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Main Authors: Lee, Jonghyeon, Hamzi, Boumediene, Kevrekidis, Yannis, Owhadi, Houman
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.03003
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author Lee, Jonghyeon
Hamzi, Boumediene
Kevrekidis, Yannis
Owhadi, Houman
author_facet Lee, Jonghyeon
Hamzi, Boumediene
Kevrekidis, Yannis
Owhadi, Houman
contents In this paper we use Gaussian processes (kernel methods) to learn mappings between trajectories of distinct differential equations. Our goal is to simplify both the representation and the solution of these equations. We begin by examining the Cole-Hopf transformation, a classical result that converts the nonlinear, viscous Burgers' equation into the linear heat equation. We demonstrate that this transformation can be effectively learned using Gaussian process regression, either from single or from multiple initial conditions of the Burgers equation. We then extend our methodology to discover mappings between initial conditions of a nonlinear partial differential equation (PDE) and a linear PDE, where the exact form of the linear PDE remains unknown and is inferred through Computational Graph Completion (CGC), a generalization of Gaussian Process Regression from approximating single input/output functions to approximating multiple input/output functions that interact within a computational graph. Further, we employ CGC to identify a local transformation from the nonlinear ordinary differential equation (ODE) of the Brusselator to its Poincaré normal form, capturing the dynamics around a Hopf bifurcation. We conclude by addressing the broader question of whether systematic transformations between nonlinear and linear PDEs can generally exist, suggesting avenues for future research.
format Preprint
id arxiv_https___arxiv_org_abs_2410_03003
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Gaussian Processes simplify differential equations
Lee, Jonghyeon
Hamzi, Boumediene
Kevrekidis, Yannis
Owhadi, Houman
Dynamical Systems
In this paper we use Gaussian processes (kernel methods) to learn mappings between trajectories of distinct differential equations. Our goal is to simplify both the representation and the solution of these equations. We begin by examining the Cole-Hopf transformation, a classical result that converts the nonlinear, viscous Burgers' equation into the linear heat equation. We demonstrate that this transformation can be effectively learned using Gaussian process regression, either from single or from multiple initial conditions of the Burgers equation. We then extend our methodology to discover mappings between initial conditions of a nonlinear partial differential equation (PDE) and a linear PDE, where the exact form of the linear PDE remains unknown and is inferred through Computational Graph Completion (CGC), a generalization of Gaussian Process Regression from approximating single input/output functions to approximating multiple input/output functions that interact within a computational graph. Further, we employ CGC to identify a local transformation from the nonlinear ordinary differential equation (ODE) of the Brusselator to its Poincaré normal form, capturing the dynamics around a Hopf bifurcation. We conclude by addressing the broader question of whether systematic transformations between nonlinear and linear PDEs can generally exist, suggesting avenues for future research.
title Gaussian Processes simplify differential equations
topic Dynamical Systems
url https://arxiv.org/abs/2410.03003