Publication Details

Semantically-oriented mutation operator in cartesian genetic programming for evolutionary circuit design

HODAŇ David, MRÁZEK Vojtěch and VAŠÍČEK Zdeněk. Semantically-oriented mutation operator in cartesian genetic programming for evolutionary circuit design. Genetic Programming and Evolvable Machines, vol. 22, no. 4, 2021, pp. 539-572. ISSN 1389-2576. Available from: https://link.springer.com/article/10.1007%2Fs10710-021-09416-6
Czech title
Sémanticky orientovaný mutační operátor pro evoluční návrh obvodů s využitím kartézského genetického programování
Type
journal article
Language
english
Authors
URL
Keywords

Cartesian genetic programming, Semantic operator, Semantic mutation, Evolutionary circuit design

Abstract

Cartesian genetic programming (CGP) represents the most efficient method for the evolution of digital circuits. Despite many successful applications, however, CGP suffers from limited scalability, especially when used for evolutionary circuit design, i.e. design of circuits from a randomly initialized population. Considering the multiplier design problem, for example, the 5×5-bit multiplier represents the most complex circuit designed by the evolution from scratch. The efficiency of CGP highly depends on the performance of the point mutation operator, however, this operator is purely stochastic. This contrasts with the recent developments in genetic programming (GP), where advanced informed approaches such as semantic-aware operators are incorporated to improve the search space exploration capability of GP. In this paper, we propose a semantically-oriented mutation operator (SOMOk) suitable for the evolutionary design of combinational circuits. In contrast to standard point mutation modifying the values of the mutated genes randomly, the proposed operator uses semantics to determine the best value for each mutated gene. Compared to the common CGP and its variants, the proposed method converges on common Boolean benchmarks substantially faster while keeping the phenotype size relatively small. The successfully evolved instances presented in this paper include 10-bit parity, 10 + 10-bit adder and 5×5-bit multiplier. The most complex circuits were evolved in less than one hour with a single-thread implementation running on a common CPU.

Published
2021
Pages
539-572
Journal
Genetic Programming and Evolvable Machines, vol. 22, no. 4, ISSN 1389-2576
Publisher
Springer International Publishing
DOI
UT WoS
000702806100001
EID Scopus
BibTeX
@ARTICLE{FITPUB12569,
   author = "David Hoda\v{n} and Vojt\v{e}ch Mr\'{a}zek and Zden\v{e}k Va\v{s}\'{i}\v{c}ek",
   title = "Semantically-oriented mutation operator in cartesian genetic programming for evolutionary circuit design",
   pages = "539--572",
   journal = "Genetic Programming and Evolvable Machines",
   volume = 22,
   number = 4,
   year = 2021,
   ISSN = "1389-2576",
   doi = "10.1007/s10710-021-09416-6",
   language = "english",
   url = "https://www.fit.vut.cz/research/publication/12569"
}
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