`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:

```
require(e1071)
# 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...
fit$decision.values
```

Tabulate actual class labels vs. model predictions:

```
> table(Actual=iris.part$Species, Fitted=pred)
Fitted
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
[,1]
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)
versicolor/virginica
51 -1.3997066
52 -0.4402254
53 -1.1596819
54 1.7199970
55 -0.2796942
56 0.9996141
...
```