A natural approach to studying schema processing
The Building Block Hypothesis (BBH) states that adaptive systems combine good partial solutions (so-called building blocks) to find increasingly better solutions. It is thought that Genetic Algorithms (GAs) implement the BBH. However, for GAs building blocks are semi-theoretical objects in that they...
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| creator | Fletcher, Jack McKay Wennekers, Thomas |
| description | The Building Block Hypothesis (BBH) states that adaptive systems combine good
partial solutions (so-called building blocks) to find increasingly better
solutions. It is thought that Genetic Algorithms (GAs) implement the BBH.
However, for GAs building blocks are semi-theoretical objects in that they are
thought only to be implicitly exploited via the selection and crossover
operations of a GA. In the current work, we discover a mathematical method to
identify the complete set of schemata present in a given population of a GA; as
such a natural way to study schema processing (and thus the BBH) is revealed.
We demonstrate how this approach can be used both theoretically and
experimentally. Theoretically, we show that the search space for good schemata
is a complete lattice and that each generation samples a complete sub-lattice
of this search space. In addition, we show that combining schemata can only
explore a subset of the search space. Experimentally, we compare how well
different crossover methods combine building blocks. We find that for most
crossover methods approximately 25-35% of building blocks in a generation
result from the combination of the previous generation's building blocks. We
also find that an increase in the combination of building blocks does not lead
to an increase in the efficiency of a GA. To complement this article, we
introduce an open source Python package called schematax, which allows one to
calculate the schemata present in a population using the methods described in
this article. |
| doi_str_mv | 10.48550/arxiv.1705.04536 |
| format | Article |
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partial solutions (so-called building blocks) to find increasingly better
solutions. It is thought that Genetic Algorithms (GAs) implement the BBH.
However, for GAs building blocks are semi-theoretical objects in that they are
thought only to be implicitly exploited via the selection and crossover
operations of a GA. In the current work, we discover a mathematical method to
identify the complete set of schemata present in a given population of a GA; as
such a natural way to study schema processing (and thus the BBH) is revealed.
We demonstrate how this approach can be used both theoretically and
experimentally. Theoretically, we show that the search space for good schemata
is a complete lattice and that each generation samples a complete sub-lattice
of this search space. In addition, we show that combining schemata can only
explore a subset of the search space. Experimentally, we compare how well
different crossover methods combine building blocks. We find that for most
crossover methods approximately 25-35% of building blocks in a generation
result from the combination of the previous generation's building blocks. We
also find that an increase in the combination of building blocks does not lead
to an increase in the efficiency of a GA. To complement this article, we
introduce an open source Python package called schematax, which allows one to
calculate the schemata present in a population using the methods described in
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partial solutions (so-called building blocks) to find increasingly better
solutions. It is thought that Genetic Algorithms (GAs) implement the BBH.
However, for GAs building blocks are semi-theoretical objects in that they are
thought only to be implicitly exploited via the selection and crossover
operations of a GA. In the current work, we discover a mathematical method to
identify the complete set of schemata present in a given population of a GA; as
such a natural way to study schema processing (and thus the BBH) is revealed.
We demonstrate how this approach can be used both theoretically and
experimentally. Theoretically, we show that the search space for good schemata
is a complete lattice and that each generation samples a complete sub-lattice
of this search space. In addition, we show that combining schemata can only
explore a subset of the search space. Experimentally, we compare how well
different crossover methods combine building blocks. We find that for most
crossover methods approximately 25-35% of building blocks in a generation
result from the combination of the previous generation's building blocks. We
also find that an increase in the combination of building blocks does not lead
to an increase in the efficiency of a GA. To complement this article, we
introduce an open source Python package called schematax, which allows one to
calculate the schemata present in a population using the methods described in
this article.</description><subject>Computer Science - Neural and Evolutionary Computing</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNotzr1qw0AQBOBrUgQnD5DK9wJS9n5W0pXG5MdgSONerFYrSyDb4k4O8dvHsVMNzMDwKfViIPcVIrxS_Bm-c1MC5uDRFY8KVvpI8znSqGma4om41_NJp_ncXobjXifu5UD6urCkdG2e1ENHY5Ln_1yo3fvbbv2Zbb8-NuvVNqOiLDIJFkzVUTDo0Fjniq7i1lpGkK7y6NtgDLZsDTJJKF3T2CDC0pQMwYNbqOX99kaupzgcKF7qP3p9o7tfJe890w</recordid><startdate>20170512</startdate><enddate>20170512</enddate><creator>Fletcher, Jack McKay</creator><creator>Wennekers, Thomas</creator><scope>AKY</scope><scope>GOX</scope></search><sort><creationdate>20170512</creationdate><title>A natural approach to studying schema processing</title><author>Fletcher, Jack McKay ; Wennekers, Thomas</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a676-e92018fa9153512336f8cd22c50ef8454d9115dc215cae973bb29eeceb7c09403</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Computer Science - Neural and Evolutionary Computing</topic><toplevel>online_resources</toplevel><creatorcontrib>Fletcher, Jack McKay</creatorcontrib><creatorcontrib>Wennekers, Thomas</creatorcontrib><collection>arXiv Computer Science</collection><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Fletcher, Jack McKay</au><au>Wennekers, Thomas</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A natural approach to studying schema processing</atitle><date>2017-05-12</date><risdate>2017</risdate><abstract>The Building Block Hypothesis (BBH) states that adaptive systems combine good
partial solutions (so-called building blocks) to find increasingly better
solutions. It is thought that Genetic Algorithms (GAs) implement the BBH.
However, for GAs building blocks are semi-theoretical objects in that they are
thought only to be implicitly exploited via the selection and crossover
operations of a GA. In the current work, we discover a mathematical method to
identify the complete set of schemata present in a given population of a GA; as
such a natural way to study schema processing (and thus the BBH) is revealed.
We demonstrate how this approach can be used both theoretically and
experimentally. Theoretically, we show that the search space for good schemata
is a complete lattice and that each generation samples a complete sub-lattice
of this search space. In addition, we show that combining schemata can only
explore a subset of the search space. Experimentally, we compare how well
different crossover methods combine building blocks. We find that for most
crossover methods approximately 25-35% of building blocks in a generation
result from the combination of the previous generation's building blocks. We
also find that an increase in the combination of building blocks does not lead
to an increase in the efficiency of a GA. To complement this article, we
introduce an open source Python package called schematax, which allows one to
calculate the schemata present in a population using the methods described in
this article.</abstract><doi>10.48550/arxiv.1705.04536</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Neural and Evolutionary Computing |
| title | A natural approach to studying schema processing |
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