Fault-tolerant deadbeat model predictive current control for a five-phase PMSM with improved SVPWM

Saeed, Suleman; Zhao, Wenxiang; Wang, Huanan; Tao, Tao; Khan, Faisal

doi:10.23919/cjee.2021.000030

Cited by 23 publications

(9 citation statements)

References 24 publications

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“…For the left eigenvector, the left eigenvector sensitivity ∂ψ i T /∂b can be calculated by simply replacing all the closed-loop Jacobian matrices A cl in Eq. (10) with their transpose T cl A and replacing the right eigenvector with the transpose ψ i of the left eigenvector.…”

Section: Eigenvalue and Eigenvector Sensitivitymentioning

confidence: 99%

“…Although an LQR can also be designed to improve the time-domain dynamic performance by incorporating settling time and overshoot into the linear quadratic function, it requires full-state feedback, which increases the complexity of the control system. Other control methods based on discrete control, such as deadbeat control [9][10] , adjust the duty cycle based on the principle that the controlled variable of the next digital control cycle should be equal to the reference value. Deadbeat control can theoretically achieve a dynamic adjustment of the converter within a limited number of steps in digital control.…”

Section: Introduction1mentioning

confidence: 99%

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Time-domain Dynamic-performance-improvement Method for Pulse-width-modulated DC-DC Converters Based on Eigenvalue and Eigenvector Sensitivity

Zhou

Pan

et al. 2023

Chin. J. Electr. Eng.

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For pulse-width modulated (PWM) DC-DC converters, the input voltage fluctuation and load variation in practical applications make it necessary for them to have better dynamic performance to meet the regulation requirements of the system. The dynamic-performance-improvement method for PWM DC-DC converters is mainly based on indirect dynamic performance indices, such as the gain margin and phase margin. However, both settling time and overshoot in the time domain are important in practical engineering. This makes it difficult for designers to obtain a clear understanding of the time-domain dynamic performance that can be achieved with improved control. In this study, a direct analysis of the time-domain dynamic characteristic of PWM DC-DC converters is performed. A dynamic-performance-improvement method based on eigenvalues and eigenvector sensitivity (E 2 S-based DPIM) is proposed to directly improve the time-domain dynamic performance index of PWM DC-DC converters. By considering a boost converter with proportional-integral control as an example, an additional virtual inductor current feedback control was designed using the proposed dynamic-performance-improvement method. Simulation and experimental results verify the validity and accuracy of the proposed dynamic-performance-improvement method.

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Section: Eigenvalue and Eigenvector Sensitivitymentioning

confidence: 99%

Section: Introduction1mentioning

confidence: 99%

Time-domain Dynamic-performance-improvement Method for Pulse-width-modulated DC-DC Converters Based on Eigenvalue and Eigenvector Sensitivity

Zhou

Pan

et al. 2023

Chin. J. Electr. Eng.

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“…The above analysis and Equation (5) indicate that the existence of dead-zone can cause an error between the ideal output voltage and actual output voltage, which mainly depends on the duration of the dead-zone time and the direction of the phase current.…”

Section: Inverter Dead-zone Analysismentioning

confidence: 99%

“…Model predictive control (MPC) has advantages such as good control effect and high current tracking accuracy, and is widely used in the field of motor control [3, 4]. MPC can be divided into Continuous Control Set Model Predictive Control (CCS‐MPC) [5, 6] and Finite Control Set Model Predictive Control (FCS‐MPC) [7, 8]. Although CCS‐MPC has better robustness when parameters change, it has drawbacks such as high computational complexity and slow response [7].…”

Section: Introductionmentioning

confidence: 99%

Three‐vector model‐free predictive control for permanent magnet synchronous motor

Wen,

Zhang,

Zhang

2023

IET Power Electronics

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A three‐vector model‐free predictive control (TV‐MFPC) strategy is proposed to address the problem of model predictive control systems performance degradation caused by parameter mismatch and inverter dead‐zone. Firstly, an ultra‐local model is constructed for parameter mismatch and dead‐zone. Then, to improve the adaptive capability of the observer to parameter variations, sliding mode control is introduced, and an Improved Extended State Observer (IESO) is designed to estimate unknown disturbances in the ultra‐local model and provide feedforward compensation for the current loop. Finally, the proposed strategy is experimentally validated, and the results demonstrate that it reduces dependence on the model, suppresses the phase current distortion caused by dead‐zone, and improves the robustness of the control system.

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“…Permanent magnet synchronous motors (PMSMs) have been widely utilized in several high-performance applications owing to their advantages of high efficiency, high torque density, and negligible size [1][2] . An increasing number of multiphase motors, especially six-phase motors, have been applied in applications requiring high-power output at lower voltage and strong fault-tolerant capability, such as electric aircraft, electric vehicles, and railway traction [3][4][5][6][7] . Notably, the torque ripple of the asymmetrical dual three-phase PMSM is lesser than that of the symmetrical six-phase PMSM, which has garnered the attention of engineers.…”

Section: Introductionmentioning

confidence: 99%

Model Predictive Torque Control for a Dual Three-phase PMSM Using Modified Dual Virtual Vector Modulation Method

Ren

Tang³

et al. 2022

Chin. J. Electr. Eng.

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Single voltage vectors applied in the conventional model predictive torque control (MPTC) for multiphase motors do not only suffer from serious torque and stator flux ripples but also cause the large harmonic current. To address the aforementioned challenges, an MPTC using a modified dual virtual vector modulation method is proposed to improve the operational performance of a dual three-phase permanent magnet synchronous motor. Virtual voltage vectors are synthesized as the candidate control set to restrain the harmonic current. A transformation method is introduced to consider both the stator flux and torque in the duty cycle modulation. The torque and stator flux ripples are simultaneously reduced by addressing the limitations of nonuniform units.Furthermore, the null voltage vector is then inserted to expand the modulation range and improve the steady-state performance.Moreover, the sawtooth carrier is adopted to address the challenge of the asymmetric switch sequence caused by the modified modulation. Finally, the experimental results are presented to verify the effectiveness and superiority of the proposed MPTC method.

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Fault-tolerant deadbeat model predictive current control for a five-phase PMSM with improved SVPWM

Cited by 23 publications

References 24 publications

Time-domain Dynamic-performance-improvement Method for Pulse-width-modulated DC-DC Converters Based on Eigenvalue and Eigenvector Sensitivity

Time-domain Dynamic-performance-improvement Method for Pulse-width-modulated DC-DC Converters Based on Eigenvalue and Eigenvector Sensitivity

Three‐vector model‐free predictive control for permanent magnet synchronous motor

Model Predictive Torque Control for a Dual Three-phase PMSM Using Modified Dual Virtual Vector Modulation Method

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