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Main Authors: Zheng, Jialin, Wang, Haoyu, Zeng, Yangbin, Mou, Di, Zhang, Xin, Li, Hong, Vazquez, Sergio, Franquelo, Leopoldo G.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.02887
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author Zheng, Jialin
Wang, Haoyu
Zeng, Yangbin
Mou, Di
Zhang, Xin
Li, Hong
Vazquez, Sergio
Franquelo, Leopoldo G.
author_facet Zheng, Jialin
Wang, Haoyu
Zeng, Yangbin
Mou, Di
Zhang, Xin
Li, Hong
Vazquez, Sergio
Franquelo, Leopoldo G.
contents Edge Digital Twins (EDTs) are crucial for monitoring and control of Power Electronics Systems (PES). However, existing modeling approaches struggle to consistently capture continuously evolving hybrid dynamics that are inherent in PES, degrading Sim-to-Real generalization on resource-constrained edge devices. To address these challenges, this paper proposes a Physics-Embedded Neural ODEs (PENODE) that (i) embeds the hybrid operating mechanism as an event automaton to explicitly govern discrete switching and (ii) injects known governing ODE components directly into the neural parameterization of unmodeled dynamics. This unified design yields a differentiable end-to-end trainable architecture that preserves physical interpretability while reducing redundancy, and it supports a cloud-to-edge toolchain for efficient FPGA deployment. Experimental results demonstrate that PENODE achieves significantly higher accuracy in benchmarks in white-box, gray-box, and black-box scenarios, with a 75% reduction in neuron count, validating that the proposed PENODE maintains physical interpretability, efficient edge deployment, and real-time control enhancement.
format Preprint
id arxiv_https___arxiv_org_abs_2508_02887
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Physics-Embedded Neural ODEs for Sim2Real Edge Digital Twins of Hybrid Power Electronics Systems
Zheng, Jialin
Wang, Haoyu
Zeng, Yangbin
Mou, Di
Zhang, Xin
Li, Hong
Vazquez, Sergio
Franquelo, Leopoldo G.
Machine Learning
Systems and Control
Edge Digital Twins (EDTs) are crucial for monitoring and control of Power Electronics Systems (PES). However, existing modeling approaches struggle to consistently capture continuously evolving hybrid dynamics that are inherent in PES, degrading Sim-to-Real generalization on resource-constrained edge devices. To address these challenges, this paper proposes a Physics-Embedded Neural ODEs (PENODE) that (i) embeds the hybrid operating mechanism as an event automaton to explicitly govern discrete switching and (ii) injects known governing ODE components directly into the neural parameterization of unmodeled dynamics. This unified design yields a differentiable end-to-end trainable architecture that preserves physical interpretability while reducing redundancy, and it supports a cloud-to-edge toolchain for efficient FPGA deployment. Experimental results demonstrate that PENODE achieves significantly higher accuracy in benchmarks in white-box, gray-box, and black-box scenarios, with a 75% reduction in neuron count, validating that the proposed PENODE maintains physical interpretability, efficient edge deployment, and real-time control enhancement.
title Physics-Embedded Neural ODEs for Sim2Real Edge Digital Twins of Hybrid Power Electronics Systems
topic Machine Learning
Systems and Control
url https://arxiv.org/abs/2508.02887