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Genetic Algorithms By: Jacob Noyes 4/16/2013 Traveling Salesman Problem Given: A list of cities Distances between each city Find: Shortest path to reach every city once Traveling Salesman Problem Brute force Exact Algorithms Pro: Will find the right answer Con: Does not scale well Evolution Change in inherited characteristics over time Natural Selection: A mechanism through which evolution happens Survival of the fittest Genes of the more suitable organisms get passed on more often Deoxyribonucleic acid(DNA): Genes encoded in amino acids Used to pass genes from parent to offspring Genetic Algorithms: The Basics Genetic algorithms are specialized search heuristics which use the fundamental principles of evolution through natural selection to find the best solution to a problem. Genetic Algorithms: The Basics Encoding Initialization Selection Crossover Mutation Encoding Changeable representation of individual's traits is created Completed only at the start Its “string” is designed a series of bits Concatenate multiple parameters Examples: Max y-values? Example 1: y = -x^2 + 255x 0 ≤ x ≤ 255 String: 00000000 Example 2: y = 2w + x + 3z ≤ ≤ ≤ x ≤ 11111111 ≤ ≤ ≤ ≤ 0 w 7, 0 x 7, 0 z 7 String: 000/000/000 – 111/111/111 Initialization Beginning population is created Each bit(gene) is randomly generated to create variety Performed only for the first generation and not repeated Example: Initialization Given y = -x^2 + 255x 0 ≤ x ≤ 255 X 188 48 75 104 249 10 134 125 Binary x 10111100 00110000 01001011 01101000 11111001 00001010 10000110 01111101 Selection Assign a fitness measure of how close a solution is to fulfilling the problem Assigned to each individual Select individuals Individuals with higher fitness will reproduce more often Non-selected individuals will “die off” Example: Fitness Given y = -x^2 + 255x 0 ≤ x ≤ 255 X 188 48 75 104 249 10 134 125 Binary x 10111100 00110000 01001011 01101000 11111001 00001010 10000110 01111101 Fitness 12596 9936 13500 15704 1494 2450 16214 16250 Optimums Local optimum: A point where small changes will lead to worse results Overall optimum: The best solution Selection: Categories Proportionate Selection: Fitness relative to other individuals Ranking Selection: Chance to reproduce based on order Tournament Selection: Pits individuals against each other in smaller brackets Gender Specific Selection: Splits Individuals into groups based on “sex” Genetic Relatedness Based Selection: Individuals are selected based on their genetic distance from others in the population Selection: Proportionate Selection Roulette wheel selection Deterministic Sampling Stochastic Remainder Sampling with Replacement Stochastic Remainder Sampling without Replacement Stochastic Universal Selection Roulette Wheel Selection 1. Find Pf: Population fitness = sum of all fitness factors 2. Find Psel: Each individual's probability of selection Psel = (fitness factor) / Pf 3. Load each Psel into an array 4. Generate random number between 0-100 5. Start at beginning of array, subtract each Psel from number until number <= 0 Deterministic Sampling 1. Average fitness is found 2. Individual fitnesses are divided by the average 3. Whole number results = number of spots in the mating pool 4. Extra slots filled starting by highest decimal 5. Random numbers generated to select individuals from the mating pool Stochastic Remainder with Replacement Uses Deterministic Sampling to fill slots with whole number results Left over slots are then filled using the remainders with the Roulette Wheel Selection Method Stochastic Remainder without Replacement Uses Deterministic Sampling to fill slots with whole number results Uses a “weighted-coin toss” to determine the rest 1. Each remainder multiplied by 100 2. Random number between 0-100 generated 3. If random number <= remainder, accept 4. Loop until all spots are filled Ranking Selection Chance to breed based on order of fitness, not proportion Pro: Easy to implement and understand Con: Generally less accurate, less efficient, and phase out diversity too quickly Due to cons, not used often Types: Linear ranking selection Truncate Selection Linear Ranking Selection 1. Probabilities are set up for each rank before fitnesses are even assessed 2. Individuals are ordered based on fitness level 3. The predefined probabilities are assigned to their rank 4. Individuals are selected based on the probabilities Truncate Selection 1. Candidates are put in order based on fitness 2. The top predefined percentage are chosen to reproduce Tournament Selection Individuals are pitted against each other in smaller brackets The winner(s) of each bracket reproduces Bracket participants only need to know fitness levels of others in bracket No need for total or average population fitness factors Good for situations when it is impossible or implausible to calculate totals Tournament Selection: Categories Binary Tournament Selection Larger Tournament Selection Boltzmann Tournament Selection Correlative Tournament Selection Binary Tournament Selection 1. Two candidates are randomly selected out of possible solutions 2. Candidate with best fitness factor is chosen to reproduce Larger Tournament Selection 1. More than two candidates are randomly selected out of possible solutions 2. Candidate with best fitness factor is chosen to reproduce Only difference from Binary Tournament Selection is number of candidates in each bracket More candidates = higher selection pressure Boltzmann Tournament Selection N = temperature = variable describing number of differences in bit string between two individuals 1. First candidate is chosen randomly 2. Second candidate is chosen as having exactly n differences in gene string from first candidate 3. Third candidate is chosen Half of the time has exactly n differences in gene string from first AND second candidate (strict choice) Other half of the time has exactly n difference in gene string from ONLY first candidate (relaxed choice) 4. Choose the winner of the three to reproduce Correlative Tournament Selection Not so much a separate selection method as much as an extension of other tournament selections Once mating pool is selected, pairs are created based on how closely they are related Pairing similar individuals allows a better chance of passing on their (probably) good similar trait Gender Specific Selection Genetic Algorithm with Chromosome Differentiation(GACD) Restricted Mating Correlative Family-based Selection Genetic Algorithms with Chromosome Differentiation Every individual has an extra 00 or 01 attached to their bit string 00 = female, 01 = male When a male and female mate each parent randomly selects a bit to pass onto the child Females(00) can pass on 0 or 0 Males(01) can pass on 0 or 1 Hamming distance: the sum of the differences between each bit of two individuals Ex: 00011111 and 11111111 have a hamming distance of 3. Genetic Algorithm With Chromosome Differentiation 1. Males generated first randomly 2. Females created for each male with maximum hamming distance 3. Select individuals to put into mating pool by either: Using a separate selection method for each sex Or, lumping them together and using one selection method over all of them 4. Mate each individual in the mating pool twice 5. If there are fewer of one sex in the mating pool, mate leftovers with the highest fitness individual of the opposite sex Restricted Mating In nature, different species cannot or will not mate Restricted mating is based on species differentiations Certain traits (predefined sections of the bit string) must be the same to mate two candidates Keeps several variations from converging to a local optimum Correlative Family-based Selection 1. Two candidates are mated together twice 2. Between the two candidates and the two children, the most fit solution is chosen 3. The hamming distance is calculated for each individual compared to the other three 4. The individual with the highest hamming distance is also chosen to reproduce Genetic Relatedness Based Selection Purpose is to search unexplored areas of the search space Groups candidates based on similar fitness factors Does not try to find most fit candidates Includes: Fitness Uniform Selection Scheme(FUSS) Reserve Selection Fitness Uniform Selection Scheme Candidates with similar fitness factors are grouped together Random numbers are generated from the range of minimum fitness to maximum fitness Candidates with fitnesses closest to the random number are selected This gives a higher probability of selecting unexplored areas Helps avoid local optimums Reserve Selection Candidates split into two categories Non-reserved: Normal candidates with normal selection process applied Reserved: Specific less fit candidates that are carried over from generation to generation to keep variety in the population Keeps pool out of local maximums Elitism Automatically carry over most fit individual to next generation Extension of other selection methods Makes sure best fit does not just get unlucky Example: Selection X 188 48 75 104 249 10 134 125 Binary x 10111100 00110000 01001011 01101000 11111001 00001010 10000110 01111101 Fitness 12596 9936 13500 15704 1494 2450 16214 16250 Gene pool 01111101 10000110 01101000 01001011 Given y = -x^2 + 255x 0 ≤ x ≤ 255 Top half truncate selection Crossover Genes(bit strings) are combined from both parents to create offspring Locus: the randomly generated point(s) at which each parent's bit string is separated Example: Crossover Candidate 1 2 3 4 Gene pool 01111101 10000110 01101000 01001011 Locus 3 1 1 6 Parents 1, 2 2, 1 2, 3 3, 2 3, 4 4, 3 4, 1 1, 4 P1 String 011 100 1 0 0 0 010010 011111 P2 String 00110 11101 1101000 0000110 1001011 1101000 01 11 Offspring 01100110 10011101 11101000 00000110 01001011 01101000 01001001 01111111 Mutation in The Natural World Brings diversity to a population Without mutation, just different combinations of the same traits Mutations happen when DNA is not copied properly If the mutation has a benefit, or is just not a hindrance, it may be passed on to new generations Mutation in Genetic Algorithms Purposely inject after crossover Rate of mutation is decided beforehand Ex: 1/2000th chance of mutation per bit For every bit in a population, a random number is generated If the probability hits, the bit is XOR'ed with 1 Example: Mutation Given mutation rate: 1/64 Pre-mutated 01100110 10011101 11101000 00000110 01001011 01101000 01001001 01111111 XOR 00000000 00000000 00000010 00000000 00000000 00000000 00000000 00000000 Offspring 01100110 10011101 11101010 00000110 01001011 01101000 01001001 01111111 Genetic Algorithms: End Fitness threshold based Each solution's fitness level is checked after each generation If a given minimum fitness level is achieved, the algorithm finishes running and outputs the maximum fitness candidate Generation threshold based Genetic algorithm runs for a predefined number of generations Most fit solution over all generations is outputted Uses of Genetic Algorithms Optimal water network layouts Facial recognition Robotics Trajectories for spacecraft Fun with walking Much More Questions?