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The meat of my question is "how does one design a kernel function for a learning problem?"

As a quick background, I'm reading books on support vector machines and kernel machines, and everywhere I look authors give examples of kernels (polynomial kernels both homogeneous and nonhomogeneous, gaussian kernels, and allusions to text-based kernels to name a few), but all either provide pictures of the results without specifying the kernel, or vaguely claim that "an efficient kernel can be constructed". I'm interested in the process that goes on when one designs a kernel for a new problem.

Probably the easiest example is learning XOR, a smallest (4 points) non-linear data set as embedded the real plane. How would one come up with a natural (and non-trivial) kernel to linearly separate this data?

As a more complex example (see Cristianini, Introduction to SVMs, figure 6.2), how would one design a kernel to learn a checkerboard pattern? Cristianini states the picture was derived "using Gaussian kernels" but it seems that he uses multiple, and they are combined and modified in an unspecified way.

If this question is too broad to answer here, I'd appreciate a reference to the construction of one such kernel function, though I'd prefer the example be somewhat simple.

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3 Answers 3

up vote 7 down vote accepted

Q: "How does one design a kernel function for a learning problem?"

A: "Very carefully"

Trying the usual suspects (linear, polynomial, RBF) and using whichever works the best really is sound advice for someone trying to get the most accurate predictive model they can. For what it's worth it's a common criticism of SVMs that they seem to have a lot of parameters that you need to tune empirically. So at least you're not alone.

If you really want to design a kernel for a specific problem then you are right, it is a machine learning problem all in itself. It's called the 'model selection problem'. I'm not exactly an expert myself here, but the best source of insight into kernel methods for me was the book 'Gaussian Processes' by Rasumussen and Williams (it's freely available online), particularly chapters 4 and 5. I'm sorry that I can't say much more than 'read this huge book full of maths' but it's a complicated problem and they do a really good job of explaining it.

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You're lucky I'm not afraid of maths :) Even better that the contests of this book are online. – JeremyKun May 15 '11 at 16:36
@Bean I think further questions of this type would best be directed at . It's a smaller community but there a lot more machine learning experts there. – StompChicken May 17 '11 at 8:24

(For anyone not familiar with the use of kernel functions in Machine Learning, kernels just maps the input vectors (data points that comprise the data set) into a higher-dimensional space, aka, the "Feature Space". The SVM then finds a separating hyperplane with the maximal margin (distance between the hyperplane and the support vectors) in this transformed space.)

Well, start with kernels that are known to work with SVM classifiers to solve the problem of interest. In this case, we know that the RBF (radial basis function) kernel w/ a trained SVM, cleanly separates XOR. You can write an RBF function in Python this way:

def RBF():
    return NP.exp(-gamma * NP.abs(x - y)**2)

In which gamma is 1/number of features (columns in the data set), and x, y are a Cartesian pair.

(A radial basis function module is also in scipy.interpolate.Rbf)

Second, if what you are after is not just using available kernel functions to solve classification/regression problems, but instead you want to build your own, i would suggest first studying how the choice of kernel function and the parameters inside those functions affect classifier performance. The small group of kernel functions in common use with SVM/SVC, is the best place to start. This group is comprised of (aside from RBF):

  • linear kernel

  • polynomial

  • sigmoid

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How can we determine ahead of time whether a kernel "cleanly separates" anything? Certainly there's more principle to it than folk lore and guess-and-check. Are you saying that we approximate the best kernel with certain combinations of linear/polynomial/sogmoid kernels? Because that sounds like a machine learning problem all in itself, even if we restrict ourselves to one class of kernels. – JeremyKun May 14 '11 at 4:04
No. Here, kernels are not relied upon to separate the data--but rather to project the data into a higher-dimensional feature space. Second, i mentioned a simple empirical study not "folklore." E.g, a simple study: the same data, same SVM parameters, and kernel choice is the only tunable parameter; to measure the effect of the simplest kernels on SVM classifier performance ). – doug May 14 '11 at 4:26
You said, "start with kernels that are known to work," which sounds like folk lore to me. And the point of the kernel is to separate the data via that projection, otherwise there would be no separating hyperplane. My question is whether there is any theoretical reason for picking linear/poly/sigmoid/rbf kernels for a given problem, and how does one combine them to fit any known (spacial) properties of the problem. You answer is "empirical study," which is really just a fancy way to say guess and check. – JeremyKun May 15 '11 at 16:33

I am looking for some polynomial kernel work through examples and stumbled on this post. A couple of things that might help if you are still looking are this toolkit ( which uses multiple kernel learning, where you can choose a wide selection of kernel methods and then the learning will choose the best for the problem, so you don't have to.

An easier more traditional method for your choice of kernel is to use cross-validation with different kernel methods to find the best.

Hope this helps you or anyone else reading around kernel methods.

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Unfortunately I've been looking for a mathematical justification, not an empirical reason. I have yet to find one, so I've sort of resigned it to the bane of applied mathematics and arbitrary parameters. – JeremyKun Nov 7 '12 at 23:31

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