# Decision Boundary from sklearn

Suppose that we have a simple training case and training targets for SVM

``````from sklearn import svm
>>> X = [[0, 0], [2, 2]]
>>> y = [0.5, 2.5]
>>> clf = svm.SVR()
>>> clf.fit(X, y)
SVR(C=1.0, cache_size=200, coef0=0.0, degree=3,
epsilon=0.1, gamma=0.0, kernel='rbf', max_iter=-1, probability=False,
random_state=None, shrinking=True, tol=0.001, verbose=False)
>>> clf.predict([[1, 1]])
array([ 1.5])
``````

How could we get the decision boundary with the no linear 'rbf' kernel? We could get the support vectors by clf.suppport_vectors_ However, what is the correspondonce between support vectors and decision boundary equations?

Thanks,

-

First, SVM constructs a hyperplane `w`, which is then used for separating data by calculating the inner product `<w,x>` and checking the sign of `<w,x>+b` (where `b` is a trained threshold). While in the linear case we can simply reconstruct the `w` by taking `SUM y_i alpha_i x_i`, where `x_i` are support vectors, `y_i` their classes and `alpha_i` the dual coefficient found in the optimization process, it is much more complex when we are dealing with infinitely dimensional space induced by RBF kernel. The so called kernel trick shows, that we can calculate the inner product `<w,x>+b` using a kernel easily, so we can classify without computing the actual `w`. So what is `w` exactly? It is a linear combination of gaussians centered in support vectors (some of which have negative coefficients). You can again compute `SUM y_i alpha_i f(x_i)`, where `f` is a feature projection (in this case it would be a function returning gaussian distribution centered in given point, with variance equal to `1/(2gamma)`. The actual decision boundary is now described as points where the inner product of this function and the gaussian centered in this point is equal to `-b`.