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Can anyone provide some pseudo code for a roulette selection function? How would I implement this:

alt text

I don't really understand how to read this math notation. I never took any probability or statistics.

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The denominator is just a sum : SUM(f_j for j=1 upto N). This just says that the probability p_i of choosing item i is just its fitness f_i over the sum of all fitnesses. –  rampion May 16 '09 at 16:56
1  
@rampion: thanks. this kind of notation makes my head spin but I had guessed correctly and your explanation confirmed it :) –  jkp Dec 23 '10 at 10:37
    
does anyone know if the above formula is valid even when the f_i values (ie. fitness values) are negative? –  mkuse Jan 4 '13 at 7:05
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11 Answers 11

up vote 19 down vote accepted

It's been a few years since i've done this myself, however the following pseudo code was found easily enough on google.

for all members of population
    sum += fitness of this individual
end for

for all members of population
    probability = sum of probabilities + (fitness / sum)
    sum of probabilities += probability
end for

loop until new population is full
    do this twice
        number = Random between 0 and 1
        for all members of population
            if number > probability but less than next probability 
                then you have been selected
        end for
    end
    create offspring
end loop

The site where this came from can be found here if you need further details.

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You may be able to make this more efficient by doing a binary search on the probability array (rather than an iterative search). –  rampion May 16 '09 at 16:54
3  
Please note that this algorithm will not function as expected for minimization problems. It is a common problem with the Roulette Selection (fitness proportionate selection). –  gpampara Feb 13 '10 at 6:45
    
Fitness score should be assigned in a way such that higher score is always more favourable. For minimization problems, the invert is usually taken. For example, to minimize the sum of x and y, a fitness function could be written as fitness = 1 / (x + y). –  user1032613 Feb 4 '13 at 22:26
    
@JarodElliott I might be missing something, but that psuedocode doesn't look correct. The later values in probability could well be greater than 1 and will therefore never be selected.. number should be number = (Random between 0 and 1) * sum of probabilities shouldn't it? –  user1520427 May 20 '13 at 0:10
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Here is some code in C :

// Find the sum of fitnesses. The function fitness(i) should 
//return the fitness value   for member i**

float sumFitness = 0.0f;
for (int i=0; i < nmembers; i++)
    sumFitness += fitness(i);

// Get a floating point number in the interval 0.0 ... sumFitness**
float randomNumber = (float(rand() % 10000) / 9999.0f) * sumFitness;

// Translate this number to the corresponding member**
int memberID=0;
float partialSum=0.0f;

while (randomNumber > partialSum)
{
   partialSum += fitness(memberID);
   memberID++;
} 

**// We have just found the member of the population using the roulette algorithm**
**// It is stored in the "memberID" variable**
**// Repeat this procedure as many times to find random members of the population**
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From the above answer, I got the following, which was clearer to me than the answer itself.

To give an example:

Random(sum) :: Random(12) Iterating through the population, we check the following: random < sum

Let us chose 7 as the random number.

Index   |   Fitness |   Sum |   7 < Sum
0       |   2   |   2       |   false
1       |   3   |   5       |   false
2       |   1   |   6       |   false
3       |   4   |   10      |   true
4       |   2   |   12      |   ...

Through this example, the most fit (Index 3) has the highest percentage of being chosen (33%); as the random number only has to land within 6->10, and it will be chosen.

    for (unsigned int i=0;i<sets.size();i++) {
        sum += sets[i].eval();
    }       
    double rand = (((double)rand() / (double)RAND_MAX) * sum);
    sum = 0;
    for (unsigned int i=0;i<sets.size();i++) {
        sum += sets[i].eval();
        if (rand < sum) {
            //breed i
            break;
        }
    }
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The pseudocode posted contained some unclear elements, and it adds the complexity of generating offspring in stead of performing pure selection. Here is a simple python implementation of that pseudocode:

def roulette_select(population, fitnesses, num):
    """ Roulette selection, implemented according to:
        <http://stackoverflow.com/questions/177271/roulette
        -selection-in-genetic-algorithms/177278#177278>
    """
    total_fitness = float(sum(fitnesses))
    rel_fitness = [f/total_fitness for f in fitnesses]
    # Generate probability intervals for each individual
    probs = [sum(rel_fitness[:i+1]) for i in range(len(rel_fitness))]
    # Draw new population
    new_population = []
    for n in xrange(num):
        r = rand()
        for (i, individual) in enumerate(population):
            if r <= probs[i]:
                new_population.append(individual)
                break
    return new_population
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I wrote a version in C# and am really looking for confirmation that it is indeed correct:

(roulette_selector is a random number which will be in the range 0.0 to 1.0)

private Individual Select_Roulette(double sum_fitness)
    {
        Individual ret = new Individual();
        bool loop = true;

        while (loop)
        {
            //this will give us a double within the range 0.0 to total fitness
            double slice = roulette_selector.NextDouble() * sum_fitness;

            double curFitness = 0.0;

            foreach (Individual ind in _generation)
            {
                curFitness += ind.Fitness;
                if (curFitness >= slice)
                {
                    loop = false;
                    ret = ind;
                    break;
                }
            }
        }
        return ret;

    }
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Lots of correct solutions already, but I think this code is clearer.

def select(fs):
    p = random.uniform(0, sum(fs))
    for i, f in enumerate(fs):
        if p <= 0:
            break
        p -= f
    return i

In addition, if you accumulate the fs, you can produce a more efficient solution.

cfs = [sum(fs[:i+1]) for i in xrange(len(fs))]

def select(cfs):
    return bisect.bisect_left(cfs, random.uniform(0, cfs[-1]))

This is both faster and it's extremely concise code. STL in C++ has a similar bisection algorithm available if that's the language you're using.

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That solution is not just shorter than my code but also clearer and more efficient. (Y) –  Noio Jan 29 '12 at 11:08
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Prof. Thrun of Stanford AI lab also presented a fast(er?) re-sampling code in python during his CS373 of Udacity. Google search result led to the following link:

http://www.udacity-forums.com/cs373/questions/20194/fast-resampling-algorithm

Hope this helps

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Here's a compact java implementation I wrote recently for roulette selection, hopefully of use.

public static gene rouletteSelection()
{
    float totalScore = 0;
    float runningScore = 0;
    for (gene g : genes)
    {
        totalScore += g.score;
    }

    float rnd = (float) (Math.random() * totalScore);

    for (gene g : genes)
    {   
        if (    rnd>=runningScore &&
                rnd<=runningScore+g.score)
        {
            return g;
        }
        runningScore+=g.score;
    }

    return null;
}
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I'm doing an implementation of proportional selection with roulette wheel in javascript, and i was wondering if i'm doing it right. According to Jarod Elliott code I'am doing it right.

this.population is sorted in ascending order, so the elements with lower probability are best, because they have a better fitness score. So i first select two parents, and make sure they are not same, crossover them and save best children to new_population.

Crossover rate is 0.7 in that case.

I'm just not sure if a condition if( spin_num < this.population[i].prob) is right?

var new_population = [];
do
{
    var spin_num = Math.random(1234)/10;
    var p1;
    for( var i in this.population)
    {
        if( spin_num < this.population[i].prob)
        {
            p1 = this.population[i];
            break;
        }
    }

    var spin_num = Math.random(1234)/10;
    var p2;
    for( var i in this.population)
    {
        if( spin_num < this.population[i].prob & p1 !== this.population[i])
        {
            p2 = this.population[i];
            break;
        }
    }

    var offsprings = this.crossover(p1, p2);

    if( offsprings[0].fitness > offsprings[1].fitness )
    {
        new_population.push(offsprings[1]);
    }
    else
    {
        new_population.push(offsprings[0]);
    }
}
while(new_population.length < new_population.length*((this.m_rate)*100)/100)
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Based on my research ,Here is another implementation in C# if there is a need for it:


//those with higher fitness get selected wit a large probability 
//return-->individuals with highest fitness
        private int RouletteSelection()
        {
            double randomFitness = m_random.NextDouble() * m_totalFitness;
            int idx = -1;
            int mid;
            int first = 0;
            int last = m_populationSize -1;
            mid = (last - first)/2;

            //  ArrayList's BinarySearch is for exact values only
            //  so do this by hand.
            while (idx == -1 && first <= last)
            {
                if (randomFitness < (double)m_fitnessTable[mid])
                {
                    last = mid;
                }
                else if (randomFitness > (double)m_fitnessTable[mid])
                {
                    first = mid;
                }
                mid = (first + last)/2;
                //  lies between i and i+1
                if ((last - first) == 1)
                    idx = last;
            }
            return idx;
        }
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This is called roulette-wheel selection via stochastic acceptance:

/// \param[in] f_max maximum fitness of the population
///
/// \return index of the selected individual
///
/// \note
/// Assuming positive fitness. Greater is better.
///
unsigned rw_selection(double f_max)
{
  for (;;)
  {
    // Select randomly one of the individuals
    unsigned i(random_individual());

    // The selection is accepted with probability fitness(i) / f_max
    if (uniform_random_01() < fitness(i) / f_max)
      return i;
  }   
}

The average number of attempts needed for a single selection is:

τ = fmax / avg(f)

  • fmax is the maximum fitness of the population
  • avg(f) is the average fitness

τ doesn't depend explicitly on the number of individual in the population (N), but the ratio can change with N.

However in many application (where the fitness remains bounded and the average fitness doesn't diminish to 0 for increasing N) τ doesn't increase unboundedly with N and thus a typical complexity of this algorithm is O(1) (roulette wheel selection using search algorithms has O(N) or O(log N) complexity).

The probability distribution of this procedure is indeed the same as in the classical roulette-wheel selection.

For further details see:

  • Roulette-wheel selection via stochastic acceptance (Adam Liposki, Dorota Lipowska - 2011)
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