Efficient Neural Hybrid System Learning and Interpretable Transition System Abstraction for Dynamical Systems1

Yejiang Yang; Zihao Mo; Weiming Xiang

doi:10.1115/1.4066516

Efficient Neural Hybrid System Learning and Interpretable Transition System Abstraction for Dynamical Systems1

Yejiang Yang
, Zihao Mo
, Weiming Xiang

Computer Science

Research output: Contribution to journal › Article › peer-review

Abstract

This article proposes a neural network hybrid modeling framework for dynamics learning to promote an interpretable, computationally efficient method of dynamics learning and system identification. First, a low-level model is trained to learn the system dynamics, which utilizes multiple simple neural networks to approximate the local dynamics generated from data-driven partitions. Then, based on the low-level model, a high-level model is trained to abstract the low-level neural hybrid system model into a transition system that allows computational tree logic (CTL) verification to promote model's ability to handle human interaction and verification efficiency.

Original language	English (US)
Article number	011001
Journal	ASME Letters in Dynamic Systems and Control
Volume	5
Issue number	1
DOIs	https://doi.org/10.1115/1.4066516
State	Published - Jan 1 2025

Keywords

complex systems
hybrid and distributed system modeling
maximum-entropy partitioning
model abstraction
modeling
neural networks
nonlinear system
nonlinear system modeling

ASJC Scopus subject areas

Industrial and Manufacturing Engineering
Automotive Engineering
Biomedical Engineering
Mechanical Engineering

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10.1115/1.4066516

Cite this

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title = "Efficient Neural Hybrid System Learning and Interpretable Transition System Abstraction for Dynamical Systems1",

abstract = "This article proposes a neural network hybrid modeling framework for dynamics learning to promote an interpretable, computationally efficient method of dynamics learning and system identification. First, a low-level model is trained to learn the system dynamics, which utilizes multiple simple neural networks to approximate the local dynamics generated from data-driven partitions. Then, based on the low-level model, a high-level model is trained to abstract the low-level neural hybrid system model into a transition system that allows computational tree logic (CTL) verification to promote model's ability to handle human interaction and verification efficiency.",

keywords = "complex systems, hybrid and distributed system modeling, maximum-entropy partitioning, model abstraction, modeling, neural networks, nonlinear system, nonlinear system modeling",

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N2 - This article proposes a neural network hybrid modeling framework for dynamics learning to promote an interpretable, computationally efficient method of dynamics learning and system identification. First, a low-level model is trained to learn the system dynamics, which utilizes multiple simple neural networks to approximate the local dynamics generated from data-driven partitions. Then, based on the low-level model, a high-level model is trained to abstract the low-level neural hybrid system model into a transition system that allows computational tree logic (CTL) verification to promote model's ability to handle human interaction and verification efficiency.

AB - This article proposes a neural network hybrid modeling framework for dynamics learning to promote an interpretable, computationally efficient method of dynamics learning and system identification. First, a low-level model is trained to learn the system dynamics, which utilizes multiple simple neural networks to approximate the local dynamics generated from data-driven partitions. Then, based on the low-level model, a high-level model is trained to abstract the low-level neural hybrid system model into a transition system that allows computational tree logic (CTL) verification to promote model's ability to handle human interaction and verification efficiency.

KW - complex systems

KW - hybrid and distributed system modeling

KW - maximum-entropy partitioning

KW - model abstraction

KW - modeling

KW - neural networks

KW - nonlinear system

KW - nonlinear system modeling

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Efficient Neural Hybrid System Learning and Interpretable Transition System Abstraction for Dynamical Systems1

Abstract

Keywords

ASJC Scopus subject areas

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