I am trying to optimize a function (say find the minimum) with n parameters (Xn). All Xi are bound in a certain range (for example -200 to 200) and if any parameter leaves this range, the function goes to infinity very fast. However, n can be large (from 20 to about 60-70) and computing it's value takes long time.
I don't think the details about the function are of big relevance, but here are some: it consists of a weighted sum of 20-30 smaller functions (all different), which on their part consist of sums of dot products under the sign of an inverse sinusoidal function (arcsin, arccos, arctan, etc). Something like arcsin(X1 . X2) + arcsin(X4 . X7) + ...
The function has many local minima in general, so approaches such as (naive) conjugated gradients or newton are useless. Searching the entire domain brute force is too slow.
My initial idea was to use some sort of massive parallelization in combination with a genetic algorithm, which performs many searches on different spots in the domain of the function, and at regular intervals checks whether some of the searches reached a local minima. If yes, it compares them and discards all results but the smallest one, and continues the search until a reasonably small value is found.
My two questions are: 1) Is it possible to implement this problem in CUDA or a similar technology? Can CUDA compute the value of a function like this fast enough? 2) Would be better/faster to implement the problem on a multicore PC (with 12+ cores)?