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I have a GA with a fitness function that can evaluate to negative or positive values. For the sake of this question let's assume the function

u = 5 - (x^2 + y^2)

where

x in [-5.12 .. 5.12]
y in [-5.12 .. 5.12]

Example fitness function

Now in the selection phase of GA I am using simple roulette wheel. Since to be able to use simple roulette wheel my fitness function must be positive for concrete cases in a population, I started looking for scaling solutions. The most natural seems to be linear fitness scaling. It should be pretty straightforward, for example look at this implementation. However, I am getting negative values even after linear scaling.

For example for the above mentioned function and these fitness values:

-9.734897  -7.479017 -22.834280  -9.868979 -13.180669   4.898595

after linear scaling I am getting these values

-9.6766040 -11.1755111  -0.9727897  -9.5875139  -7.3870793 -19.3997490

Instead, I would like to scale them to positive values, so I can do roulette wheel selection in the next phase.

I must be doing something fundamentally wrong here. How should I approach this problem?

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2  
Your smallest possible value for u = 5 - (2*5.12^2). Why not just add this to your u? –  Hyperboreus Jul 12 '11 at 6:05
    
As far as I understand it, by doing that would be ruining the within-population fitness distribution and in so different/wrong chromosomes will get picked for the next generation. From the link in my post: "We want to maintain a certain relationship between the maximum fitness individual in the population and the average population fitness." –  Grega Kešpret Jul 12 '11 at 6:11
    
Did you use exactly the code from the page you linked to? If you read closely, they state that this code does yield negative values and you still have to adjust by a shift of f'_min. –  Frank Jul 12 '11 at 6:16
    
Yes I used the algorithm from the page I linked to, however translated it to R. As far as I understand it, in that algorithm the else clause (/* if smin becomes negative on scaling */) already should handle this,no? –  Grega Kešpret Jul 12 '11 at 6:23
    
Well, "shift of f'_min" would be what I proposed. –  Hyperboreus Jul 12 '11 at 6:24

3 Answers 3

up vote 1 down vote accepted

Your smallest possible value for u = 5 - (2*5.12^2). Why not just add this to your u?

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The main mistake was that the input to linear scaling must already be positive (by definition), whereas I was fetching it also negative values.

The talk about negative values is not about input to the algorithm, but about output (scaled values) from the algorithm. The check is to handle this case and then correct it so as not to produce negative scaled values.

  if(p->min > (p->scaleFactor * p->avg - p->max)/
     (p->scaleFactor - 1.0)) { /* if nonnegative smin */
    d = p->max - p->avg;
    p->scaleConstA = (p->scaleFactor - 1.0) * p->avg / d;
    p->scaleConstB = p->avg * (p->max - (p->scaleFactor * p->avg))/d;
  } else {  /* if smin becomes negative on scaling */
    d = p->avg - p->min;
    p->scaleConstA = p->avg/d;
    p->scaleConstB = -p->min * p->avg/d;
  }

On the image below, if f'min is negative, go to else clause and handle this case.

Well the solution is then to prescale above mentioned function, so it gives only positive values. As Hyperboreus suggested, this can be done by adding the smallest possible value

u = 5 - (2*5.12^2)

It is best if we separate real fitness values that we are trying to maximize from scaled fitness values that are input to selection phase of GA.

enter image description here

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I agree with the previous answer. Linear scaling by itself tries to preserve the average fitness value, so it needs to be offset if the function is negative. For more details, please have a look in Goldberg's Genetic Algorithms book (1989), Chapter 7, pp. 76-79.

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