Related papers: Parameter Identification for Partial Differential Equations with Spatiotemporal Varying Coefficients

Parameter Identification for Partial Differential Equations with Spatiotemporal Varying Coefficients

URL: http://arxiv.org/abs/2307.00035v1
Date: Fri, 30 Jun 2023 07:17:19 GMT
Title: Parameter Identification for Partial Differential Equations with Spatiotemporal Varying Coefficients
Authors: Guangtao Zhang and Yiting Duan and Guanyu Pan and Qijing Chen and Huiyu Yang and Zhikun Zhang
Abstract summary: We propose a framework that facilitates the investigation of parameter identification for multi-state systems governed by varying partial differential equations. Our framework consists of two integral components: a constrained self-adaptive neural network, and a sub-network physics-informed neural network. We have showcased the efficacy of our framework on two numerical cases: the 1D Burgers' cases with time-varying parameters and the 2 wave equation with a space-varying parameter.
Score: 5.373009527854677
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: To comprehend complex systems with multiple states, it is imperative to reveal the identity of these states by system outputs. Nevertheless, the mathematical models describing these systems often exhibit nonlinearity so that render the resolution of the parameter inverse problem from the observed spatiotemporal data a challenging endeavor. Starting from the observed data obtained from such systems, we propose a novel framework that facilitates the investigation of parameter identification for multi-state systems governed by spatiotemporal varying parametric partial differential equations. Our framework consists of two integral components: a constrained self-adaptive physics-informed neural network, encompassing a sub-network, as our methodology for parameter identification, and a finite mixture model approach to detect regions of probable parameter variations. Through our scheme, we can precisely ascertain the unknown varying parameters of the complex multi-state system, thereby accomplishing the inversion of the varying parameters. Furthermore, we have showcased the efficacy of our framework on two numerical cases: the 1D Burgers' equation with time-varying parameters and the 2D wave equation with a space-varying parameter.

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