Dual-Environmental Particle Swarm Optimizer in Noisy and Noise-Free Environments

Dual-Environmental Particle Swarm Optimizer in Noisy and Noise-Free Environments

Particle swarm optimizer (PSO) is a population-based optimization technique applied to a wide range of problems. In the literature, many PSO variants have been proposed to deal with noise-free or noisy environments, respectively. While in real-life applications, noise emerges irregularly and unpredi...

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Bibliographic Details
Published in:IEEE transactions on cybernetics Vol. 49; no. 6; pp. 2011 - 2021
Main Authors: Zhang, Junqi, Zhu, Xixun, Wang, Yuheng, Zhou, MengChu
Format: Journal Article
Language:English
Published: United States IEEE 01-06-2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Acceleration
Additives
Dual environments
evolutionary algorithms
Fitness
Genetics
Interference
Local optimization
Noise
Noise measurement
Noise reduction
Optimization
Optimization techniques
Particle swarm optimization
particle swarm optimizer (PSO)
Resampling
Swarm intelligence
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Summary:Particle swarm optimizer (PSO) is a population-based optimization technique applied to a wide range of problems. In the literature, many PSO variants have been proposed to deal with noise-free or noisy environments, respectively. While in real-life applications, noise emerges irregularly and unpredictably. As a result, PSO for a noise-free environment loses its accuracy when noise exists, while PSO for a noisy environment wastes its resampling resource when noise does not exist. To handle such scenario, a PSO variant that can work well in both noise-free and noisy environments is required, which does, to the authors' best knowledge, not exist yet. To fill such gap, this work proposes a novel PSO variant named as dual-environmental PSO (DEPSO). It uses a weighted search center based on top-<inline-formula> <tex-math notation="LaTeX">{k} </tex-math></inline-formula> elite particles to guide the swarm. It averages their positions rather than resampling fitness values of particles to achieve noise reduction, which challenges the indispensable role of the resampling method in a noisy environment and adapts to a noise-free environment as well. Two theoretical analyses are presented for noise reduction and finer local optimization capabilities. Experimental results performed on CEC2013 benchmark functions indicate that DEPSO outperforms state-of-the-art PSO variants in both noise-free and noisy environments.
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ISSN:2168-2267
2168-2275
DOI:10.1109/TCYB.2018.2817020