基于多目标混合精英粒子群算法的三相整流系统控制器参数优化

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摘要针对传统比例积分（PI）控制器参数经验调试法存在主观性强、优化效率低等问题,本文提出基于多目标混合精英粒子群算法（MOHEPSO）的三相整流系统控制器参数优化方法。该方法通过集成熵值法筛选精英粒子（基于信息熵最小化增强全局搜索）、轮盘赌机制优选高质量粒子（引导局部精细化搜索）及支配度自适应调整策略（动态平衡全局、局部寻优能力）3大核心模块,构建具有协同优化特性的智能算法框架。仿真结果表明,相较于传统的粒子群算法和多目标粒子群算法,所提方法在Matlab/Simulink仿真中的稳定时间、超调量及稳态误差等核心指标表现更优,体现了其在电力电子系统优化中的优势。

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	邢云
	王子为

关键词 ：三相整流, 多目标粒子群算法, 比例积分（PI）控制器, 电子电力

Abstract：To address the issues of strong subjectivity and low optimization efficiency in traditional empirical tuning methods for proportional integral (PI) controller parameters, this paper proposes a multi-objective hybrid elite particle swarm optimization (MOHEPSO) algorithm for parameter optimization of the three-phase rectifier system controller. This method integrates three core modules: an entropy-weighted method for elite particle selection (enhancing global search through information entropy minimization), a roulette wheel mechanism for high-quality particle optimization (guiding refined local search), and a dominance-based adaptive adjustment strategy (dynamically balancing global/local optimization capabilities). These components collectively construct an intelligent algorithmic framework with synergistic optimization characteristics. Simulation results demonstrate that, compared to conventional multi-objective particle swarm optimization (MOPSO) and particle swarm optimization (PSO), the proposed method achieves better performance in Matlab/Simulink simulations. Significant improvements are observed in key metrics including settling time, overshoot, and steady- state error, thereby validating its remarkable advantages in power electronics system optimization.

Key words： three-phase rectifier multi-objective particle swarm optimization proportional integral (PI) controller power electronics

收稿日期: 2025-06-16

作者简介: 邢云（2000—）,男,硕士研究生,主要从事多目标智能进化算法与电力电子系统控制研究工作。

引用本文:

邢云, 王子为. 基于多目标混合精英粒子群算法的三相整流系统控制器参数优化[J]. 电气技术, 2026, 27(3): 1-12. XING Yun, WANG Ziwei. Optimization of parameters for a three-phase rectifier system controller based on multi-objective hybrid elite particle swarm optimization algorithm. Electrical Engineering, 2026, 27(3): 1-12.

链接本文:

https://dqjs.cesmedia.cn/CN/Y2026/V27/I3/1

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