# A hard and soft constraints issue with timetabling using Genetic Algorithms

I am working on this problem, what i have found out is that when i randomly initialize the population (say a size of 1000) almost all genomes in one run do not pass the hard constraints due to inevitable clashes for each genome's genes (events), this is because some variables of each gene are randomly assigned a time slot from a range of time slots with an instructor from a range of instructors and a room from a range of rooms, all for this specific event. so this issue is preventing me from applying the soft constraints evaluation functions, because i can't apply them on an invalid solution. what i think i should do, but I am not sure if it's the way to go is one of the following:

-First, assuming the scale of fitness value is x/100 where x is between 0 and 100,genomes passing all hard constraints will be assigned a fitness value (arbitrarily) of 20, not passing them will give them a fitness that is less than 20 depending on the number of clashes, Genomes that have passed the hard constraints will get soft constraints evaluation function applied on them where they're given a higher score (80) than the hard constraints evaluation functions would ;to give them more advantage over most genomes that didn't pass the hard constraints.

-Second, I exclude (avoid) hard constraints violations by initializing the population without causing clashes and make the fitness function works on only soft constraints, so any genome in the population in any generation will be valid and that the difference between genomes is the quality of the solution, this will work in the beginning but after crossing over parents, the offspring will have hard constraints violations so the population will contain invalid solutions.

looks like the first is the only option i have, i wish if there is another way?

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Why distinguish hard constraints from soft ones? Just give all constraints simple additive penalties, but make the penalties for the hard constraints large enough that it's not possible for an individual that violates a hard constraint to compete with even the worst individual that violates no hard constraints. –  j_random_hacker Nov 21 '12 at 14:24
Alternatively/additionally, try looking for a different representation of your genes so that "hard constraint" violations are impossible. E.g. make each genome consist of a list of records that are each of 1 of 2 types: either (1) a "change to room X" directive or (2) an "instructor Y uses the currently selected room at the next available time slot" directive. This way rooms are used without any gaps or potential for clashes (of one kind at least). –  j_random_hacker Nov 21 '12 at 14:27
j_random_hacker i understand you, looks like i am going with number one as it complies with your first comment, i don't have the time to change the representation (4 weeks dead line) and it appears that violations are as i said inevitable since the number of rooms are way less than the other resources. i hope it doesn't fail and if it does then I'll go with your second suggestion ! Thank you. –  user1165645 Nov 21 '12 at 18:10