TY - GEN
T1 - Towards a stronger theory for permutation-based evolutionary algorithms
AU - Doerr, Benjamin
AU - Ghannane, Yassine
AU - Brahim, Marouane Ibn
N1 - Publisher Copyright:
© 2022 ACM.
PY - 2022/7/8
Y1 - 2022/7/8
N2 - While the theoretical analysis of evolutionary algorithms (EAs) has made significant progress for pseudo-Boolean optimization problems in the last 25 years, only sporadic theoretical results exist on how EAs solve permutation-based problems. To overcome the lack of permutation-based benchmark problems, we propose a general way to transfer the classic pseudo-Boolean benchmarks into benchmarks defined on sets of permutations. We then conduct a rigorous runtime analysis of the permutation-based (1 +1) EA proposed by Scharnow, Tinnefeld, and Wegener (2004) on the analogues of the LeadingOnes and Jump benchmarks. The latter shows that, different from bit-strings, it is not only the Hamming distance that determines how difficult it is to mutate a permutation s into another one t, but also the precise cycle structure of st- 1. For this reason, we also regard the more symmetric scramble mutation operator. We observe that it not only leads to simpler proofs, but also reduces the runtime on jump functions with odd jump size by a factor of T(n). Finally, we show that a heavy-tailed version of the scramble operator, as in the bit-string case, leads to a speed-up of order mT(m) on jump functions with jump size m.
AB - While the theoretical analysis of evolutionary algorithms (EAs) has made significant progress for pseudo-Boolean optimization problems in the last 25 years, only sporadic theoretical results exist on how EAs solve permutation-based problems. To overcome the lack of permutation-based benchmark problems, we propose a general way to transfer the classic pseudo-Boolean benchmarks into benchmarks defined on sets of permutations. We then conduct a rigorous runtime analysis of the permutation-based (1 +1) EA proposed by Scharnow, Tinnefeld, and Wegener (2004) on the analogues of the LeadingOnes and Jump benchmarks. The latter shows that, different from bit-strings, it is not only the Hamming distance that determines how difficult it is to mutate a permutation s into another one t, but also the precise cycle structure of st- 1. For this reason, we also regard the more symmetric scramble mutation operator. We observe that it not only leads to simpler proofs, but also reduces the runtime on jump functions with odd jump size by a factor of T(n). Finally, we show that a heavy-tailed version of the scramble operator, as in the bit-string case, leads to a speed-up of order mT(m) on jump functions with jump size m.
KW - Runtime analysis
KW - mutation
KW - permutation search spaces
KW - theory
U2 - 10.1145/3512290.3528720
DO - 10.1145/3512290.3528720
M3 - Conference contribution
AN - SCOPUS:85134686480
T3 - GECCO 2022 - Proceedings of the 2022 Genetic and Evolutionary Computation Conference
SP - 1390
EP - 1398
BT - GECCO 2022 - Proceedings of the 2022 Genetic and Evolutionary Computation Conference
PB - Association for Computing Machinery, Inc
T2 - 2022 Genetic and Evolutionary Computation Conference, GECCO 2022
Y2 - 9 July 2022 through 13 July 2022
ER -