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There is an alternative to vertical gene transfer (the traditional concept of generations), which is horizontal gene transfer (see this paper). With horizontal gene transfer, the population size remains constant throughout the simulation. Also, when you breed genotypes (with whichever method you choose) you should definitely not keep only the fittest ...


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Using machine internal representation is considered harmful because it leads to deceptive solutions in genetic algorithms. There are many articles about MDP (Minimal Deceptive Problem) in genetic algoritms that cover this topic, for example: http://www.dtic.mil/get-tr-doc/pdf?AD=ADA294072 and great David Goldberg's book which explains deceptive problems ...


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It divides on threshold function of argument instead of argument. Thres(x) = epsilon*Theta(x) if fabs(x)<epsilon. Where Theta() is non-zero variant of theta-function. Other threshold functions possible. Or sometimes it is just 'epsilon'.


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First step is to wrap both loops in a function, this simplifies the code. Then create a cell with all functions you want to evaluate in parallel. Check the documentation for "function handle" if you don't understand the syntax. I use some dummy functions here: jobs={@()exp(1),@()exp(2),@()sin(3)} Now you can easily evaluate the jobs in parallel: ...


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The accumulated normalized fitness is the cumulative sum of the normalized fitnesses of each individual. Example: you have individuals with fitnesses 2, 1, and 7. Their normalized fitnesses are 0.2, 0.1 and 0.7. Their accumulated fitnesses are then 0.2, 0.3 and 1. The order may differ but it has no effect on the selection procedure. The accumulated fitness ...


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cubic is supposed to return the gradient and thus must be a vector. Try the following: module functions implicit none contains function cubic(x,n) result(g) integer, intent(in) :: n real*8, dimension(n), intent(in) :: x real*8, dimension(n) :: g g =(/ 4.d0*(x(1)**3.d0), 8.d0*(x(2)**3.d0) /) end function cubic end module program SOGradient use ...


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I don't know VB, but the following should be general enough. If the genotypes are directly the city permutations the data structures I use are (for N cities): a distance matrix - a N-1 by N-1 2-D array where position (i, j) contains the distance from i-th city to j-th city the genotypes are then arrays (or lists) of the city indices (i.e. 0..N-1) The ...


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I think a 3D volume would be very hard to interpret, it would probably be best to do an animation (ideally) in 2D, or if you can't do an animation, plot all iterations on the same plot with e.g. changing color to indicate iterations. For example:


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As this is StackOverflow, and as you are going to spend fkn 500 of your hardly earned points, and as I am greatly interested in this stuff myself, I wrote you some example code which implements the recipe I presented a few days ago. Although it is a toy model which is solved there, it contains most of the issues of your original problem, and -- given enough ...


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You can try to use lsqcurvefit (http://nl.mathworks.com/help/optim/ug/lsqcurvefit.html), e.g. function F = myfun(x,xdata) %your parameters xa,a,theta,h,k %map to parameter vector x(1),x(2),x(3),x(4),x(5) n = ((xdata-x(1))-x(2)*cos(x(3)))^2+(x(4)-x(2)*sin(x(3)))^2; d = ((xdata-x(1))+acos(x(3)))^2+(x(4)+asin(x(3)))^2; F = x(5)*log(n/d); end ...


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Overview Although you've explicitly tagged evolutionary-algorithm, I'd suggest you to have a look on a set of algorithms summarized under the name Approximate Dynamic Programming (ADP). In my opinion a good introductory book is the one of Warren B. Powell. It contains a lot of such ressource allocation problems, as well as several other practically relevant ...


4

It looks like you want to store the binary representation of your numbers, so you can use the function dec2bin and the best thing, you don't even need a loop ;) r=randi([0 3],1,20); x = dec2bin(r,2) ; >> x x = 10 00 11 11 10 11 10 01 ...


0

Change the fitness to fitness_new = 1 / fitness_old and you have maximization problem again. If fitness_old = 0 is possible, add 1 to the denominator to avoid division by zero.


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It's shows the quantity of features which inherited from the parents in crossover! Note: If crossover probability is 100%, then all offspring is made by crossover. If it is 0%, whole new generation is made from exact copies of chromosomes from old population (but this does not mean that the new generation is the same!).


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Welcome to the world of genetic algorithms! I'll go through your issues and suggest a potential problem. Here we go: maximum fitness does not always grow in the next generation, but becomes smallest - You probably meant smaller. This is weird since you employed elitism, so each generation's best individual should be at least as good as in the previous ...


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I'd prefer fewer lines and not storing the fitness value in chromosomes: import itertools def choose(population): bounds = list(itertools.accumulate(fitness(chromosome) for chromosome in population)) pick = random.random() * bounds[-1] return next(chromosome for chromosome, bound in zip(population, bounds) if pick < bound) But ...



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