Research on TOGI-EFLL flux observer for IPMSM sensorless control

IF 1.9 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC IET Power Electronics Pub Date : 2024-08-05 DOI:10.1049/pel2.12735

Xue Hao, Yutao Luo

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Abstract

For the purpose of enhancing the performance of interior permanent magnet synchronous motors (IPMSMs) sensorless control, a flux observer based on a third-order generalized integrator with enhanced frequency-locked loop (TOGI-EFLL) is introduced in this paper. Compared with the traditional second-order generalized integrator with frequency-locked loop (SOGI-FLL), the proposed TOGI-EFLL can effectively mitigate the direct current (DC) bias stemming from non-ideal factors, such as the inverter non-linearities and detection errors, without introducing additional parameters. Initially, the active flux observer model and the limitations of the conventional SOGI-FLL are presented. Subsequently, the proposed flux observer based on TOGI-EFLL has been intensively investigated. Furthermore, the design of the damping factor and the digital implementation of the algorithm are developed to ensure seamless integration into digital systems. Finally, the effectiveness of the proposed sensorless control strategy is validated through the comprehensive experimental results.

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用于 IPMSM 无传感器控制的 TOGI-EFLL 磁通量观测器研究

为了提高室内永磁同步电机（IPMSMs）无传感器控制的性能，本文介绍了一种基于三阶广义积分器与增强型锁频环（TOGI-EFLL）的磁通观测器。与传统的带锁频环的二阶广义积分器（SOGI-FLL）相比，本文提出的 TOGI-EFLL 可以有效缓解由逆变器非线性和检测误差等非理想因素引起的直流（DC）偏差，而无需引入额外参数。首先，介绍了有源磁通观测器模型和传统 SOGI-FLL 的局限性。随后，对基于 TOGI-EFLL 的拟议磁通量观测器进行了深入研究。此外，还开发了阻尼系数的设计和算法的数字实现，以确保无缝集成到数字系统中。最后，通过综合实验结果验证了所提出的无传感器控制策略的有效性。

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来源期刊

IET Power Electronics ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

5.50

自引率

10.00%

发文量

195

审稿时长

5.1 months

期刊介绍： IET Power Electronics aims to attract original research papers, short communications, review articles and power electronics related educational studies. The scope covers applications and technologies in the field of power electronics with special focus on cost-effective, efficient, power dense, environmental friendly and robust solutions, which includes: Applications: Electric drives/generators, renewable energy, industrial and consumable applications (including lighting, welding, heating, sub-sea applications, drilling and others), medical and military apparatus, utility applications, transport and space application, energy harvesting, telecommunications, energy storage management systems, home appliances. Technologies: Circuits: all type of converter topologies for low and high power applications including but not limited to: inverter, rectifier, dc/dc converter, power supplies, UPS, ac/ac converter, resonant converter, high frequency converter, hybrid converter, multilevel converter, power factor correction circuits and other advanced topologies. Components and Materials: switching devices and their control, inductors, sensors, transformers, capacitors, resistors, thermal management, filters, fuses and protection elements and other novel low-cost efficient components/materials. Control: techniques for controlling, analysing, modelling and/or simulation of power electronics circuits and complete power electronics systems. Design/Manufacturing/Testing: new multi-domain modelling, assembling and packaging technologies, advanced testing techniques. Environmental Impact: Electromagnetic Interference (EMI) reduction techniques, Electromagnetic Compatibility (EMC), limiting acoustic noise and vibration, recycling techniques, use of non-rare material. Education: teaching methods, programme and course design, use of technology in power electronics teaching, virtual laboratory and e-learning and fields within the scope of interest. Special Issues. Current Call for papers: Harmonic Mitigation Techniques and Grid Robustness in Power Electronic-Based Power Systems - https://digital-library.theiet.org/files/IET_PEL_CFP_HMTGRPEPS.pdf