Genetic-Algorithms for engineering appl.ppt
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Aug 22, 2024
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About This Presentation
Genetic algorithms
Slide Content
Genetic AlgorithmsGenetic Algorithms
IntroductionIntroduction
After scientists became disillusioned with After scientists became disillusioned with
classical and neo-classical attempts at classical and neo-classical attempts at
modeling intelligence, they looked in other modeling intelligence, they looked in other
directions. directions.
Two prominent fields arose, connectionism Two prominent fields arose, connectionism
(neural networking, parallel processing) and (neural networking, parallel processing) and
evolutionary computing. evolutionary computing.
It is the latter that this essay deals with - It is the latter that this essay deals with -
genetic algorithms and genetic programming.genetic algorithms and genetic programming.
After scientists became disillusioned with After scientists became disillusioned with
classical and neo-classical attempts at classical and neo-classical attempts at
modeling intelligence, they looked in other modeling intelligence, they looked in other
directions. directions.
Two prominent fields arose, connectionism Two prominent fields arose, connectionism
(neural networking, parallel processing) and (neural networking, parallel processing) and
evolutionary computing. evolutionary computing.
It is the latter that this essay deals with - It is the latter that this essay deals with -
genetic algorithms and genetic programming.genetic algorithms and genetic programming.
What is GAWhat is GA
A A genetic algorithmgenetic algorithm (or (or GAGA) is a search technique ) is a search technique
used in computing to find true or approximate used in computing to find true or approximate
solutions to optimization and search problems. solutions to optimization and search problems.
Genetic algorithms are categorized as global search Genetic algorithms are categorized as global search
heuristics. heuristics.
Genetic algorithms are a particular class of Genetic algorithms are a particular class of
evolutionary algorithms that use techniques inspired evolutionary algorithms that use techniques inspired
by evolutionary biology such as inheritance, by evolutionary biology such as inheritance,
mutation, selection, and crossover (also called mutation, selection, and crossover (also called
recombination).recombination).
A A genetic algorithmgenetic algorithm (or (or GAGA) is a search technique ) is a search technique
used in computing to find true or approximate used in computing to find true or approximate
solutions to optimization and search problems. solutions to optimization and search problems.
Genetic algorithms are categorized as global search Genetic algorithms are categorized as global search
heuristics. heuristics.
Genetic algorithms are a particular class of Genetic algorithms are a particular class of
evolutionary algorithms that use techniques inspired evolutionary algorithms that use techniques inspired
by evolutionary biology such as inheritance, by evolutionary biology such as inheritance,
mutation, selection, and crossover (also called mutation, selection, and crossover (also called
recombination).recombination).
What is GAWhat is GA
Genetic algorithms are implemented as a computer Genetic algorithms are implemented as a computer
simulation in which a population of abstract simulation in which a population of abstract
representations (called chromosomes or the genotype representations (called chromosomes or the genotype
or the genome) of candidate solutions (called or the genome) of candidate solutions (called
individuals, creatures, or phenotypes) to an individuals, creatures, or phenotypes) to an
optimization problem evolves toward better solutions. optimization problem evolves toward better solutions.
Traditionally, solutions are represented in binary as Traditionally, solutions are represented in binary as
strings of 0s and 1s, but other encodings are also strings of 0s and 1s, but other encodings are also
possible. possible.
Genetic algorithms are implemented as a computer Genetic algorithms are implemented as a computer
simulation in which a population of abstract simulation in which a population of abstract
representations (called chromosomes or the genotype representations (called chromosomes or the genotype
or the genome) of candidate solutions (called or the genome) of candidate solutions (called
individuals, creatures, or phenotypes) to an individuals, creatures, or phenotypes) to an
optimization problem evolves toward better solutions. optimization problem evolves toward better solutions.
Traditionally, solutions are represented in binary as Traditionally, solutions are represented in binary as
strings of 0s and 1s, but other encodings are also strings of 0s and 1s, but other encodings are also
possible. possible.
What is GAWhat is GA
The evolution usually starts from a population of The evolution usually starts from a population of
randomly generated individuals and happens in randomly generated individuals and happens in
generations. generations.
In each generation, the fitness of every individual in In each generation, the fitness of every individual in
the population is evaluated, multiple individuals are the population is evaluated, multiple individuals are
selected from the current population (based on their selected from the current population (based on their
fitness), and modified (recombined and possibly fitness), and modified (recombined and possibly
mutated) to form a new population.mutated) to form a new population.
The evolution usually starts from a population of The evolution usually starts from a population of
randomly generated individuals and happens in randomly generated individuals and happens in
generations. generations.
In each generation, the fitness of every individual in In each generation, the fitness of every individual in
the population is evaluated, multiple individuals are the population is evaluated, multiple individuals are
selected from the current population (based on their selected from the current population (based on their
fitness), and modified (recombined and possibly fitness), and modified (recombined and possibly
mutated) to form a new population.mutated) to form a new population.
What is GAWhat is GA
The new population is then used in the next The new population is then used in the next
iteration of the algorithm. iteration of the algorithm.
Commonly, the algorithm terminates when Commonly, the algorithm terminates when
either a maximum number of generations has either a maximum number of generations has
been produced, or a satisfactory fitness level been produced, or a satisfactory fitness level
has been reached for the population. has been reached for the population.
If the algorithm has terminated due to a If the algorithm has terminated due to a
maximum number of generations, a maximum number of generations, a
satisfactory solution may or may not have satisfactory solution may or may not have
been reached. been reached.
The new population is then used in the next The new population is then used in the next
iteration of the algorithm. iteration of the algorithm.
Commonly, the algorithm terminates when Commonly, the algorithm terminates when
either a maximum number of generations has either a maximum number of generations has
been produced, or a satisfactory fitness level been produced, or a satisfactory fitness level
has been reached for the population. has been reached for the population.
If the algorithm has terminated due to a If the algorithm has terminated due to a
maximum number of generations, a maximum number of generations, a
satisfactory solution may or may not have satisfactory solution may or may not have
been reached. been reached.
Key terms Key terms
IndividualIndividual - Any possible solution - Any possible solution
PopulationPopulation - Group of all - Group of all individualsindividuals
Search SpaceSearch Space - All possible solutions to the problem - All possible solutions to the problem
ChromosomeChromosome - Blueprint for an - Blueprint for an individualindividual
TraitTrait - Possible aspect ( - Possible aspect (features)features) of an of an individualindividual
Allele - - Possible settings of trait (black, blond, etc.)
LocusLocus - The position of a - The position of a genegene on the on the chromosomechromosome
GenomeGenome - Collection of all - Collection of all chromosomeschromosomes for an for an
individualindividual
IndividualIndividual - Any possible solution - Any possible solution
PopulationPopulation - Group of all - Group of all individualsindividuals
Search SpaceSearch Space - All possible solutions to the problem - All possible solutions to the problem
ChromosomeChromosome - Blueprint for an - Blueprint for an individualindividual
TraitTrait - Possible aspect ( - Possible aspect (features)features) of an of an individualindividual
Allele - - Possible settings of trait (black, blond, etc.)
LocusLocus - The position of a - The position of a genegene on the on the chromosomechromosome
GenomeGenome - Collection of all - Collection of all chromosomeschromosomes for an for an
individualindividual
Chromosome, Genes and
Genomes
Genomes
Genotype and Phenotype
Genotype:
– Particular set of genes in a genome
Phenotype:
– Physical characteristic of the genotype
(smart, beautiful, healthy, etc.)
Genotype:
– Particular set of genes in a genome
Phenotype:
– Physical characteristic of the genotype
(smart, beautiful, healthy, etc.)
Genotype and Phenotype
GA RequirementsGA Requirements
A typical genetic algorithm requires two things to be defined:A typical genetic algorithm requires two things to be defined:
a genetic representation of the solution domain, anda genetic representation of the solution domain, and
a fitness function to evaluate the solution domain. a fitness function to evaluate the solution domain.
A standard representation of the solution is as an array of bits. A standard representation of the solution is as an array of bits.
Arrays of other types and structures can be used in essentially Arrays of other types and structures can be used in essentially
the same way. the same way.
The main property that makes these genetic representations The main property that makes these genetic representations
convenient is that their parts are easily aligned due to their convenient is that their parts are easily aligned due to their
fixed size, that facilitates simple crossover operation. fixed size, that facilitates simple crossover operation.
Variable length representations may also be used, but Variable length representations may also be used, but
crossover implementation is more complex in this case. crossover implementation is more complex in this case.
Tree-like representations are explored in Genetic Tree-like representations are explored in Genetic
programming.programming.
A typical genetic algorithm requires two things to be defined:A typical genetic algorithm requires two things to be defined:
a genetic representation of the solution domain, anda genetic representation of the solution domain, and
a fitness function to evaluate the solution domain. a fitness function to evaluate the solution domain.
A standard representation of the solution is as an array of bits. A standard representation of the solution is as an array of bits.
Arrays of other types and structures can be used in essentially Arrays of other types and structures can be used in essentially
the same way. the same way.
The main property that makes these genetic representations The main property that makes these genetic representations
convenient is that their parts are easily aligned due to their convenient is that their parts are easily aligned due to their
fixed size, that facilitates simple crossover operation. fixed size, that facilitates simple crossover operation.
Variable length representations may also be used, but Variable length representations may also be used, but
crossover implementation is more complex in this case. crossover implementation is more complex in this case.
Tree-like representations are explored in Genetic Tree-like representations are explored in Genetic
programming.programming.
RepresentationRepresentation
Chromosomes could be:Chromosomes could be:
Bit strings (0101 ... 1100)Bit strings (0101 ... 1100)
Real numbers (43.2 -33.1 ... 0.0 89.2) Real numbers (43.2 -33.1 ... 0.0 89.2)
Permutations of element (E11 E3 E7 ... E1 E15)Permutations of element (E11 E3 E7 ... E1 E15)
Lists of rules (R1 R2 R3 ... R22 R23)Lists of rules (R1 R2 R3 ... R22 R23)
Program elements (genetic programming)Program elements (genetic programming)
... any data structure ...... any data structure ...
Chromosomes could be:Chromosomes could be:
Bit strings (0101 ... 1100)Bit strings (0101 ... 1100)
Real numbers (43.2 -33.1 ... 0.0 89.2) Real numbers (43.2 -33.1 ... 0.0 89.2)
Permutations of element (E11 E3 E7 ... E1 E15)Permutations of element (E11 E3 E7 ... E1 E15)
Lists of rules (R1 R2 R3 ... R22 R23)Lists of rules (R1 R2 R3 ... R22 R23)
Program elements (genetic programming)Program elements (genetic programming)
... any data structure ...... any data structure ...
GA RequirementsGA Requirements
The fitness function is defined over the genetic representation The fitness function is defined over the genetic representation
and measures the and measures the qualityquality of the represented solution. of the represented solution.
The fitness function is always problem dependent. The fitness function is always problem dependent.
For instance, in the For instance, in the knapsack problem we want to maximize we want to maximize
the total value of objects that we can put in a knapsack of the total value of objects that we can put in a knapsack of
some fixed capacity. some fixed capacity.
A representation of a solution might be an array of bits, where A representation of a solution might be an array of bits, where
each bit represents a different object, and the value of the bit each bit represents a different object, and the value of the bit
(0 or 1) represents whether or not the object is in the knapsack. (0 or 1) represents whether or not the object is in the knapsack.
Not every such representation is valid, as the size of objects Not every such representation is valid, as the size of objects
may exceed the capacity of the knapsack. may exceed the capacity of the knapsack.
The The fitnessfitness of the solution is the sum of values of all objects in of the solution is the sum of values of all objects in
the knapsack if the representation is valid, or 0 otherwise. In the knapsack if the representation is valid, or 0 otherwise. In
some problems, it is hard or even impossible to define the some problems, it is hard or even impossible to define the
fitness expression; in these cases, interactive genetic fitness expression; in these cases, interactive genetic
algorithms are used.algorithms are used.
The fitness function is defined over the genetic representation The fitness function is defined over the genetic representation
and measures the and measures the qualityquality of the represented solution. of the represented solution.
The fitness function is always problem dependent. The fitness function is always problem dependent.
For instance, in the For instance, in the knapsack problem we want to maximize we want to maximize
the total value of objects that we can put in a knapsack of the total value of objects that we can put in a knapsack of
some fixed capacity. some fixed capacity.
A representation of a solution might be an array of bits, where A representation of a solution might be an array of bits, where
each bit represents a different object, and the value of the bit each bit represents a different object, and the value of the bit
(0 or 1) represents whether or not the object is in the knapsack. (0 or 1) represents whether or not the object is in the knapsack.
Not every such representation is valid, as the size of objects Not every such representation is valid, as the size of objects
may exceed the capacity of the knapsack. may exceed the capacity of the knapsack.
The The fitnessfitness of the solution is the sum of values of all objects in of the solution is the sum of values of all objects in
the knapsack if the representation is valid, or 0 otherwise. In the knapsack if the representation is valid, or 0 otherwise. In
some problems, it is hard or even impossible to define the some problems, it is hard or even impossible to define the
fitness expression; in these cases, interactive genetic fitness expression; in these cases, interactive genetic
algorithms are used.algorithms are used.
A fitness functionA fitness function
Basics of GABasics of GA
The most common type of genetic algorithm works like this: The most common type of genetic algorithm works like this:
a population is created with a group of individuals created a population is created with a group of individuals created
randomly. randomly.
The individuals in the population are then evaluated. The individuals in the population are then evaluated.
The evaluation function is provided by the programmer and The evaluation function is provided by the programmer and
gives the individuals a score based on how well they perform gives the individuals a score based on how well they perform
at the given task. at the given task.
Two individuals are then selected based on their fitness, the Two individuals are then selected based on their fitness, the
higher the fitness, the higher the chance of being selected. higher the fitness, the higher the chance of being selected.
These individuals then "reproduce" to create one or more These individuals then "reproduce" to create one or more
offspring, after which the offspring are mutated randomly. offspring, after which the offspring are mutated randomly.
This continues until a suitable solution has been found or a This continues until a suitable solution has been found or a
certain number of generations have passed, depending on the certain number of generations have passed, depending on the
needs of the programmer.needs of the programmer.
The most common type of genetic algorithm works like this: The most common type of genetic algorithm works like this:
a population is created with a group of individuals created a population is created with a group of individuals created
randomly. randomly.
The individuals in the population are then evaluated. The individuals in the population are then evaluated.
The evaluation function is provided by the programmer and The evaluation function is provided by the programmer and
gives the individuals a score based on how well they perform gives the individuals a score based on how well they perform
at the given task. at the given task.
Two individuals are then selected based on their fitness, the Two individuals are then selected based on their fitness, the
higher the fitness, the higher the chance of being selected. higher the fitness, the higher the chance of being selected.
These individuals then "reproduce" to create one or more These individuals then "reproduce" to create one or more
offspring, after which the offspring are mutated randomly. offspring, after which the offspring are mutated randomly.
This continues until a suitable solution has been found or a This continues until a suitable solution has been found or a
certain number of generations have passed, depending on the certain number of generations have passed, depending on the
needs of the programmer.needs of the programmer.
General Algorithm for GA General Algorithm for GA
InitializationInitialization
Initially many individual solutions are randomly Initially many individual solutions are randomly
generated to form an initial population. The generated to form an initial population. The
population size depends on the nature of the problem, population size depends on the nature of the problem,
but typically contains several hundreds or thousands but typically contains several hundreds or thousands
of possible solutions. of possible solutions.
Traditionally, the population is generated randomly, Traditionally, the population is generated randomly,
covering the entire range of possible solutions (the covering the entire range of possible solutions (the
search spacesearch space). ).
Occasionally, the solutions may be "seeded" in areas Occasionally, the solutions may be "seeded" in areas
where optimal solutions are likely to be found.where optimal solutions are likely to be found.
InitializationInitialization
Initially many individual solutions are randomly Initially many individual solutions are randomly
generated to form an initial population. The generated to form an initial population. The
population size depends on the nature of the problem, population size depends on the nature of the problem,
but typically contains several hundreds or thousands but typically contains several hundreds or thousands
of possible solutions. of possible solutions.
Traditionally, the population is generated randomly, Traditionally, the population is generated randomly,
covering the entire range of possible solutions (the covering the entire range of possible solutions (the
search spacesearch space). ).
Occasionally, the solutions may be "seeded" in areas Occasionally, the solutions may be "seeded" in areas
where optimal solutions are likely to be found.where optimal solutions are likely to be found.
General Algorithm for GAGeneral Algorithm for GA
SelectionSelection
During each successive generation, a proportion of the During each successive generation, a proportion of the
existing population is selected to breed a new generation. existing population is selected to breed a new generation.
Individual solutions are selected through a Individual solutions are selected through a fitness-basedfitness-based
process, where fitter solutions (as measured by a fitness process, where fitter solutions (as measured by a fitness
function) are typically more likely to be selected. function) are typically more likely to be selected.
Certain selection methods rate the fitness of each solution and Certain selection methods rate the fitness of each solution and
preferentially select the best solutions. Other methods rate preferentially select the best solutions. Other methods rate
only a random sample of the population, as this process may only a random sample of the population, as this process may
be very time-consuming.be very time-consuming.
Most functions are stochastic and designed so that a small Most functions are stochastic and designed so that a small
proportion of less fit solutions are selected. This helps keep proportion of less fit solutions are selected. This helps keep
the diversity of the population large, preventing premature the diversity of the population large, preventing premature
convergence on poor solutions. Popular and well-studied convergence on poor solutions. Popular and well-studied
selection methods include roulette wheel selection and selection methods include roulette wheel selection and
tournament selection.tournament selection.
SelectionSelection
During each successive generation, a proportion of the During each successive generation, a proportion of the
existing population is selected to breed a new generation. existing population is selected to breed a new generation.
Individual solutions are selected through a Individual solutions are selected through a fitness-basedfitness-based
process, where fitter solutions (as measured by a fitness process, where fitter solutions (as measured by a fitness
function) are typically more likely to be selected. function) are typically more likely to be selected.
Certain selection methods rate the fitness of each solution and Certain selection methods rate the fitness of each solution and
preferentially select the best solutions. Other methods rate preferentially select the best solutions. Other methods rate
only a random sample of the population, as this process may only a random sample of the population, as this process may
be very time-consuming.be very time-consuming.
Most functions are stochastic and designed so that a small Most functions are stochastic and designed so that a small
proportion of less fit solutions are selected. This helps keep proportion of less fit solutions are selected. This helps keep
the diversity of the population large, preventing premature the diversity of the population large, preventing premature
convergence on poor solutions. Popular and well-studied convergence on poor solutions. Popular and well-studied
selection methods include roulette wheel selection and selection methods include roulette wheel selection and
tournament selection.tournament selection.
General Algorithm for GAGeneral Algorithm for GA
In roulette wheel selection, individuals are In roulette wheel selection, individuals are
given a probability of being selected that is given a probability of being selected that is
directly proportionate to their fitness.directly proportionate to their fitness.
Two individuals are then chosen randomly Two individuals are then chosen randomly
based on these probabilities and produce based on these probabilities and produce
offspring.offspring.
In roulette wheel selection, individuals are In roulette wheel selection, individuals are
given a probability of being selected that is given a probability of being selected that is
directly proportionate to their fitness.directly proportionate to their fitness.
Two individuals are then chosen randomly Two individuals are then chosen randomly
based on these probabilities and produce based on these probabilities and produce
offspring.offspring.
General Algorithm for GAGeneral Algorithm for GA
Roulette Wheel’s Selection Pseudo Code:Roulette Wheel’s Selection Pseudo Code:
for all members of populationfor all members of population
sum += fitness of this individualsum += fitness of this individual
end for end for
for all members of population for all members of population
probability = sum of probabilities + (fitness / sum) probability = sum of probabilities + (fitness / sum)
sum of probabilities += probability sum of probabilities += probability
end for end for
loop until new population is full loop until new population is full
do this twice do this twice
number = Random between 0 and 1 number = Random between 0 and 1
for all members of populationfor all members of population
if number > probability but less than next probability then if number > probability but less than next probability then
you have been selected you have been selected
end for end for
endend
create offspring create offspring
end loop end loop
Roulette Wheel’s Selection Pseudo Code:Roulette Wheel’s Selection Pseudo Code:
for all members of populationfor all members of population
sum += fitness of this individualsum += fitness of this individual
end for end for
for all members of population for all members of population
probability = sum of probabilities + (fitness / sum) probability = sum of probabilities + (fitness / sum)
sum of probabilities += probability sum of probabilities += probability
end for end for
loop until new population is full loop until new population is full
do this twice do this twice
number = Random between 0 and 1 number = Random between 0 and 1
for all members of populationfor all members of population
if number > probability but less than next probability then if number > probability but less than next probability then
you have been selected you have been selected
end for end for
endend
create offspring create offspring
end loop end loop
General Algorithm for GAGeneral Algorithm for GA
ReproductionReproduction
The next step is to generate a second generation population of The next step is to generate a second generation population of
solutions from those selected through genetic operators: solutions from those selected through genetic operators:
crossover (also called recombination), and/or mutation.crossover (also called recombination), and/or mutation.
For each new solution to be produced, a pair of "parent" For each new solution to be produced, a pair of "parent"
solutions is selected for breeding from the pool selected solutions is selected for breeding from the pool selected
previously. previously.
By producing a "child" solution using the above methods of By producing a "child" solution using the above methods of
crossover and mutation, a new solution is created which crossover and mutation, a new solution is created which
typically shares many of the characteristics of its "parents". typically shares many of the characteristics of its "parents".
New parents are selected for each child, and the process New parents are selected for each child, and the process
continues until a new population of solutions of appropriate continues until a new population of solutions of appropriate
size is generated.size is generated.
ReproductionReproduction
The next step is to generate a second generation population of The next step is to generate a second generation population of
solutions from those selected through genetic operators: solutions from those selected through genetic operators:
crossover (also called recombination), and/or mutation.crossover (also called recombination), and/or mutation.
For each new solution to be produced, a pair of "parent" For each new solution to be produced, a pair of "parent"
solutions is selected for breeding from the pool selected solutions is selected for breeding from the pool selected
previously. previously.
By producing a "child" solution using the above methods of By producing a "child" solution using the above methods of
crossover and mutation, a new solution is created which crossover and mutation, a new solution is created which
typically shares many of the characteristics of its "parents". typically shares many of the characteristics of its "parents".
New parents are selected for each child, and the process New parents are selected for each child, and the process
continues until a new population of solutions of appropriate continues until a new population of solutions of appropriate
size is generated.size is generated.
General Algorithm for GAGeneral Algorithm for GA
These processes ultimately result in the next These processes ultimately result in the next
generation population of chromosomes that is generation population of chromosomes that is
different from the initial generation. different from the initial generation.
Generally the average fitness will have Generally the average fitness will have
increased by this procedure for the population, increased by this procedure for the population,
since only the best organisms from the first since only the best organisms from the first
generation are selected for breeding, along generation are selected for breeding, along
with a small proportion of less fit solutions, for with a small proportion of less fit solutions, for
reasons already mentioned above.reasons already mentioned above.
These processes ultimately result in the next These processes ultimately result in the next
generation population of chromosomes that is generation population of chromosomes that is
different from the initial generation. different from the initial generation.
Generally the average fitness will have Generally the average fitness will have
increased by this procedure for the population, increased by this procedure for the population,
since only the best organisms from the first since only the best organisms from the first
generation are selected for breeding, along generation are selected for breeding, along
with a small proportion of less fit solutions, for with a small proportion of less fit solutions, for
reasons already mentioned above.reasons already mentioned above.
CrossoverCrossover
the most common type is single point crossover. In single the most common type is single point crossover. In single
point crossover, you choose a locus at which you swap the point crossover, you choose a locus at which you swap the
remaining alleles from on parent to the other. This is complex remaining alleles from on parent to the other. This is complex
and is best understood visually.and is best understood visually.
As you can see, the children take one section of the As you can see, the children take one section of the
chromosome from each parent. chromosome from each parent.
The point at which the chromosome is broken depends on the The point at which the chromosome is broken depends on the
randomly selected crossover point. randomly selected crossover point.
This particular method is called single point crossover because This particular method is called single point crossover because
only one crossover point exists. Sometimes only child 1 or only one crossover point exists. Sometimes only child 1 or
child 2 is created, but oftentimes both offspring are created child 2 is created, but oftentimes both offspring are created
and put into the new population. and put into the new population.
Crossover does not always occur, however. Sometimes, based Crossover does not always occur, however. Sometimes, based
on a set probability, no crossover occurs and the parents are on a set probability, no crossover occurs and the parents are
copied directly to the new population. The probability of copied directly to the new population. The probability of
crossover occurring is usually 60% to 70%.crossover occurring is usually 60% to 70%.
the most common type is single point crossover. In single the most common type is single point crossover. In single
point crossover, you choose a locus at which you swap the point crossover, you choose a locus at which you swap the
remaining alleles from on parent to the other. This is complex remaining alleles from on parent to the other. This is complex
and is best understood visually.and is best understood visually.
As you can see, the children take one section of the As you can see, the children take one section of the
chromosome from each parent. chromosome from each parent.
The point at which the chromosome is broken depends on the The point at which the chromosome is broken depends on the
randomly selected crossover point. randomly selected crossover point.
This particular method is called single point crossover because This particular method is called single point crossover because
only one crossover point exists. Sometimes only child 1 or only one crossover point exists. Sometimes only child 1 or
child 2 is created, but oftentimes both offspring are created child 2 is created, but oftentimes both offspring are created
and put into the new population. and put into the new population.
Crossover does not always occur, however. Sometimes, based Crossover does not always occur, however. Sometimes, based
on a set probability, no crossover occurs and the parents are on a set probability, no crossover occurs and the parents are
copied directly to the new population. The probability of copied directly to the new population. The probability of
crossover occurring is usually 60% to 70%.crossover occurring is usually 60% to 70%.
CrossoverCrossover
MutationMutation
After selection and crossover, you now have a new population After selection and crossover, you now have a new population
full of individuals. full of individuals.
Some are directly copied, and others are produced by Some are directly copied, and others are produced by
crossover. crossover.
In order to ensure that the individuals are not all exactly the In order to ensure that the individuals are not all exactly the
same, you allow for a small chance of mutation. same, you allow for a small chance of mutation.
You loop through all the alleles of all the individuals, and if You loop through all the alleles of all the individuals, and if
that allele is selected for mutation, you can either change it by that allele is selected for mutation, you can either change it by
a small amount or replace it with a new value. The probability a small amount or replace it with a new value. The probability
of mutation is usually between 1 and 2 tenths of a percent. of mutation is usually between 1 and 2 tenths of a percent.
Mutation is fairly simple. You just change the selected alleles Mutation is fairly simple. You just change the selected alleles
based on what you feel is necessary and move on. Mutation is, based on what you feel is necessary and move on. Mutation is,
however, vital to ensuring genetic diversity within the however, vital to ensuring genetic diversity within the
population.population.
After selection and crossover, you now have a new population After selection and crossover, you now have a new population
full of individuals. full of individuals.
Some are directly copied, and others are produced by Some are directly copied, and others are produced by
crossover. crossover.
In order to ensure that the individuals are not all exactly the In order to ensure that the individuals are not all exactly the
same, you allow for a small chance of mutation. same, you allow for a small chance of mutation.
You loop through all the alleles of all the individuals, and if You loop through all the alleles of all the individuals, and if
that allele is selected for mutation, you can either change it by that allele is selected for mutation, you can either change it by
a small amount or replace it with a new value. The probability a small amount or replace it with a new value. The probability
of mutation is usually between 1 and 2 tenths of a percent. of mutation is usually between 1 and 2 tenths of a percent.
Mutation is fairly simple. You just change the selected alleles Mutation is fairly simple. You just change the selected alleles
based on what you feel is necessary and move on. Mutation is, based on what you feel is necessary and move on. Mutation is,
however, vital to ensuring genetic diversity within the however, vital to ensuring genetic diversity within the
population.population.
MutationMutation
General Algorithm for GAGeneral Algorithm for GA
TerminationTermination
This generational process is repeated until a This generational process is repeated until a
termination condition has been reached. termination condition has been reached.
Common terminating conditions are:Common terminating conditions are:
A solution is found that satisfies minimum criteria A solution is found that satisfies minimum criteria
Fixed number of generations reached Fixed number of generations reached
Allocated budget (computation time/money) reached Allocated budget (computation time/money) reached
The highest ranking solution's fitness is reaching or has The highest ranking solution's fitness is reaching or has
reached a plateau such that successive iterations no longer reached a plateau such that successive iterations no longer
produce better results produce better results
Manual inspection Manual inspection
Any Combinations of the aboveAny Combinations of the above
TerminationTermination
This generational process is repeated until a This generational process is repeated until a
termination condition has been reached. termination condition has been reached.
Common terminating conditions are:Common terminating conditions are:
A solution is found that satisfies minimum criteria A solution is found that satisfies minimum criteria
Fixed number of generations reached Fixed number of generations reached
Allocated budget (computation time/money) reached Allocated budget (computation time/money) reached
The highest ranking solution's fitness is reaching or has The highest ranking solution's fitness is reaching or has
reached a plateau such that successive iterations no longer reached a plateau such that successive iterations no longer
produce better results produce better results
Manual inspection Manual inspection
Any Combinations of the aboveAny Combinations of the above
GA Pseudo-code GA Pseudo-code
Choose initial populationChoose initial population
Evaluate the fitness of each individual in the population Evaluate the fitness of each individual in the population
Repeat Repeat
Select best-ranking individuals to reproduceSelect best-ranking individuals to reproduce
Breed new generation through crossover and mutation (genetic Breed new generation through crossover and mutation (genetic
operations) and give birth to offspringoperations) and give birth to offspring
Evaluate the individual fitnesses of the offspring Evaluate the individual fitnesses of the offspring
Replace worst ranked part of population with offspringReplace worst ranked part of population with offspring
Until <terminating condition> Until <terminating condition>
Choose initial populationChoose initial population
Evaluate the fitness of each individual in the population Evaluate the fitness of each individual in the population
Repeat Repeat
Select best-ranking individuals to reproduceSelect best-ranking individuals to reproduce
Breed new generation through crossover and mutation (genetic Breed new generation through crossover and mutation (genetic
operations) and give birth to offspringoperations) and give birth to offspring
Evaluate the individual fitnesses of the offspring Evaluate the individual fitnesses of the offspring
Replace worst ranked part of population with offspringReplace worst ranked part of population with offspring
Until <terminating condition> Until <terminating condition>
Symbolic AI VS. Genetic Symbolic AI VS. Genetic
Algorithms Algorithms
Most symbolic AI systems are very static. Most symbolic AI systems are very static.
Most of them can usually only solve one given Most of them can usually only solve one given
specific problem, since their architecture was specific problem, since their architecture was
designed for whatever that specific problem was in designed for whatever that specific problem was in
the first place. the first place.
Thus, if the given problem were somehow to be Thus, if the given problem were somehow to be
changed, these systems could have a hard time changed, these systems could have a hard time
adapting to them, since the algorithm that would adapting to them, since the algorithm that would
originally arrive to the solution may be either originally arrive to the solution may be either
incorrect or less efficient. incorrect or less efficient.
Genetic algorithms (or GA) were created to combat Genetic algorithms (or GA) were created to combat
these problems; they are basically algorithms based these problems; they are basically algorithms based
on natural biological evolution. on natural biological evolution.
Algorithms Algorithms
Most symbolic AI systems are very static. Most symbolic AI systems are very static.
Most of them can usually only solve one given Most of them can usually only solve one given
specific problem, since their architecture was specific problem, since their architecture was
designed for whatever that specific problem was in designed for whatever that specific problem was in
the first place. the first place.
Thus, if the given problem were somehow to be Thus, if the given problem were somehow to be
changed, these systems could have a hard time changed, these systems could have a hard time
adapting to them, since the algorithm that would adapting to them, since the algorithm that would
originally arrive to the solution may be either originally arrive to the solution may be either
incorrect or less efficient. incorrect or less efficient.
Genetic algorithms (or GA) were created to combat Genetic algorithms (or GA) were created to combat
these problems; they are basically algorithms based these problems; they are basically algorithms based
on natural biological evolution. on natural biological evolution.
Symbolic AI VS. Genetic Symbolic AI VS. Genetic
AlgorithmsAlgorithms
The architecture of systems that implement genetic algorithms The architecture of systems that implement genetic algorithms
(or GA) are more able to adapt to a wide range of problems. (or GA) are more able to adapt to a wide range of problems.
A GA functions by generating a large set of possible solutions A GA functions by generating a large set of possible solutions
to a given problem. to a given problem.
It then evaluates each of those solutions, and decides on a It then evaluates each of those solutions, and decides on a
"fitness level" (you may recall the phrase: "survival of the "fitness level" (you may recall the phrase: "survival of the
fittest") for each solution set. fittest") for each solution set.
These solutions then breed new solutions. These solutions then breed new solutions.
The parent solutions that were more "fit" are more likely to The parent solutions that were more "fit" are more likely to
reproduce, while those that were less "fit" are more unlikely to reproduce, while those that were less "fit" are more unlikely to
do so. do so.
In essence, solutions are evolved over time. This way you In essence, solutions are evolved over time. This way you
evolve your search space scope to a point where you can find evolve your search space scope to a point where you can find
the solution. the solution.
Genetic algorithms can be incredibly efficient if programmed Genetic algorithms can be incredibly efficient if programmed
correctly. correctly.
AlgorithmsAlgorithms
The architecture of systems that implement genetic algorithms The architecture of systems that implement genetic algorithms
(or GA) are more able to adapt to a wide range of problems. (or GA) are more able to adapt to a wide range of problems.
A GA functions by generating a large set of possible solutions A GA functions by generating a large set of possible solutions
to a given problem. to a given problem.
It then evaluates each of those solutions, and decides on a It then evaluates each of those solutions, and decides on a
"fitness level" (you may recall the phrase: "survival of the "fitness level" (you may recall the phrase: "survival of the
fittest") for each solution set. fittest") for each solution set.
These solutions then breed new solutions. These solutions then breed new solutions.
The parent solutions that were more "fit" are more likely to The parent solutions that were more "fit" are more likely to
reproduce, while those that were less "fit" are more unlikely to reproduce, while those that were less "fit" are more unlikely to
do so. do so.
In essence, solutions are evolved over time. This way you In essence, solutions are evolved over time. This way you
evolve your search space scope to a point where you can find evolve your search space scope to a point where you can find
the solution. the solution.
Genetic algorithms can be incredibly efficient if programmed Genetic algorithms can be incredibly efficient if programmed
correctly. correctly.
Genetic ProgrammingGenetic Programming
In programming languages such as LISP, the mathematical In programming languages such as LISP, the mathematical
notation is not written in standard notation, but in prefix notation is not written in standard notation, but in prefix
notation. Some examples of this: notation. Some examples of this:
+ 2 1+ 2 1 : : 2 + 1 2 + 1
* + 2 1 2 * + 2 1 2 : : 2 * (2+1) 2 * (2+1)
* + - 2 1 4 9 : * + - 2 1 4 9 : 9 * ((2 - 1) + 4) 9 * ((2 - 1) + 4)
Notice the difference between the left-hand side to the right? Notice the difference between the left-hand side to the right?
Apart from the order being different, no parenthesis! The Apart from the order being different, no parenthesis! The
prefix method makes it a lot easier for programmers and prefix method makes it a lot easier for programmers and
compilers alike, because order precedence is not an issue. compilers alike, because order precedence is not an issue.
You can build expression trees out of these strings that then You can build expression trees out of these strings that then
can be easily evaluated, for example, here are the trees for the can be easily evaluated, for example, here are the trees for the
above three expressions. above three expressions.
In programming languages such as LISP, the mathematical In programming languages such as LISP, the mathematical
notation is not written in standard notation, but in prefix notation is not written in standard notation, but in prefix
notation. Some examples of this: notation. Some examples of this:
+ 2 1+ 2 1 : : 2 + 1 2 + 1
* + 2 1 2 * + 2 1 2 : : 2 * (2+1) 2 * (2+1)
* + - 2 1 4 9 : * + - 2 1 4 9 : 9 * ((2 - 1) + 4) 9 * ((2 - 1) + 4)
Notice the difference between the left-hand side to the right? Notice the difference between the left-hand side to the right?
Apart from the order being different, no parenthesis! The Apart from the order being different, no parenthesis! The
prefix method makes it a lot easier for programmers and prefix method makes it a lot easier for programmers and
compilers alike, because order precedence is not an issue. compilers alike, because order precedence is not an issue.
You can build expression trees out of these strings that then You can build expression trees out of these strings that then
can be easily evaluated, for example, here are the trees for the can be easily evaluated, for example, here are the trees for the
above three expressions. above three expressions.
Genetic ProgrammingGenetic Programming
Genetic ProgrammingGenetic Programming
You can see how expression evaluation is thus a lot You can see how expression evaluation is thus a lot
easier.easier.
What this have to do with GAs? If for example you What this have to do with GAs? If for example you
have numerical data and 'answers', but no expression have numerical data and 'answers', but no expression
to conjoin the data with the answers. to conjoin the data with the answers.
A genetic algorithm can be used to 'evolve' an A genetic algorithm can be used to 'evolve' an
expression tree to create a very close fit to the data.expression tree to create a very close fit to the data.
By 'splicing' and 'grafting' the trees and evaluating By 'splicing' and 'grafting' the trees and evaluating
the resulting expression with the data and testing it to the resulting expression with the data and testing it to
the answers, the fitness function can return how close the answers, the fitness function can return how close
the expression is. the expression is.
You can see how expression evaluation is thus a lot You can see how expression evaluation is thus a lot
easier.easier.
What this have to do with GAs? If for example you What this have to do with GAs? If for example you
have numerical data and 'answers', but no expression have numerical data and 'answers', but no expression
to conjoin the data with the answers. to conjoin the data with the answers.
A genetic algorithm can be used to 'evolve' an A genetic algorithm can be used to 'evolve' an
expression tree to create a very close fit to the data.expression tree to create a very close fit to the data.
By 'splicing' and 'grafting' the trees and evaluating By 'splicing' and 'grafting' the trees and evaluating
the resulting expression with the data and testing it to the resulting expression with the data and testing it to
the answers, the fitness function can return how close the answers, the fitness function can return how close
the expression is. the expression is.
Genetic ProgrammingGenetic Programming
The limitations of genetic programming lie in The limitations of genetic programming lie in
the the hugehuge search space the GAs have to search search space the GAs have to search
for - an infinite number of equations. for - an infinite number of equations.
Therefore, normally before running a GA to Therefore, normally before running a GA to
search for an equation, the user tells the search for an equation, the user tells the
program which operators and numerical ranges program which operators and numerical ranges
to search under. to search under.
Uses of genetic programming can lie in stock Uses of genetic programming can lie in stock
market prediction, advanced mathematics and market prediction, advanced mathematics and
military applications .military applications .
The limitations of genetic programming lie in The limitations of genetic programming lie in
the the hugehuge search space the GAs have to search search space the GAs have to search
for - an infinite number of equations. for - an infinite number of equations.
Therefore, normally before running a GA to Therefore, normally before running a GA to
search for an equation, the user tells the search for an equation, the user tells the
program which operators and numerical ranges program which operators and numerical ranges
to search under. to search under.
Uses of genetic programming can lie in stock Uses of genetic programming can lie in stock
market prediction, advanced mathematics and market prediction, advanced mathematics and
military applications .military applications .
Evolving Neural Networks Evolving Neural Networks
Evolving the architecture of neural network is Evolving the architecture of neural network is
slightly more complicated, and there have slightly more complicated, and there have
been several ways of doing it. For small nets, a been several ways of doing it. For small nets, a
simple matrix represents which neuron simple matrix represents which neuron
connects which, and then this matrix is, in connects which, and then this matrix is, in
turn, converted into the necessary 'genes', and turn, converted into the necessary 'genes', and
various combinations of these are evolved.various combinations of these are evolved.
Evolving the architecture of neural network is Evolving the architecture of neural network is
slightly more complicated, and there have slightly more complicated, and there have
been several ways of doing it. For small nets, a been several ways of doing it. For small nets, a
simple matrix represents which neuron simple matrix represents which neuron
connects which, and then this matrix is, in connects which, and then this matrix is, in
turn, converted into the necessary 'genes', and turn, converted into the necessary 'genes', and
various combinations of these are evolved.various combinations of these are evolved.
Evolving Neural Networks Evolving Neural Networks
Many would think that a learning function could be Many would think that a learning function could be
evolved via genetic programming. Unfortunately, evolved via genetic programming. Unfortunately,
genetic programming combined with neural networks genetic programming combined with neural networks
could be could be incrediblyincredibly slow, thus impractical. slow, thus impractical.
As with many problems, you have to constrain what As with many problems, you have to constrain what
you are attempting to create. you are attempting to create.
For example, in 1990, David Chalmers attempted to For example, in 1990, David Chalmers attempted to
evolve a function as good as the delta rule. evolve a function as good as the delta rule.
He did this by creating a general equation based upon He did this by creating a general equation based upon
the delta rule with 8 unknowns, which the genetic the delta rule with 8 unknowns, which the genetic
algorithm then evolved.algorithm then evolved.
Many would think that a learning function could be Many would think that a learning function could be
evolved via genetic programming. Unfortunately, evolved via genetic programming. Unfortunately,
genetic programming combined with neural networks genetic programming combined with neural networks
could be could be incrediblyincredibly slow, thus impractical. slow, thus impractical.
As with many problems, you have to constrain what As with many problems, you have to constrain what
you are attempting to create. you are attempting to create.
For example, in 1990, David Chalmers attempted to For example, in 1990, David Chalmers attempted to
evolve a function as good as the delta rule. evolve a function as good as the delta rule.
He did this by creating a general equation based upon He did this by creating a general equation based upon
the delta rule with 8 unknowns, which the genetic the delta rule with 8 unknowns, which the genetic
algorithm then evolved.algorithm then evolved.
Other AreasOther Areas
Genetic Algorithms can be applied to virtually any problem Genetic Algorithms can be applied to virtually any problem
that has a large search space. that has a large search space.
Al Biles uses genetic algorithms to filter out 'good' and 'bad' Al Biles uses genetic algorithms to filter out 'good' and 'bad'
riffs for jazz improvisation. riffs for jazz improvisation.
The military uses GAs to evolve equations to differentiate The military uses GAs to evolve equations to differentiate
between different radar returns.between different radar returns.
Stock companies use GA-powered programs to predict the Stock companies use GA-powered programs to predict the
stock market. stock market.
Genetic Algorithms can be applied to virtually any problem Genetic Algorithms can be applied to virtually any problem
that has a large search space. that has a large search space.
Al Biles uses genetic algorithms to filter out 'good' and 'bad' Al Biles uses genetic algorithms to filter out 'good' and 'bad'
riffs for jazz improvisation. riffs for jazz improvisation.
The military uses GAs to evolve equations to differentiate The military uses GAs to evolve equations to differentiate
between different radar returns.between different radar returns.
Stock companies use GA-powered programs to predict the Stock companies use GA-powered programs to predict the
stock market. stock market.
ExampleExample
f(x) = {MAX(xf(x) = {MAX(x
22
): 0 <= x <= 32 }): 0 <= x <= 32 }
Encode Solution: Just use 5 bits (1 or 0).Encode Solution: Just use 5 bits (1 or 0).
Generate initial population.Generate initial population.
Evaluate each solution against objective.Evaluate each solution against objective.
Sol.Sol. StringString FitnessFitness % of Total% of Total
AA 0110101101 169169 14.414.4
BB 1100011000 576576 49.249.2
CC 0100001000 6464 5.55.5
DD 1001110011 361361 30.930.9
AA0011110011
BB1111000000
CC0011000000
DD1100001111
f(x) = {MAX(xf(x) = {MAX(x
22
): 0 <= x <= 32 }): 0 <= x <= 32 }
Encode Solution: Just use 5 bits (1 or 0).Encode Solution: Just use 5 bits (1 or 0).
Generate initial population.Generate initial population.
Evaluate each solution against objective.Evaluate each solution against objective.
Sol.Sol. StringString FitnessFitness % of Total% of Total
AA 0110101101 169169 14.414.4
BB 1100011000 576576 49.249.2
CC 0100001000 6464 5.55.5
DD 1001110011 361361 30.930.9
AA0011110011
BB1111000000
CC0011000000
DD1100001111
Example Cont’dExample Cont’d
Create next generation of solutionsCreate next generation of solutions
Probability of “being a parent” depends on the fitness.Probability of “being a parent” depends on the fitness.
Ways for parents to create next generationWays for parents to create next generation
ReproductionReproduction
Use a string again unmodified.Use a string again unmodified.
CrossoverCrossover
Cut and paste portions of one string to another.Cut and paste portions of one string to another.
MutationMutation
Randomly flip a bit.Randomly flip a bit.
COMBINATION of all of the above.COMBINATION of all of the above.
Create next generation of solutionsCreate next generation of solutions
Probability of “being a parent” depends on the fitness.Probability of “being a parent” depends on the fitness.
Ways for parents to create next generationWays for parents to create next generation
ReproductionReproduction
Use a string again unmodified.Use a string again unmodified.
CrossoverCrossover
Cut and paste portions of one string to another.Cut and paste portions of one string to another.
MutationMutation
Randomly flip a bit.Randomly flip a bit.
COMBINATION of all of the above.COMBINATION of all of the above.
Checkboard example
We are given an n by n checkboard in which every field
can have a different colour from a set of four colors.
Goal is to achieve a checkboard in a way that there are no
neighbours with the same color (not diagonal)
1 2 3 4 5 6 7 8 9 10
1
2
3
4
5
6
7
8
9
10
1 2 3 4 5 6 7 8 9 10
1
2
3
4
5
6
7
8
9
10
We are given an n by n checkboard in which every field
can have a different colour from a set of four colors.
Goal is to achieve a checkboard in a way that there are no
neighbours with the same color (not diagonal)
1 2 3 4 5 6 7 8 9 10
1
2
3
4
5
6
7
8
9
10
1 2 3 4 5 6 7 8 9 10
1
2
3
4
5
6
7
8
9
10
Checkboard example Cont’d
Chromosomes represent the way the checkboard is colored.
Chromosomes are not represented by bitstrings but by
bitmatrices
The bits in the bitmatrix can have one of the four values 0,
1, 2 or 3, depending on the color.
Crossing-over involves matrix manipulation instead of
point wise operating.
Crossing-over can be combining the parential matrices in a
horizontal, vertical, triangular or square way.
Mutation remains bitwise changing bits in either one
of the other numbers.
Chromosomes represent the way the checkboard is colored.
Chromosomes are not represented by bitstrings but by
bitmatrices
The bits in the bitmatrix can have one of the four values 0,
1, 2 or 3, depending on the color.
Crossing-over involves matrix manipulation instead of
point wise operating.
Crossing-over can be combining the parential matrices in a
horizontal, vertical, triangular or square way.
Mutation remains bitwise changing bits in either one
of the other numbers.
Checkboard example Cont’d
•This problem can be seen as a graph with n nodes
and (n-1) edges, so the fitness f(x) is defined
as:
f(x) = 2 · (n-1) ·n
•This problem can be seen as a graph with n nodes
and (n-1) edges, so the fitness f(x) is defined
as:
f(x) = 2 · (n-1) ·n
Checkboard example Cont’d
•Fitnesscurves for different cross-over rules:
0 100 200 300 400 500
130
140
150
160
170
180
F
i
t
n
e
s
s
Lower-Triangular Crossing Over
0 200 400 600 800
130
140
150
160
170
180
Square Crossing Over
0 200 400 600 800
130
140
150
160
170
180
Generations
F
i
t
n
e
s
s
Horizontal Cutting Crossing Over
0 500 1000 1500
130
140
150
160
170
180
Generations
Verical Cutting Crossing Over
•Fitnesscurves for different cross-over rules:
0 100 200 300 400 500
130
140
150
160
170
180
F
i
t
n
e
s
s
Lower-Triangular Crossing Over
0 200 400 600 800
130
140
150
160
170
180
Square Crossing Over
0 200 400 600 800
130
140
150
160
170
180
Generations
F
i
t
n
e
s
s
Horizontal Cutting Crossing Over
0 500 1000 1500
130
140
150
160
170
180
Generations
Verical Cutting Crossing Over
QuestionsQuestions
????
????
THANK YOUTHANK YOU
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