TY - JOUR
T1 - Encoderless Parallel Predictive Torque Control for Induction Machine Using A Robust Model Reference Adaptive System
AU - Xie, Haotian
AU - Wang, Fengxiang
AU - He, Yingjie
AU - Rodriguez, Jose
AU - Kennel, Ralph
N1 - Publisher Copyright:
IEEE
PY - 2021
Y1 - 2021
N2 - This paper proposes a robust model reference adaptive system (MRAS) estimator incorporating online parameter identification algorithm for parallel predictive torque control (PPTC) scheme. In contrast to conventional predictive torque control (PTC), the proposed PPTC is designed to facilitate the determination of weighting factor that modifies the relative importance of the control objectives, by simultaneously evaluating the torque and flux tracking error terms. The weighting factor is fine-tuned via an adaptive selecting mechanism, to obtain the attractive feature of reduced torque and current tracking errors. Besides, an encoderless MRAS-based estimator is employed for rotor speed and stator flux estimation to reduce the hardware complexity. However, this proposed encoderless PPTC algorithm still suffers from weak robustness against inevitable disturbances caused by parameter variations, which is an important issue to be further investigated. In this paper, an encoderless MRAS estimator combined with online parameter identification algorithm is proposed as an effective solution to accurately estimate the rotor speed and predicted stator flux-linkage, that improves robustness against mismatched parameters for the proposed encoderless PPTC scheme. The feasibility of the proposed algorithm is verified through the obtained experimental measurements, that achieves precise speed tracking capability as well as reduced torque and current tracking errors.
AB - This paper proposes a robust model reference adaptive system (MRAS) estimator incorporating online parameter identification algorithm for parallel predictive torque control (PPTC) scheme. In contrast to conventional predictive torque control (PTC), the proposed PPTC is designed to facilitate the determination of weighting factor that modifies the relative importance of the control objectives, by simultaneously evaluating the torque and flux tracking error terms. The weighting factor is fine-tuned via an adaptive selecting mechanism, to obtain the attractive feature of reduced torque and current tracking errors. Besides, an encoderless MRAS-based estimator is employed for rotor speed and stator flux estimation to reduce the hardware complexity. However, this proposed encoderless PPTC algorithm still suffers from weak robustness against inevitable disturbances caused by parameter variations, which is an important issue to be further investigated. In this paper, an encoderless MRAS estimator combined with online parameter identification algorithm is proposed as an effective solution to accurately estimate the rotor speed and predicted stator flux-linkage, that improves robustness against mismatched parameters for the proposed encoderless PPTC scheme. The feasibility of the proposed algorithm is verified through the obtained experimental measurements, that achieves precise speed tracking capability as well as reduced torque and current tracking errors.
KW - model reference adaptive system (MRAS)
KW - online parameter identification
KW - optimal weighting factor
KW - parallel predictive torque control
KW - Prediction algorithms
KW - Predictive models
KW - Robustness
KW - Rotors
KW - Stators
KW - Torque
KW - Torque control
UR - http://www.scopus.com/inward/record.url?scp=85112213403&partnerID=8YFLogxK
U2 - 10.1109/TEC.2021.3102305
DO - 10.1109/TEC.2021.3102305
M3 - Article
AN - SCOPUS:85112213403
SN - 0885-8969
JO - IEEE Transactions on Energy Conversion
JF - IEEE Transactions on Energy Conversion
ER -