Input-to-State Stable Neural Ordinary Differential Equations with Applications to Transient Modeling of Circuits

Alan Yang; Jie Xiong; Maxim Raginsky; Elyse Rosenbaum

2022 L4DC L4DC 2022

Input-to-State Stable Neural Ordinary Differential Equations with Applications to Transient Modeling of Circuits

Abstract

This paper proposes a class of neural ordinary differential equations parametrized by provably input-to-state stable continuous-time recurrent neural networks. The model dynamics are defined by construction to be input-to-state stable (ISS) with respect to an ISS-Lyapunov function that is learned jointly with the dynamics. We use the proposed method to learn cheap-to-simulate behavioral models for electronic circuits that can accurately reproduce the behavior of various digital and analog circuits when simulated by a commercial circuit simulator, even when interconnected with circuit components not encountered during training. We also demonstrate the feasibility of learning ISS-preserving perturbations to the dynamics for modeling degradation effects due to circuit aging.

🌉 Interdisciplinary Bridge — Artificial Intelligence and Machine Learning

🧭 Keyword Pioneer — circuit modeling

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics

Authors

Alan Yang , Jie Xiong , Maxim Raginsky , Elyse Rosenbaum

Topics

Artificial Intelligence > Core AI > Agent Systems Artificial Intelligence > Core AI > Interpretability Machine Learning > Optimization & Theory > Neural Network Optimization

Keywords

neural ordinary differential equation input-to-state stability behavioral model circuit modeling iss-lyapunov function

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