TY - GEN
T1 - Improving Sailfish Optimizer with Population Switching Strategy and Random Mutation Strategy
AU - Peng, Fei
AU - Zhong, Rui
AU - Fan, Qinqin
AU - Zhang, Chao
AU - Yu, Jun
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - We propose two novel search strategies to further boost the performance of the standard sailfish optimizer (SFO) and present an enhanced SFO with advanced capabilities. Specifically, the first strategy, named the population switching strategy, takes into account the fitness consumption cost of the sardine population. It enables individuals from two different populations to switch, resulting in improved search efficiency. The second strategy, referred to as the random mutation strategy, assists the stagnant individuals in escaping from localized areas where they are trapped and facilitates their search for other potential regions. To evaluate the performance of these strategies, we conducted experiments using three SFO variants: SFO with the population switching strategy, SFO with the random mutation strategy, and SFO with both strategies. Additionally, we compared these variants with the standard SFO on 29 benchmark functions from the CEC2017 test suite. Each benchmark function consists of various dimensions, and each dimension was independently run 30 times. Moreover, we applied the improved algorithm to two classical engineering design problems and compared its performance with three other evolutionary computation (EC) algorithms, including the conventional SFO. The experimental results confirmed that the improved SFO exhibited superior convergence accuracy and provided improved solutions for the two engineering design problems.
AB - We propose two novel search strategies to further boost the performance of the standard sailfish optimizer (SFO) and present an enhanced SFO with advanced capabilities. Specifically, the first strategy, named the population switching strategy, takes into account the fitness consumption cost of the sardine population. It enables individuals from two different populations to switch, resulting in improved search efficiency. The second strategy, referred to as the random mutation strategy, assists the stagnant individuals in escaping from localized areas where they are trapped and facilitates their search for other potential regions. To evaluate the performance of these strategies, we conducted experiments using three SFO variants: SFO with the population switching strategy, SFO with the random mutation strategy, and SFO with both strategies. Additionally, we compared these variants with the standard SFO on 29 benchmark functions from the CEC2017 test suite. Each benchmark function consists of various dimensions, and each dimension was independently run 30 times. Moreover, we applied the improved algorithm to two classical engineering design problems and compared its performance with three other evolutionary computation (EC) algorithms, including the conventional SFO. The experimental results confirmed that the improved SFO exhibited superior convergence accuracy and provided improved solutions for the two engineering design problems.
KW - Evolutionary Computation
KW - Nature-inspired Optimization
KW - Population Switching Strategy
KW - Random Mutation Strategy
KW - Sailfish Optimizer
UR - http://www.scopus.com/inward/record.url?scp=85194136989&partnerID=8YFLogxK
U2 - 10.1109/ACAIT60137.2023.10528475
DO - 10.1109/ACAIT60137.2023.10528475
M3 - 会議への寄与
AN - SCOPUS:85194136989
T3 - Proceedings of 2023 7th Asian Conference on Artificial Intelligence Technology, ACAIT 2023
SP - 713
EP - 720
BT - Proceedings of 2023 7th Asian Conference on Artificial Intelligence Technology, ACAIT 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 7th Asian Conference on Artificial Intelligence Technology, ACAIT 2023
Y2 - 10 November 2023 through 12 November 2023
ER -