控制理论(社会学)
非周期图
计算机科学
趋同(经济学)
控制器(灌溉)
重复控制
瞬态(计算机编程)
不连续性分类
国家观察员
补偿(心理学)
谐波
观察员(物理)
稳健性(进化)
控制工程
控制系统
鲁棒控制
模式(计算机接口)
扰动(地质)
谐波分析
工程类
伺服电动机
限制
国家(计算机科学)
伺服机构
脉冲宽度调制
机器控制
扭矩
瞬态响应
滑模控制
作者
Jinlin Sun,Nengwen Zhu,Qiankang Hou,Shihong Ding,Jun Yang
标识
DOI:10.1109/tpel.2026.3653900
摘要
Achieving robust and precise speed regulation in permanent magnet synchronous motor (PMSM) drive systems remains a significant challenge, particularly under disturbances comprising both periodic and aperiodic components. For aperiodic disturbances, disturbance observers are commonly employed; however, conventional designs often exhibit slow convergence and phase lag, limiting their effectiveness. To address the issue of slow convergence, we first develop a modified supertwisting extended state observer (MSESO), which guarantees finite-time convergence while avoiding the discontinuities inherent in traditional sliding mode observers. Building upon the MSESO, a phase-lifting extended state observer (PLESO) is further designed to mitigate phase lag and enhance the dynamic performance of disturbance estimation. Its phase-lifting characteristics are quantitatively validated via frequency-domain analysis. To suppress periodic disturbances, a switching quasi-resonant (SQR) controller is developed, which demonstrates superior harmonic rejection capability. In contrast to conventional quasi-resonant controllers that may degrade system dynamics, the proposed SQR controller employs a smooth switching mechanism to activate resonant compensation only when needed, thereby preserving transient performance. Extensive experimental results under both aperiodic and periodic disturbance conditions demonstrate that the proposed control scheme achieves robust disturbance rejection and high steady-state speed accuracy in PMSMs.
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