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基于重复扩张状态观测器的自抗扰控制及并网逆变器应用OA

Active Disturbance Rejection Control Based on Repetitive Extended State Observer and Its Application in the Grid-Connected Inverter

中文摘要英文摘要

传统自抗扰控制具有较强的鲁棒性,但因其扩张状态观测器带宽有限而难以抑制并网逆变器中的高频周期谐波扰动,导致并网电流畸变,而重复控制因含有多周期信号的内模能有效跟踪或抑制周期信号.为了提高系统的鲁棒性,同时对多频次谐波扰动进行高精度观测与补偿,该文将重复控制嵌入扩张状态观测器中,提出一种基于重复扩张状态观测器的自抗扰控制策略.首先,分析并网逆变器系统广义扰动中的物理量以及影响自抗扰控制精度的因素;其次,设计重复扩张状态观测器的结构、补偿器和带宽,并分析扰动观测的收敛性;接着,对基于重复扩张状态观测器的自抗扰控制进行性能分析和参数优化设计;最后,在一台 1.5 kW 的并网逆变器实验平台上进行了验证.实验结果表明,所提出的控制策略在逆变器系统存在大量谐波扰动和模型不确定性的情况下,仍能实现良好的稳态性能与鲁棒性.

Grid-connected inverters face persistent challenges in current control due to voltage harmonics from the grid and nonlinearities such as inverter dead-time effects.These disturbances introduce low-frequency harmonics into the grid current,threatening power quality and system stability.Additionally,uncertainties caused by component aging and parameter drift in filter circuits further compromise control performance and may lead to instability. Active disturbance rejection control(ADRC)is a robust control strategy,leveraging an extended state observer(ESO)to estimate and compensate for disturbances and model uncertainties.However,conventional ESOs are limited in bandwidth and struggle to observe high-frequency harmonic disturbances typical in grid-connected inverters.As a result,the grid current exhibits high total harmonic distortion(THD)and significant steady-state error.Repetitive control provides strong harmonic suppression.However,since its compensator design relies on accurate modeling of the plant,system instability may occur in the presence of uncertainties. This paper proposes a novel repetitive extended state observer-based ADRC(RESO-ADRC).The disturbance estimation capability of the ESO is enhanced by integrating repetitive control into its structure.Both periodic disturbances and system uncertainties can be accurately estimated by the resulting RESO,allowing effective rejection of voltage harmonics and compensation for system uncertainties. The limitations of the conventional ESO are analyzed from the perspective of the internal model principle.Accordingly,repetitive control is integrated into the ESO,enhancing its disturbance estimation capability.A compensator is then designed based on the RESO rather than the controlled plant.To limit the observer bandwidth and reduce noise sensitivity,a zero-phase low-pass filter is introduced into the RESO,effectively reducing the system's sensitivity to high-frequency noise. The paper also presents a discrete-domain stability analysis of RESO and RESO-ADRC.The tracking and disturbance rejection performance are analyzed,and optimized controller parameters are provided.Furthermore,robustness analysis under input gain mismatch is discussed. By switching between different LCL filters,the robustness and steady-state performance of the traditional ADRC,repetitive control,and the proposed RESO-ADRC are evaluated.The results show that the traditional ADRC maintains stability across different filters but exhibits poor steady-state performance.Repetitive control offers good steady-state accuracy but becomes unstable when the filter changes.In contrast,RESO-ADRC consistently achieves low THD and demonstrates robust performance across various filter configurations.In addition,the influence of input gain on the system's dynamic performance is investigated,and the stability margins and robustness conditions of the controller parameters are verified.

赵强松;王启帆;夏元清;王军;卢利军

中原工学院自动化与电气工程学院 郑州 450007中原工学院自动化与电气工程学院 郑州 450007中原工学院自动化与电气工程学院 郑州 450007河南许继仪表有限公司 许昌 461000河南许继仪表有限公司 许昌 461000

信息技术与安全科学

自抗扰控制扩张状态观测器重复控制并网逆变器

Active disturbance rejection controlextended state observerrepetitive controlgrid-connected inverters

《电工技术学报》 2026 (12)

4203-4215,13

国家自然科学基金项目(62441315)、河南省自然科学基金重点项目(252300421299)和中原工学院优秀科技创新人才支持计划项目(K2023YXRC03)资助.

10.19595/j.cnki.1000-6753.tces.251019

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