The genotypic complexity of evolved fault-tolerant and noise-robust circuits

Noise and component failure is an increasingly difficult problem in modern electronic design. Bio-inspired techniques is one approach that is applied in an effort to solve such issues, motivated by the strong robustness and adaptivity often observed in nature. Circuits investigated herein are design...

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Veröffentlicht in:	BioSystems 2007-02, Vol.87 (2), p.224-232
Hauptverfasser:	Hartmann, Morten, Haddow, Pauline C., Lehre, Per Kristian
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Biological Evolution Complexity EHW Electronics, Medical Evolution Fault-tolerance Genotype Noise Robust Systems Biology
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container_title	BioSystems
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creator	Hartmann, Morten Haddow, Pauline C. Lehre, Per Kristian
description	Noise and component failure is an increasingly difficult problem in modern electronic design. Bio-inspired techniques is one approach that is applied in an effort to solve such issues, motivated by the strong robustness and adaptivity often observed in nature. Circuits investigated herein are designed to be tolerant to faults or robust to noise, using an evolutionary algorithm. A major challenge is to improve the scalability of the approach. Earlier results have indicated that the evolved circuits may be suited for the application of artificial development, an approach to indirect mapping from genotype to phenotype that may improve scalability. Those observations were based on the genotypic complexity of evolved circuits. Herein, we measure the genotypic complexity of circuits evolved for tolerance to faults or noise, in order to uncover how that tolerance affects the complexity of the circuits. The complexity is analysed and discussed with regards to how it relates to the potential benefits to the evolutionary process of introducing an indirect genotype–phenotype mapping such as artificial development.
doi_str_mv	10.1016/j.biosystems.2006.09.017
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subjects	Algorithms Biological Evolution Complexity EHW Electronics, Medical Evolution Fault-tolerance Genotype Noise Robust Systems Biology
title	The genotypic complexity of evolved fault-tolerant and noise-robust circuits
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