I am interested in test the SVM performance to classify several individuals into four groups/classes. When using the svmtrain LibSVM function from MATLAB, I am able to get the three equations used to classify those individuals among the 4 groups, based on the values of this equation. An scheme could be as follows:

                All individuals (N)*
 Group 1 (n1) <--- equation 1 --->  (N-n1)
                   (N-n1-n2) <--- equation 2 ---> Group 2 (n2)
Group 3 (n3) <--- equation 3 ---> Group 4(n4)

*N = n1+n2+n3+n4

Is there any way to get these equations using the svm function in the e1071 R package?


svm in e1071 uses the "one-against-one" strategy for multiclass classification (i.e. binary classification between all pairs, followed by voting). So to handle this hierarchical setup, you probably need to do a series of binary classifiers manually, like group 1 vs. all, then group 2 vs. whatever is left, etc.. Additionally, the basic svm function does not tune the hyperparameters, so you will typically want to use a wrapper like tune in e1071, or train in the excellent caret package.

Anyway, to classify new individuals in R, you don't have to plug numbers into an equation manually. Rather, you use the predict generic function, which has methods for different models like SVM. For model objects like this, you can also usually use the generic functions plot and summary. Here is an example of the basic idea using a linear SVM:


# Subset the iris dataset to only 2 labels and 2 features
iris.part = subset(iris, Species != 'setosa')
iris.part$Species = factor(iris.part$Species)
iris.part = iris.part[, c(1,2,5)]

# Fit svm model
fit = svm(Species ~ ., data=iris.part, type='C-classification', kernel='linear')

# Make a plot of the model
dev.new(width=5, height=5)
plot(fit, iris.part)

# Tabulate actual labels vs. fitted labels
pred = predict(fit, iris.part)
table(Actual=iris.part$Species, Fitted=pred)

# Obtain feature weights
w = t(fit$coefs) %*% fit$SV

# Calculate decision values manually
iris.scaled = scale(iris.part[,-3], fit$x.scale[[1]], fit$x.scale[[2]]) 
t(w %*% t(as.matrix(iris.scaled))) - fit$rho

# Should equal...

enter image description here

Tabulate actual class labels vs. model predictions:

> table(Actual=iris.part$Species, Fitted=pred)
Actual       versicolor virginica
  versicolor         38        12
  virginica          15        35

Extract feature weights from svm model object (for feature selection, etc.). Here, Sepal.Length is obviously more useful.

> t(fit$coefs) %*% fit$SV
     Sepal.Length Sepal.Width
[1,]    -1.060146  -0.2664518

To understand where the decision values come from, we can calculate them manually as the dot product of the feature weights and the preprocessed feature vectors, minus the intercept offset rho. (Preprocessed means possibly centered/scaled and/or kernel transformed if using RBF SVM, etc.)

> t(w %*% t(as.matrix(iris.scaled))) - fit$rho
51 -1.3997066
52 -0.4402254
53 -1.1596819
54  1.7199970
55 -0.2796942
56  0.9996141

This should equal what is calculated internally:

> head(fit$decision.values)
51           -1.3997066
52           -0.4402254
53           -1.1596819
54            1.7199970
55           -0.2796942
56            0.9996141
  • Thanks for you answer, John. The reason because I want to know these equations is to assess which parameters from the total have more importance when classifying my events. – Manuel Ramón Oct 19 '11 at 9:53
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    @ManuelRamón Ahh gotcha. Those are called the "weights" for a linear SVM. See edit above for how to calculate from an svm model object. Good luck! – John Colby Oct 19 '11 at 18:22
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    Your example has only two categories (versicolor and virginica) and you got a vector with two coeffcients, one for each variable used to classify the iris data. If I have N categories I get N-1 vectors from with(fit, t(coefs) %*% SV). What is the meaning of each vector? – Manuel Ramón Oct 21 '11 at 16:45
  • The length of the weights vector will be equal to the number of features that were actually used to fit the SVM. If you used the formula interface and factor features, your input features get processed into numeric dummy variables via model.matrix(). Thus, if you have a factor feature with 3 levels, it will get processed into only two final features. That is probably where your N-1 is coming from. – John Colby Oct 21 '11 at 17:24
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    Ohh I see...you decided to go with the multi-class mode up front. I see what you're saying - if running on the full iris data, coefs only has two columns, where I would have expected 3. rho has 3 values and decision.values has 3 columns as well (for the 3 one vs. one binary classifiers). See above for how to calculate the decision values manually, but so far I can't reproduce what is stored in decision.values from any combination of those 2 coefs sets and 3 rho values. I'm stumped here at the moment... – John Colby Oct 23 '11 at 6:54

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