# Solving the Magic Square with Genetic Algorithms: population score converges fast, but never reaches the goal?

The desire to learn more about GA has sparkled again, and instead of reading a lot and doing nothing, I've decided to start the other way around: pick a problem and try to solve it.

I've picked the Magic Square problem. For encoding the chromosomes I am using Permutation Encoding, and the following methods for Mutation() and NewChild(parent1, parent2, pivot) .

My selection algorithm is a bit weird, and is adapted from examples found on the Internet.

The score is calculated based on the square of the difference of the sum of rows/columns/diagonals and the magic constant, like this.

What I've noticed is that it converges very fast, and stops improving once it reaches a score of 1..7 (less is better).

I am seeing this as: it reaches a local optimum, a potential well, if you can call it that way, and won't jump over the near-by hill because the mutations are not different enough?

I've tried changing the mutation rate 5 - 80%, leaving an elite group of 10-20% in the chromosome population, changing the population size from 16-32 chromosomes, but no luck.

What am I doing wrong? What improvements can I use to make the population score converge to zero?

If required, I can post the full source code, if someone finds it useful or would like to play with it.

Update: Here is what the convergence rate looks like for a cube of size 5, with a crossover rate of 60% and a mutation rate of 10%:

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I also work on magic square problem using binary encoding, GA always returns the best solution from the define search space. I recommend you to play with cross over & mutation rate as well as genome size because it also effects the correctness of the solution. keep mutation rate of 5%, cross over rate 80-90%, population size 200, generation size 500-800. –  Desire Jan 2 '12 at 18:40