Bounds for probability of success of classical genetic algorithm based on hamming distance
Genetic algorithms have proven to be reasonably good optimization algorithms. Despite many successful applications, there is a lack of theoretical insight into why they work so well. In this paper, Vose-Liepins' so called "infinite population model" is used to derive a lower and upper...
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| Veröffentlicht in: | IEEE transactions on evolutionary computation 2006-02, Vol.10 (1), p.1-18 |
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| creator | Shiu Yin Yuen Cheung, B.K.S. |
| description | Genetic algorithms have proven to be reasonably good optimization algorithms. Despite many successful applications, there is a lack of theoretical insight into why they work so well. In this paper, Vose-Liepins' so called "infinite population model" is used to derive a lower and upper bound for the expected probability of the global optimal solution under proportional selection and uniform crossover. Elitist selection is not assumed. The approach is to aggregate the Markov chain (MC) into subsets of decreasing Hamming distances. The aggregation is based on a proof of equally likelihood in probability of elements in these subsets. The aggregation model is then extended to Nix-Vose's fully realistic "finite population model." This leads to a lower and upper bound expression based on the first passage theory of the MC for the probability of success of the algorithm. The proof of equally likelihood is extended correspondingly to permutations of populations. Numerical simulations reveal that the bounds are useful for small perturbations of the fitness function for all problem sizes in the infinite population model. Due to the computational burden, however, the aggregated finite population model is still restricted to relatively small problem sizes. Finally, an approximate aggregated finite population model that does not require computation of the full mixing matrix is found to give excellent performance. |
| doi_str_mv | 10.1109/TEVC.2005.851401 |
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Despite many successful applications, there is a lack of theoretical insight into why they work so well. In this paper, Vose-Liepins' so called "infinite population model" is used to derive a lower and upper bound for the expected probability of the global optimal solution under proportional selection and uniform crossover. Elitist selection is not assumed. The approach is to aggregate the Markov chain (MC) into subsets of decreasing Hamming distances. The aggregation is based on a proof of equally likelihood in probability of elements in these subsets. The aggregation model is then extended to Nix-Vose's fully realistic "finite population model." This leads to a lower and upper bound expression based on the first passage theory of the MC for the probability of success of the algorithm. The proof of equally likelihood is extended correspondingly to permutations of populations. Numerical simulations reveal that the bounds are useful for small perturbations of the fitness function for all problem sizes in the infinite population model. Due to the computational burden, however, the aggregated finite population model is still restricted to relatively small problem sizes. Finally, an approximate aggregated finite population model that does not require computation of the full mixing matrix is found to give excellent performance.</description><identifier>ISSN: 1089-778X</identifier><identifier>EISSN: 1941-0026</identifier><identifier>DOI: 10.1109/TEVC.2005.851401</identifier><identifier>CODEN: ITEVF5</identifier><language>eng</language><publisher>New York, NY: IEEE</publisher><subject>Agglomeration ; Aggregates ; Aggregation ; Algorithm design and analysis ; Algorithmics. Computability. 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Despite many successful applications, there is a lack of theoretical insight into why they work so well. In this paper, Vose-Liepins' so called "infinite population model" is used to derive a lower and upper bound for the expected probability of the global optimal solution under proportional selection and uniform crossover. Elitist selection is not assumed. The approach is to aggregate the Markov chain (MC) into subsets of decreasing Hamming distances. The aggregation is based on a proof of equally likelihood in probability of elements in these subsets. The aggregation model is then extended to Nix-Vose's fully realistic "finite population model." This leads to a lower and upper bound expression based on the first passage theory of the MC for the probability of success of the algorithm. The proof of equally likelihood is extended correspondingly to permutations of populations. Numerical simulations reveal that the bounds are useful for small perturbations of the fitness function for all problem sizes in the infinite population model. Due to the computational burden, however, the aggregated finite population model is still restricted to relatively small problem sizes. Finally, an approximate aggregated finite population model that does not require computation of the full mixing matrix is found to give excellent performance.</description><subject>Agglomeration</subject><subject>Aggregates</subject><subject>Aggregation</subject><subject>Algorithm design and analysis</subject><subject>Algorithmics. Computability. Computer arithmetics</subject><subject>Algorithms</subject><subject>Applied sciences</subject><subject>Computation</subject><subject>Computer science; control theory; systems</subject><subject>Convergence</subject><subject>convergence rate</subject><subject>evolutionary algorithms (EAs)</subject><subject>Evolutionary computation</subject><subject>Exact sciences and technology</subject><subject>first passage probability</subject><subject>first passage time</subject><subject>Genetic algorithms</subject><subject>genetic algorithms (GAs)</subject><subject>Genetic mutations</subject><subject>Hamming distance</subject><subject>Markov chain (MC)</subject><subject>Mathematical analysis</subject><subject>Mathematical models</subject><subject>Numerical simulation</subject><subject>perfect lumping</subject><subject>probability of success</subject><subject>Proving</subject><subject>Studies</subject><subject>Theoretical computing</subject><subject>Upper bound</subject><subject>Upper bounds</subject><issn>1089-778X</issn><issn>1941-0026</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2006</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNp9kUtr3TAQhU1poGmSfaEbUWi78q3elpbNJX1AoJu0hG6EJI9vFGwr1diL_PvK3ECgi65mYL45zJzTNG8Y3TFG7aebq1_7HadU7YxikrIXzSmzkrWUcv2y9tTYtuvM7avmNeI9pUwqZk-b35d5nXskQy7koeTgQxrT8kjyQHCNERC3No4eMUU_kgPMsKRI_HjIJS13EwkeoSd5Jnd-mtJ8IH3Cxc8RzpuTwY8IF0_1rPn55epm_629_vH1-_7zdRuFEUvLjQ7KUKl53w0qMuOtNLHnw2BlANCgRAg8RBWkNb2CwMFTUNZL7UXPrDhrPh516_1_VsDFTQkjjKOfIa_ojNVccmo38sN_Sd5ZY6VUFXz3D3if1zLXL5zRSmvBua4QPUKxZMQCg3soafLl0THqtkzclonbMnHHTOrK-yddj9XNoVSfEj7vddJwpnjl3h65BADPY2WE5kL8BSuOlS8</recordid><startdate>20060201</startdate><enddate>20060201</enddate><creator>Shiu Yin Yuen</creator><creator>Cheung, B.K.S.</creator><general>IEEE</general><general>Institute of Electrical and Electronics Engineers</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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Computer arithmetics</topic><topic>Algorithms</topic><topic>Applied sciences</topic><topic>Computation</topic><topic>Computer science; control theory; systems</topic><topic>Convergence</topic><topic>convergence rate</topic><topic>evolutionary algorithms (EAs)</topic><topic>Evolutionary computation</topic><topic>Exact sciences and technology</topic><topic>first passage probability</topic><topic>first passage time</topic><topic>Genetic algorithms</topic><topic>genetic algorithms (GAs)</topic><topic>Genetic mutations</topic><topic>Hamming distance</topic><topic>Markov chain (MC)</topic><topic>Mathematical analysis</topic><topic>Mathematical models</topic><topic>Numerical simulation</topic><topic>perfect lumping</topic><topic>probability of success</topic><topic>Proving</topic><topic>Studies</topic><topic>Theoretical computing</topic><topic>Upper bound</topic><topic>Upper bounds</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Shiu Yin Yuen</creatorcontrib><creatorcontrib>Cheung, B.K.S.</creatorcontrib><collection>IEEE All-Society Periodicals Package (ASPP) 2005-present</collection><collection>IEEE All-Society Periodicals Package (ASPP) 1998-Present</collection><collection>IEEE Electronic Library (IEL)</collection><collection>Pascal-Francis</collection><collection>CrossRef</collection><collection>Computer and Information Systems Abstracts</collection><collection>Electronics & Communications Abstracts</collection><collection>Technology Research Database</collection><collection>ProQuest Computer Science Collection</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>Computer and Information Systems Abstracts Academic</collection><collection>Computer and Information Systems Abstracts Professional</collection><collection>ANTE: Abstracts in New Technology & Engineering</collection><collection>Engineering Research Database</collection><jtitle>IEEE transactions on evolutionary computation</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Shiu Yin Yuen</au><au>Cheung, B.K.S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Bounds for probability of success of classical genetic algorithm based on hamming distance</atitle><jtitle>IEEE transactions on evolutionary computation</jtitle><stitle>TEVC</stitle><date>2006-02-01</date><risdate>2006</risdate><volume>10</volume><issue>1</issue><spage>1</spage><epage>18</epage><pages>1-18</pages><issn>1089-778X</issn><eissn>1941-0026</eissn><coden>ITEVF5</coden><abstract>Genetic algorithms have proven to be reasonably good optimization algorithms. Despite many successful applications, there is a lack of theoretical insight into why they work so well. In this paper, Vose-Liepins' so called "infinite population model" is used to derive a lower and upper bound for the expected probability of the global optimal solution under proportional selection and uniform crossover. Elitist selection is not assumed. The approach is to aggregate the Markov chain (MC) into subsets of decreasing Hamming distances. The aggregation is based on a proof of equally likelihood in probability of elements in these subsets. The aggregation model is then extended to Nix-Vose's fully realistic "finite population model." This leads to a lower and upper bound expression based on the first passage theory of the MC for the probability of success of the algorithm. The proof of equally likelihood is extended correspondingly to permutations of populations. Numerical simulations reveal that the bounds are useful for small perturbations of the fitness function for all problem sizes in the infinite population model. Due to the computational burden, however, the aggregated finite population model is still restricted to relatively small problem sizes. Finally, an approximate aggregated finite population model that does not require computation of the full mixing matrix is found to give excellent performance.</abstract><cop>New York, NY</cop><pub>IEEE</pub><doi>10.1109/TEVC.2005.851401</doi><tpages>18</tpages></addata></record> |
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| subjects | Agglomeration Aggregates Aggregation Algorithm design and analysis Algorithmics. Computability. Computer arithmetics Algorithms Applied sciences Computation Computer science control theory systems Convergence convergence rate evolutionary algorithms (EAs) Evolutionary computation Exact sciences and technology first passage probability first passage time Genetic algorithms genetic algorithms (GAs) Genetic mutations Hamming distance Markov chain (MC) Mathematical analysis Mathematical models Numerical simulation perfect lumping probability of success Proving Studies Theoretical computing Upper bound Upper bounds |
| title | Bounds for probability of success of classical genetic algorithm based on hamming distance |
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