A geometric margin is simply the euclidean distance between a certain x (data point) to the hyperlane.

What is the intuitive explanation to what a functional margin is?

Note: I realize that a similar question has been asked here: How to understand the functional margin in SVM ?

However, the answer given there explains the equation, but not its meaning (as I understood it).

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    better suited for cross validated – CentAu Apr 30 '15 at 17:03

"A geometric margin is simply the euclidean distance between a certain x (data point) to the hyperlane. "

I don't think that is a proper definition for the geometric margin, and I believe that is what is confusing you. The geometric margin is just a scaled version of the functional margin.

You can think the functional margin, just as a testing function that will tell you whether a particular point is properly classified or not. And the geometric margin is functional margin scaled by ||w||

If you check the formula:

enter image description here

You can notice that independently of the label, the result would be positive for properly classified points (e.g sig(1*5)=1 and sig(-1*-5)=1) and negative otherwise. If you scale that by ||w|| then you will have the geometric margin.

Why does the geometric margin exists?

Well to maximize the margin you need more that just the sign, you need to have a notion of magnitude, the functional margin would give you a number but without a reference you can't tell if the point is actually far away or close to the decision plane. The geometric margin is telling you not only if the point is properly classified or not, but the magnitude of that distance in term of units of |w|

  • Thanks @Pedrom! I really appreciate your reply. A question: "The geometric margin is telling you [...] the magnitude of that distance in term of units of |w|" - then it sort of is the distance of a data point from the hyperlane? Sorry, I know you said it's incorrect but it sounds like you're saying something similar... Thanks again! – Cheshie Nov 18 '13 at 22:58
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    @Cheshie You can think of it as a distance quantity but it is not an euclidean distance for sure (upload.wikimedia.org/math/a/0/5/…). The obvious difference is that a euclidean distance is a positive number and the geometric margin has a sign. The important thing here is that the functional margin is an unscaled version of the geometric margin. – Pedrom Nov 18 '13 at 23:22

Check Andrew Ng's Lecture Notes from Lecture 3 on SVMs (notation changed to make it easier to type without mathjax/TeX on this site):

"Let’s formalize the notions of the functional and geometric margins . Given a training example (x_i, y_i) we define the functional margin of (w, b) with respect to the training example

gamma_i = y_i( (w^T)x_i + b )

Note that if y_i > 0 then for the functional margin to be large (i.e., for our prediction to be confident and correct), we need (w^T)x + b to be a large positive number. Conversely, if y_i < 0, then for the functional margin to be large, we need (w^T)x + b to be a large negative number. Moreover, if

y_i( (w^T)x_i + b) > 0

then our prediction on this example is correct. (Check this yourself.) Hence, a large functional margin represents a confident and a correct prediction."

Page 3 from the Lecture 3 PDF linked at the materials page linked above.

  • Yeah, thanks, I read that... that's what got me confused in the first place ;) – Cheshie Nov 18 '13 at 23:00

enter image description here

Functional margin represents the correctness; and confidence of the prediction if the margnitude of the vector(w^T) orthogonal to the hyperplane remains the same value all the time.

By correctness, the functional margin should always be positive, since if wx + b is negative y is -1 and if wx + b is positive y is 1. If the functional margin is negative then the sample should be divided into the wrong group.

By confidence, the functional margin changes due to two reasons: 1) the sample(y_i and x_i) changes or 2) the vector(w^T) orthogonal to the hyperplane is scaled(scale w and b). If the vector(w^T) orthogonal to the hyperplane remains the same all the time, no matter how large its magnitude is, we can determine how confident the point is grouped into the right side. The larger that functional margin the more confident we can say the point is classified correctly.

But the functional margin is defined without keeping the magnitude of the vector(w^T) orthogonal to the hyperplane the same, then it comes the geometric margin as defined above. The functional margin is normalized by the magnitude magnitude of w to get the geometric margin of a training example. In this constraint, the value of the geometric margin results only from the samples and not from the scaling of the vector(w^T) orthogonal to the hyperplane.

The geometric margin is invariant to rescaling of the parameter, which is the only difference between geometric margin and functional margin.


The introduction of functional margin plays two roles: 1) intuit the maximization of geometric margin and 2) transform the geometric margin maximization issue to the minimization of the magnitude of the vector orthogonal to the hyperplane.

Since scaling the parameters w and b can results nothing meaningful and the parameters are scaled in the same way as the functional margin, then if we can arbitrarily make the ||w|| to be 1(results in maximizing the geometric margin) we can also rescale the parameters to make them subject to the functional margin being 1(then minimize ||w||).

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