Litcius/Paper detail

Adaptive Digital Twin Framework for PMSM Thermal Safety Monitoring: Integrating Bayesian Self-Calibration with Hierarchical Physics-Aware Network

Jinqiu Gao, Junze Luo, Shicai Yin, Chao Gong, Saibo Wang, Gerui Zhang

2026Machines22 citationsDOIOpen Access PDF

Abstract

To address the limitations of parameter drift in physical models and poor generalization in data-driven methods, this paper proposes a self-evolving digital twin framework for PMSM thermal safety. The framework integrates a dynamic-batch Bayesian calibration (DBBC) algorithm and a hierarchical physics-aware network (HPA-Net). First, the DBBC eliminates plant–model mismatch by robustly identifying stochastic parameters from operational data. Subsequently, the HPA-Net adopts a “physics-augmented” strategy, utilizing the calibrated physical model as a dynamic prior to directly infer high-fidelity temperature via a hierarchical training scheme. Furthermore, a real-time demagnetization safety margin (DSM) monitoring strategy is integrated to eliminate “false safe” zones. Experimental validation on a PMSM test bench confirms the superior performance of the proposed framework, which achieves a Root Mean Square Error (RMSE) of 0.919 °C for the stator winding and 1.603 °C for the permanent magnets. The proposed digital twin ensures robust thermal safety even under unseen operating conditions, transforming the monitoring system into a proactive safety guardian.

Topics & Concepts

Margin (machine learning)Computer scienceCalibrationBayesian probabilityBayesian networkStatorGeneralizationTest benchEngineeringPrior probabilityControl engineeringProbabilistic logicControl theory (sociology)Bayesian inferenceThermalRoot mean squareStability (learning theory)Mean squared errorMachine Fault Diagnosis TechniquesModel Reduction and Neural NetworksElectric Motor Design and Analysis