Multi-loop resonant control applied to linear permanent magnet synchronous motors for periodic position tracking

Multi-loop resonant control applied to linear permanent magnet synchronous motors for periodic position tracking

This paper addresses the periodic position tracking and load force disturbance rejection in linear permanent magnet synchronous motors (LPMSM). Periodic position tracking is a challenge for LPMSMs, as there are electromagnetic forces that are not uniform along the actuator stroke due to end effects,...

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Bibliographic Details
Published in:Mechatronics (Oxford) Vol. 99; p. 103163
Main Authors: Boff, Ben Hur Bandeira, Flores, Jeferson Vieira, Eckert, Paulo Roberto
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-05-2024
Subjects:
Linear electromagnetic actuators
Linear matrix inequalities
Linear permanent magnet synchronous motor
Position tracking
Resonant control
Resonant control
Linear matrix inequalities
Linear permanent magnet synchronous motor
Linear electromagnetic actuators
Position tracking
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Summary:This paper addresses the periodic position tracking and load force disturbance rejection in linear permanent magnet synchronous motors (LPMSM). Periodic position tracking is a challenge for LPMSMs, as there are electromagnetic forces that are not uniform along the actuator stroke due to end effects, which can lead to position variations. The proposed control structure combines a proportional–integral (PI) controller in the direct-axis control loop and a modified PI plus a multiple resonant controller (PI-RES) in the quadrature-axis control loop to ensure periodic reference tracking and disturbance rejection. The controller design is carried out by solving a convex optimization problem under linear matrix inequality (LMI) constraints, which guarantee closed-loop stability and transient performance. Simulations and experimental results are performed using a dual quasi-Halbach permanent magnet array linear tubular actuator with a coreless moving armature. The effectiveness of the proposed method is evaluated by applying position reference signals with different frequencies and harmonic compositions in conjunction with two types of load force disturbances. Experiments show the proposed controller results in precise reference tracking with negligible steady-state error.
ISSN:0957-4158
1873-4006
DOI:10.1016/j.mechatronics.2024.103163