# Minimising training error with a linear classifier

I'm trying to find a linear classifier that minimises training error (0/1 loss), in cases where the data is non-linearly separable. Specifically, I'm looking for a way of determining weights:

sign(weights' * features) = label


for features \in {0, 1}^d, label \in {-1, 1} and real-valued weights. I have N training instances, and I want the above equation to hold for the maximum possible number of instances. I know something like a hard-margin SVM would work if the problem was always separable, but I also need to find a solution when it is not.

(This task may sound a bit esoteric, but please don't advise me on what to do instead of looking for a minimum-training-error linear classifier - what I have described is definitely the problem that I want to solve!)

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Matlab includes a non-linear SVM toolbox that's really easy to use. Have a look at svmtrain and svmclassify. To select the kernel function you have to use the 'kernel_function' argument, although the default is 'linear' which is what you're trying to do. The 'boxconstraint' argument let's you select C which is the parameter for the soft constraint.

Edit

I have found this paper which describes a method to minimize the 0/1 loss.

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I'm afraid this doesn't really help, unless you have some guidance for what value of C corresponds to minimising the training error (as I understand it, this would depend on the problem). –  Richante Sep 11 '12 at 11:50
I we need to know what measure you use for training error. But I would consider not minimizing the training error but using cross-validation and taking the validation error as a measure. –  denahiro Sep 11 '12 at 11:56
I've updated my question to clarify that I'm interested in 0/1 loss. As I said in my question, I very specifically want to do exactly what I described, not cross-validation. –  Richante Sep 11 '12 at 12:07
Minimizing o/1 loss is more difficult. I have found this paper which describes a method to do this. It's quite recent and I'm not sure if it's in the publicly available. I'm sorry if isn't. –  denahiro Sep 11 '12 at 12:28
Ah, that looks like what I wanted to know, thanks! Could you edit your answer to include that information so that I can accept it please? –  Richante Sep 11 '12 at 14:23