Improving the accuracy of permanent magnet rotor position estimation for stepper motors using magnetic induction and harmonic rejection

Tran, Hoang Ngoc; Nguyen, Ty Trung; Cao, Hung Quang; Le, Kien Minh; Jeon, Jae Wook

doi:10.1049/iet-pel.2019.1128

Cited by 2 publications

(2 citation statements)

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“…30 As a result, the value of speed error is computed, and the proposed controller controls the error value. The following speed error value is taken into account: a formula (22),…”

Section: Speed Controller Designmentioning

confidence: 99%

“…The suggested technique has the ability to precisely identify bearing problems and may be used to monitor the health of stepper motors. Ngoc et al, 22 proposed a sensor less design based on electromagnetic force (back‐EMF) due to magnetic induction and suppression of harmonics by means of a third‐order orthogonal phase‐locked loop and an integrated harmonic filter (IHF). The accuracy was examined by taking into account the PM rotor position estimation errors.…”

Section: Recent Research Workmentioning

confidence: 99%

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A BMO‐based MRPID controller with optimal control of speed in hybrid stepper motor

Deepa,

Venkatesh,

Nandalal

2023

Optim Control Appl Methods

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This paper proposes a Barnacles mating optimizer‐based multi‐resolution proportional‐integral derivative (MRPID) controller for precise speed control of the hybrid stepper motor (HSM). The proposed approach is a barnacle mating optimizer (BMO) control scheme. The main objective of this approach is to use the MRPID controller to improve speed control in particular and uncertain conditions. The BMO is utilized to create the proposed MRPID controller. The proposed converter has a low switching voltage and uses a low input current. The proposed converter supplies a large amount of power to the voltage source inverter (VSI), which converts DC to AC and then supplies it to the HSM. The HSM can be utilized in various settings, including robots and factory applications. Then, the performance of the proposed system has been evaluated in the MATLAB platform and compared with various existing systems. The existing adaptive neuro‐fuzzy inference system (ANFIS) and the moth flame optimization algorithm (MFO) methods are used to validate the efficiency of the proposed controller. The proposed system rise time is 0.0007, the settling time is 0.1, the recovery time is 0.221, the AMU is 1.205, the IAE is 0.1034, and the SSE is 0.234. According to the simulation findings, the suggested system is statistically significant.

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“…30 As a result, the value of speed error is computed, and the proposed controller controls the error value. The following speed error value is taken into account: a formula (22),…”

Section: Speed Controller Designmentioning

confidence: 99%

Section: Recent Research Workmentioning

confidence: 99%