Energy-Based Modeling and Structure-Preserving Discretization of Physical Systems

TL;DR

This paper introduces a unified energy-based modeling framework that preserves physical structure and energy properties during discretization, applicable to complex multiphysics systems and ensuring physical consistency in simulations.

Contribution

It presents a systematic approach for structure-preserving discretization of energy-based models, handling complex systems like high-index DAEs and nonlinear multiphysics problems.

Findings

Framework maintains energy dissipation in numerical models

Applicable to poroelastic media, circuits, and phase-field models

Ensures physical properties are preserved in discretization

Abstract

This paper develops a comprehensive mathematical framework for energy-based modeling of physical systems, with particular emphasis on preserving fundamental structural properties throughout the modeling and discretization process. The approach provides systematic methods for handling challenging system classes including high-index differential-algebraic equations and nonlinear multiphysics problems. Theoretical foundations are established for regularizing constrained systems while maintaining physical consistency, analyzing stability properties, and constructing numerical discretizations that inherit the energy dissipation structure of the continuous models. The versatility and practical utility of the framework are demonstrated through applications across multiple domains including poroelastic media, nonlinear circuits, constrained mechanics, and phase-field models. The results ensure that essential physical properties such as energy balance and dissipation are maintained from the continuous formulation through to numerical implementation, providing robust foundations for computational physics and engineering applications.