AN ADAPTIVE NEURAL PI CONTROL FRAMEWORK USING DEEP REINFORCEMENT LEARNING FOR HIGH-PERFORMANCE PMSM SPEED DRIVES

Các tác giả

  • Do Trung Khanh Cong Ho Chi Minh City University of Technical Education, No. 1 Vo Van Ngan, Thu Duc Ward, Ho Chi Minh City Tác giả
  • Vo Ngoc Vinh Lac Hong University, No. 10 Huynh Van Nghe, Tran Bien Ward, Dong Nai Province, Vietnam Tác giả liên hệ
  • Nguyen Minh Tam Ho Chi Minh City University of Technical Education, No. 1 Vo Van Ngan, Thu Duc Ward, Ho Chi Minh City Tác giả
  • Le Tien Loc Lac Hong University, No. 10 Huynh Van Nghe, Tran Bien Ward, Dong Nai Province, Vietnam Tác giả

DOI:

https://doi.org/10.62985/j.huit_ojs.vol26.no2E.400

Từ khóa:

Permanent magnet synchronous motor, adaptive PI control, deep reinforcement learning, DDPG, neural networks

Tóm tắt

High-performance PMSM speed control remains challenging due to parameter uncertainties, nonlinear dynamics, and load disturbances. Although conventional PI controllers are widely adopted, their fixed gains limit adaptability under varying operating conditions. To overcome this, this paper proposes an adaptive DRL-based neural PI control framework for PMSM drives. The method integrates a DDPG algorithm with an RBF neural network for continuous online gain tuning. Furthermore, an anti-windup mechanism and a reference model–based augmentation are incorporated to ensure closed-loop stability under actuator saturation. The learning objective is formulated to optimize tracking accuracy, transient performance, and disturbance rejection. Simulation results demonstrate that the proposed framework significantly outperforms fixed-gain PI controllers, minimizing settling time, overshoot, and steady-state error under ideal physical constraints. These findings confirm the framework's robustness and efficiency for advanced motor drives.

Tài liệu tham khảo

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Lượt tải xuống

Đã Xuất bản

2026-06-11

Số

Tập 26 Số 2E (2026)

Chuyên mục

Điện - Điện tử - Tự động hóa