TY - JOUR
T1 - Mutation Strategy Based on Step Size and Survival Rate for Evolutionary Programming
AU - Hong, Libin
AU - Liu, Chenjian
AU - Cui, Jiadong
AU - Liu, Fuchang
N1 - Publisher Copyright:
© 2021 Libin Hong et al.
PY - 2021
Y1 - 2021
N2 - Evolutionary programming (EP) uses a mutation as a unique operator. Gaussian, Cauchy, Lévy, and double exponential probability distributions and single-point mutation were nominated as mutation operators. Many mutation strategies have been proposed over the last two decades. The most recent EP variant was proposed using a step-size-based self-adaptive mutation operator. In SSEP, the mutation type with its parameters is selected based on the step size, which differs from generation to generation. Several principles for choosing proper parameters have been proposed; however, SSEP still has limitations and does not display outstanding performance on some benchmark functions. In this work, we proposed a novel mutation strategy based on both the "step size"and "survival rate"for EP (SSMSEP). SSMSEP-1 and SSMSEP-2 are two variants of SSMSEP, which use "survival rate"or "step size"separately. Our proposed method can select appropriate mutation operators and update parameters for mutation operators according to diverse landscapes during the evolutionary process. Compared with SSMSEP-1, SSMSEP-2, SSEP, and other EP variants, the SSMSEP demonstrates its robustness and stable performance on most benchmark functions tested.
AB - Evolutionary programming (EP) uses a mutation as a unique operator. Gaussian, Cauchy, Lévy, and double exponential probability distributions and single-point mutation were nominated as mutation operators. Many mutation strategies have been proposed over the last two decades. The most recent EP variant was proposed using a step-size-based self-adaptive mutation operator. In SSEP, the mutation type with its parameters is selected based on the step size, which differs from generation to generation. Several principles for choosing proper parameters have been proposed; however, SSEP still has limitations and does not display outstanding performance on some benchmark functions. In this work, we proposed a novel mutation strategy based on both the "step size"and "survival rate"for EP (SSMSEP). SSMSEP-1 and SSMSEP-2 are two variants of SSMSEP, which use "survival rate"or "step size"separately. Our proposed method can select appropriate mutation operators and update parameters for mutation operators according to diverse landscapes during the evolutionary process. Compared with SSMSEP-1, SSMSEP-2, SSEP, and other EP variants, the SSMSEP demonstrates its robustness and stable performance on most benchmark functions tested.
UR - http://www.scopus.com/inward/record.url?scp=85118132908&partnerID=8YFLogxK
U2 - 10.1155/2021/1336929
DO - 10.1155/2021/1336929
M3 - Article
AN - SCOPUS:85118132908
SN - 1026-0226
VL - 2021
JO - Discrete Dynamics in Nature and Society
JF - Discrete Dynamics in Nature and Society
M1 - 1336929
ER -