# Exponents in Genetic Programming

I want to have real-valued exponents (not just integers) for the terminal variables. For example, lets say I want to evolve a function y = x^3.5 + x^2.2 + 6. How should I proceed? I haven't seen any GP implementations which can do this. I tried using the power function, but sometimes the initial solutions have so many exponents that the evaluated value exceeds 'double' bounds! Any suggestion would be appreciated. Thanks in advance.

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What language are you doing this in? Could you possibly make your question a bit more explicit/specific? –  simchona Apr 17 '12 at 0:12
I am using C for symbolic regression. May be I wasn't clear. In my current implementation the only way I can get exponents for the variables is through the '*' function. So if I have a tree like (*(*x x) x), I get x^3. But how do I proceed if I want to evolve x^3.5 as part of my regression function. –  Prometheus Apr 17 '12 at 13:11

DEAP (in Python) implements it. In fact there is an example for that. By adding the math.pow from Python in the primitive set you can acheive what you want.

``````pset.addPrimitive(math.pow, 2)
``````

But using the pow operator you risk getting something like x^(x^(x^(x))), which is probably not desired. You shall add a restriction (by a mean that I not sure) on where in your tree the pow is allowed (just before a leaf or something like that).

OpenBeagle (in C++) also allows it but you will need to develop your own primitive using the pow from `<math.h>`, you can use as an example the Sin or Cos primitive.

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Nested pow is exactly the problem I am facing. I can restrict the pow operator to just before the leaf node. But I also want that exponent to be a constant, not one of the variables, as @Tom Castle suggested. –  Prometheus Apr 19 '12 at 21:23

Integers have a different binary representation than reals, so you have to use a slightly different bitstring representation and recombination/mutation operator.

For an excellent demonstration, see slide 24 of www.cs.vu.nl/~gusz/ecbook/slides/Genetic_Algorithms.ppt or check out the Eiben/Smith book "Introduction to Evolutionary Computing Genetic Algorithms." This describes how to map a bit string to a real number. You can then create a representation where x only lies within an interval [y,z]. In this case, choose y and z to be the of less magnitude than the capacity of the data type you are using (e.g. 10^308 for a double) so you don't run into the overflow issue you describe.

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I am using C for symbolic regression. May be I wasn't clear. In my current implementation the only way I can get exponents for the variables is through the '*' function. So if I have a tree like (*(*x x) x), I get x^3. But how do I proceed if I want to evolve x^3.5 as part of my regression function. –  Prometheus Apr 17 '12 at 13:12

You have to consider that with real-valued exponents and a negative base you will not obtain a real, but a complex number. For example, the Math.Pow implementation in .NET says that you get NaN if you attempt to calculate the power of a negative base to a non-integer exponent. You have to make sure all your x values are positive. I think that's the problem that you're seeing when you "exceed double bounds".

Btw, you can try the HeuristicLab GP implementation. It is very flexible with a configurable grammar.

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This is a good point. The implementation of the power function that you are using needs to be protected from this situation, so any possible inputs have a valid return value. –  Tom Castle Apr 17 '12 at 21:58