Characterizing fault tolerance in genetic programming

Created by W.Langdon from gp-bibliography.bib Revision:1.8051

@Article{Gonzalez:2010:FGCS,

• author = "Daniel {Lombrana Gonzalez} and Francisco {Fernandez de Vega} and Henri Casanova",
• title = "Characterizing fault tolerance in genetic programming",
• journal = "Future Generation Computer Systems",
• year = "2010",
• volume = "26",
• number = "6",
• pages = "847--856",
• month = jun,
• keywords = "genetic algorithms, genetic programming, Fault tolerance, Parallel genetic programming, Desktop grids",
• ISSN = "0167-739X",
• URL = "http://www.sciencedirect.com/science/article/B6V06-4YDT3S4-2/2/0a9075d8d9c6905e388ad608f0c81e79",
• DOI = "doi:10.1016/j.future.2010.02.006",
• size = "10 pages",
• abstract = "Evolutionary algorithms, including genetic programming (GP), are frequently employed to solve difficult real-life problems, which can require up to days or months of computation. An approach for reducing the time-to-solution is to use parallel computing on distributed platforms. Large platforms such as these are prone to failures, which can even be commonplace events rather than rare occurrences. Thus, fault tolerance and recovery techniques are typically necessary. The aim of this article is to show the inherent ability of parallel GP to tolerate failures in distributed platforms without using any fault-tolerant technique. This ability is quantified via simulation experiments performed using failure traces from real-world distributed platforms, namely, desktop grids, for two well-known problems.",
• notes = "5.1.1. Even parity 5 5.1.2. 11-bit multiplexer",

}

Genetic Programming entries for Daniel Lombrana Gonzalez Rodriguez Francisco Fernandez de Vega Henri Casanova

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