Self-adaptive physics-informed quantum machine learning for solving differential equations

Chebyshev polynomials have shown significant promise as an efficient tool for both classical and quantum neural networks to solve linear and nonlinear differential equations (DEs). In this work, we adapt and generalize this framework in a quantum machine learning setting for a variety of problems, i...

Full description

Saved in:

Bibliographic Details
Main Authors:	Abhishek Setty, Rasul Abdusalamov, Felix Motzoi
Format:	Article
Language:	English
Published:	IOP Publishing 2025-01-01
Series:	Machine Learning: Science and Technology
Subjects:	quantum machine learning physics-informed neural networks variational quantum algorithms differential equations
Online Access:	https://doi.org/10.1088/2632-2153/ada3ab
Tags:	Add Tag No Tags, Be the first to tag this record!

_version_	1841543714339553280
author	Abhishek Setty Rasul Abdusalamov Felix Motzoi
author_facet	Abhishek Setty Rasul Abdusalamov Felix Motzoi
author_sort	Abhishek Setty
collection	DOAJ
description	Chebyshev polynomials have shown significant promise as an efficient tool for both classical and quantum neural networks to solve linear and nonlinear differential equations (DEs). In this work, we adapt and generalize this framework in a quantum machine learning setting for a variety of problems, including the 2D Poisson’s equation, second-order linear DE, system of DEs, nonlinear Duffing and Riccati equation. In particular, we propose in the quantum setting a modified Self-Adaptive Physics-Informed Neural Network approach, where self-adaptive weights are applied to problems with multi-objective loss functions. We further explore capturing correlations in our loss function using a quantum-correlated measurement, resulting in improved accuracy for initial value problems. We analyse also the use of entangling layers and their impact on the solution accuracy for second-order DEs. The results indicate a promising approach to the near-term evaluation of DEs on quantum devices.
format	Article
id	doaj-art-ac8d761f44f349689a716a7d5de0f093
institution	Kabale University
issn	2632-2153
language	English
publishDate	2025-01-01
publisher	IOP Publishing
record_format	Article
series	Machine Learning: Science and Technology
spelling	doaj-art-ac8d761f44f349689a716a7d5de0f0932025-01-13T07:32:55ZengIOP PublishingMachine Learning: Science and Technology2632-21532025-01-016101500210.1088/2632-2153/ada3abSelf-adaptive physics-informed quantum machine learning for solving differential equationsAbhishek Setty0https://orcid.org/0009-0001-4858-7985Rasul Abdusalamov1https://orcid.org/0000-0003-4988-4794Felix Motzoi2https://orcid.org/0000-0003-4756-5976Department of Continuum Mechanics, RWTH Aachen University , Aachen 52062, Germany; Forschungszentrum Jülich, Institute of Quantum Control (PGI-8) , Jülich D-52425, Germany; Institute for Theoretical Physics, University of Cologne , Cologne D-50937, GermanyDepartment of Continuum Mechanics, RWTH Aachen University , Aachen 52062, GermanyForschungszentrum Jülich, Institute of Quantum Control (PGI-8) , Jülich D-52425, Germany; Institute for Theoretical Physics, University of Cologne , Cologne D-50937, GermanyChebyshev polynomials have shown significant promise as an efficient tool for both classical and quantum neural networks to solve linear and nonlinear differential equations (DEs). In this work, we adapt and generalize this framework in a quantum machine learning setting for a variety of problems, including the 2D Poisson’s equation, second-order linear DE, system of DEs, nonlinear Duffing and Riccati equation. In particular, we propose in the quantum setting a modified Self-Adaptive Physics-Informed Neural Network approach, where self-adaptive weights are applied to problems with multi-objective loss functions. We further explore capturing correlations in our loss function using a quantum-correlated measurement, resulting in improved accuracy for initial value problems. We analyse also the use of entangling layers and their impact on the solution accuracy for second-order DEs. The results indicate a promising approach to the near-term evaluation of DEs on quantum devices.https://doi.org/10.1088/2632-2153/ada3abquantum machine learningphysics-informed neural networksvariational quantum algorithmsdifferential equations
spellingShingle	Abhishek Setty Rasul Abdusalamov Felix Motzoi Self-adaptive physics-informed quantum machine learning for solving differential equations Machine Learning: Science and Technology quantum machine learning physics-informed neural networks variational quantum algorithms differential equations
title	Self-adaptive physics-informed quantum machine learning for solving differential equations
title_full	Self-adaptive physics-informed quantum machine learning for solving differential equations
title_fullStr	Self-adaptive physics-informed quantum machine learning for solving differential equations
title_full_unstemmed	Self-adaptive physics-informed quantum machine learning for solving differential equations
title_short	Self-adaptive physics-informed quantum machine learning for solving differential equations
title_sort	self adaptive physics informed quantum machine learning for solving differential equations
topic	quantum machine learning physics-informed neural networks variational quantum algorithms differential equations
url	https://doi.org/10.1088/2632-2153/ada3ab
work_keys_str_mv	AT abhisheksetty selfadaptivephysicsinformedquantummachinelearningforsolvingdifferentialequations AT rasulabdusalamov selfadaptivephysicsinformedquantummachinelearningforsolvingdifferentialequations AT felixmotzoi selfadaptivephysicsinformedquantummachinelearningforsolvingdifferentialequations

Self-adaptive physics-informed quantum machine learning for solving differential equations

Similar Items