Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I want to train an SVM classifier in R and be able to use it in other software by exporting the relevant parameters. To do so, I first want to be able to reproduce the behavior of predict.svm() in R (using the e1071 package).

I trained the model based on the iris data.

data(iris)

# simplify the data by removing the third label
ir <- iris[1:100,]
ir$Species <- as.factor(as.integer(ir$Species))

# train the model
m <- svm(Species ~ ., data=ir, cost=8)

# the model internally uses a scaled version of the data, example:
m$x.scale
# # # # # 
# $`scaled:center`
# Sepal.Length  Sepal.Width Petal.Length  Petal.Width 
#        5.471        3.099        2.861        0.786 
#
# $`scaled:scale`
# Sepal.Length  Sepal.Width Petal.Length  Petal.Width 
#    0.6416983    0.4787389    1.4495485    0.5651531 
# # # # #

# because the model uses scaled data, make a scaled data frame
irs<-ir;
sc<-data.frame(m$x.scale);
for(col in row.names(sc)){
      irs[[col]]<-(ir[[col]]-sc[[col,1]])/sc[[col,2]]
}

# a radial kernel function
k<-function(x,x1,gamma){
    return(exp(-gamma*sum((x-x1)^2)))
}

According to Hastie, Tibshirani, Friedman (2001), equation 12.24, the prediction function of x can be written as the sum over the support vectors of the coefficient times the kernel function of the SV and x, which corresponds to a matrix product, plus the intercept.

$\hat{f}(x)= \sum^N_{i=1} \hat{\alpha}_i y_i K(x,x_i)+\hat{\beta}_0 $, where $y_i$ is already contained in m$coefs.

# m$coefs contains the coefficients of the support vectors, m$SV 
# the support vectors, and m$rho the *negative* intercept
f<-function(x,m){
    return(t(m$coefs) %*% as.matrix(apply(m$SV,1,k,x,m$gamma)) - m$rho)
}

# a prediction function based on the sign of the prediction function
my.predict<-function(m,x){
    apply(x,1,function(y) sign(f(y,m)))
}

# applying my prediction function to the scaled data frame should
# yield the same result as applying predict.svm() to the original data
# example, thus the table should show one-to-one correspondence:
table(my.predict(m,irs[,1:4]),predict(m,ir[,1:4]))

# the unexpected result:    
# # # # #
#      1  2
#  -1  4 24
#  1  46 26
# # # # #

Who can explain where this is going wrong?

Edit: there was a minor error in my code, it now gives the following, expected result:

      1  2
  -1  0 50
  1  50  0

I hope to be of help to anyone facing the same problem.

share|improve this question
    
When is the ir data.frame scaled? Any which scaling is applied? –  sdir Jan 17 '13 at 9:20
    
The svm function applies scaling to each training attribute such that the mean is zero and the variance one. During prediction, it scales the input attributes with the same factor - so that the user doesn't have to know about the scaling. I will put an example of m$x.scale in the question. –  roelandvanbeek Jan 17 '13 at 9:58
    
I truely don't see any error. My guess is that function f is wrong. The rest seems to be OK. I once had the same problem, but don't remember how I fixed it. You could have a look at the svm's predict function, and see whats the difference there. –  sdir Jan 17 '13 at 10:16
    
Nevermind, the problem was in the subscript of x in my.predict. Fixed that, it works now. Should I remove the question or leave it here because it apparently does present useful code for people working with svm in R? –  roelandvanbeek Jan 17 '13 at 10:22
    
Leave it there please. I find it very usefull! –  sdir Jan 17 '13 at 10:28

1 Answer 1

up vote 0 down vote accepted

There was a minor error in one of my functions. The edited version works.

share|improve this answer

Your Answer

 
discard

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.