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I am trying to solve the SVM Primal Form in MATLAB using the Quadprog function. When the two classes are linearly separable, the SVM Minimization Problem to get the weight vector w becomes 1/2(||W||2)

subject to the constraint yi(wxi-b) >= 1

http://en.wikipedia.org/wiki/Support_vector_machine#Primal_form

The matlab quadprog function solves the following equation

x = quadprog(H,f,A,b) minimizes 1/2*x'*H*x + f'*x subject to the restrictions A*x ≤ b. A is a matrix of doubles, and b is a vector of doubles.

So, the primal form can easily be mapped to the quadprog function to get the weight vector w easily.. H becomes a identity matrix. f' becomes a zeros matrix. A is the left hand side of the constraint from earlier b is equal to -1 because the original constraint had >= 1, it becomes <= -1 when we multiply with -1 on both sides.

When I do this, the weight vector turns out great.

Now, I am trying to solve the SVM Soft Margin case from here

http://en.wikipedia.org/wiki/Support_vector_machine#Soft_margin

The minimization equation here is

min ((1/2) ||w||2 + C (summation of epsilon(i)) w,b

subject to the constraint yi(wxi-b) >= 1 - eplison (i) >= 0.

How can this optimization problem be solved using the MATLAB quadprog function. Its not clear how the equation should be mapped to the parameters of the quadprog function. I have been cracking my head on how without any luck.

Its been a long time since I studied SVM but from vague memory, I remember that the Primal Form in the Soft Margin is a NP problem, that's why we convert it to the Wolfe Dual Representation to solve it, but I am not sure.

I converted it into the dual form and am able to get the Lagrange variable values in the dual form, however I want to confirm that the primal form cannot be solved by itself.

Does anyone know how it can be solved using the matlab quadprog function? Or if it is actually a NP problem?

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It's a quadratic programming problem, so - yes, it can be solved by MATLAB's quadprog. What are your difficulties? –  Romeo Mar 20 '13 at 16:27
    
I was able to solve the normal SVM fine. But for the soft margin SVM, I'm unable to understand how the minimization problem maps to the quadprog function. Which variable maps to what parameter in the quadprog function, this is what I am finding difficult. –  user1067334 Mar 20 '13 at 16:41
    
See my answer to the question. –  Romeo Mar 20 '13 at 16:45

1 Answer 1

up vote 5 down vote accepted

I don't see how it can be a problem. Let z be our vector of (2n + 1) variables:

z = (w, eps, b)

Then, H becomes diagonal matrix with first n values on the diagonal equal to 1 and the last n + 1 set to zero:

H = diag([ones(1, n), zeros(1, n + 1)])

Vector f can be expressed as:

f = [zeros(1, n), C * ones(1, n), 0]'

First set of constrains becomes:

Aineq = [A1, eye(n), zeros(n, 1)]
bineq = ones(n, 1)

where A1 is a the same matrix as in primal form.

Second set of constraints becomes lower bounds:

lb = (inf(n, 1), zeros(n, 1), inf(n, 1))

Then you can call MATLAB:

z = quadprog(H, f, Aineq, bineq, [], [], lb);

P.S. I can be mistaken in some small details, but the general idea is right.

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The way the "n" variable was thrown around confused me even more but I got the general idea. The n variable doesn't match up well in quite a few places. Thank you very much. –  user1067334 Mar 22 '13 at 2:48

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