Tracer spectrum: a visualisation method for distributed evolutionary computation
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- @Article{ONeill:2011:GPEM,
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author = "Michael O'Neill and Anthony Brabazon and
Erik Hemberg",
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title = "Tracer spectrum: a visualisation method for
distributed evolutionary computation",
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journal = "Genetic Programming and Evolvable Machines",
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year = "2011",
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volume = "12",
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number = "2",
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pages = "161--171",
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month = jun,
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keywords = "genetic algorithms, genetic programming,
Visualisation, Distributed evolutionary computation",
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ISSN = "1389-2576",
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DOI = "doi:10.1007/s10710-010-9125-y",
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size = "11 pages",
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abstract = "We present a novel visualisation method for
island-based evolutionary algorithms based on the
concept of tracers as adopted in medicine and molecular
biology to follow a biochemical process. For example, a
radioisotope or dye can be used to replace a stable
component of a biological compound, and the signal from
the radioisotope can be monitored as it passes through
the body to measure the compound's distribution and
elimination from the system. In a similar fashion we
attach a tracer dye to individuals in each island,
where each individual in any one island is marked with
the same colour, and each island then has its own
unique colour signal. We can then monitor how
individuals undergoing migration events are distributed
throughout the entire island ecosystem, thereby
allowing the user to visually monitor takeover times
and the resulting loss of diversity. This is achieved
by visualising each island as a spectrum of the tracer
dye associated with each individual. Experiments
adopting different rates of migration and network
connectivity confirm earlier research which predicts
that island models are extremely sensitive to the size
and frequency of migrations.",
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notes = "ECJ, Onemax http://ncra.ucd.ie/tracerspectrum/",
- }
Genetic Programming entries for
Michael O'Neill
Anthony Brabazon
Erik Hemberg
Citations