# Basic SVM Implemented in MATLAB

``````  Linearly Non-Separable Binary Classification Problem
``````

First of all, this program isn' t working correctly for RBF ( gaussianKernel() ) and I want to fix it.

It is a non-linear SVM Demo to illustrate classifying 2 class with hard margin application.

• I used Quadratic Programming Solver to compute Lagrange multipliers (alphas)

``````xn    = input .* (output*[1 1]);    % xiyi
phi   = gaussianKernel(xn, sigma2); % Radial Basis Function

k     = phi * phi';                 % Symmetric Kernel Matrix For QP Solver
gamma = 1;                          % Adjusting the upper bound of alphas
f     = -ones(2 * len, 1);          % Coefficient of sum of alphas
Aeq   = output';                    % yi
beq   = 0;                          % Sum(ai*yi) = 0
A     = zeros(1, 2* len);           % A * alpha <= b; There isn't like this term
b     = 0;                          % There isn't like this term
lb    = zeros(2 * len, 1);          % Lower bound of alphas
ub    = gamma * ones(2 * len, 1);   % Upper bound of alphas

alphas = quadprog(k, f, A, b, Aeq, beq, lb, ub);
``````
• To solve this non linear classification problem, I wrote some kernel functions such as gaussian (RBF), homogenous and non-homogenous polynomial kernel functions.

For RBF, I implemented the function in the image below:

Using Tylor Series Expansion, it yields:

And, I seperated the Gaussian Kernel like this:

K(x, x') = phi(x)' * phi(x')

The implementation of this thought is:

``````function phi = gaussianKernel(x, Sigma2)

gamma   = 1 / (2 * Sigma2);
featDim = 10; % Length of Tylor Series; Gaussian Kernel Converge 0 so It doesn't have to Be Inf Dimension
phi     = []; % Kernel Output, The Dimension will be (#Sample) x (featDim*2)

for k = 0 : (featDim - 1)

% Gaussian Kernel Trick Using Tylor Series Expansion
phi = [phi, exp( -gamma .* (x(:, 1)).^2) * sqrt(gamma^2 * 2^k / factorial(k)) .* x(:, 1).^k, ...
exp( -gamma .* (x(:, 2)).^2) * sqrt(gamma^2 * 2^k / factorial(k)) .* x(:, 2).^k];
end

end
``````

*** I think my RBF implementation is wrong, but I don' t know how to fix it. Please help me here.

Here is what I got as output:

where,

1) The first image : Samples of Classes
2) The second image : Marking The Support Vectors of Classes
3) The third image : Adding Random Test Data
4) The fourth image : Classification

Also, I implemented Homogenous Polinomial Kernel " K(x, x') = ( )^2 ", code is:

``````function phi = quadraticKernel(x)

% 2-Order Homogenous Polynomial Kernel
phi = [x(:, 1).^2, sqrt(2).*(x(:, 1).*x(:, 2)), x(:, 2).^2];

end
``````

And I got surprisingly nice output:

To sum up, the program is working correctly with using homogenous polynomial kernel but when I use RBF, it isn' t working correctly, there is something wrong with RBF implementation.

If you know about RBF (Gaussian Kernel) please let me know how I can make it right..

Edit: If you have same issue, use RBF directly that defined above and dont separe it by phi.

• Why do you use hard margin? As far as I know, using hard margin is often easily to make mistakes on a single class. Btw have you tuned the parameters ? – Jake0x32 Nov 11 '14 at 18:59
• I haven' t got experience like you mentioned; but because of setting up the problem, I generated sample data for seperable without error so Support Vector Machine might be able to classify the classes without defining any kind of error, that is why I used hard margin. And, the variance of RBF Kernel ("sigma2 = 2" in the program) is big for this application, I know, but I can' t adjust this parameter. I think here the problem is be due to my gaussianKernel() function. I must have implemented it wrongly, and I don' t know how to correct it.. – mehmet Nov 12 '14 at 9:41
• As far as I know, when using Rbf kernel we may always try grid search by trying exponentially increasing parameters, on both C and gamma, where there is a 2-D grid used to search the best model. I am always confident with the capacity of Gaussian Kernel as long as it has a good parameter. – Jake0x32 Nov 12 '14 at 18:52