra and head straight to section 6 (page 14). It has its faults, but it gives examples of using R for linear regression, SVR with epsilon-regression and with nu-regression. It also makes a stab at demonstrating the tune() method (but could be done better, IMHO).

(Note: if you choose to run the examples in that paper, don't bother trying to find a working copy of xlsReadWrite -- it's much easier to export qsar.xls as a .csv file and just use read.csv() to load the dataset.)

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.