Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Watson, Joe, Song, Chen, Weeger, Oliver, Gruner, Theo, Le, An T., Pompetzki, Kay, Hendawy, Ahmed, Arenz, Oleg, Trojak, Will, Cranmer, Miles, D'Eramo, Carlo, Bülow, Fabian, Goyal, Tanmay, Peters, Jan, Hoffman, Martin W.
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2408.09840
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866912377150111744
author Watson, Joe
Song, Chen
Weeger, Oliver
Gruner, Theo
Le, An T.
Pompetzki, Kay
Hendawy, Ahmed
Arenz, Oleg
Trojak, Will
Cranmer, Miles
D'Eramo, Carlo
Bülow, Fabian
Goyal, Tanmay
Peters, Jan
Hoffman, Martin W.
author_facet Watson, Joe
Song, Chen
Weeger, Oliver
Gruner, Theo
Le, An T.
Pompetzki, Kay
Hendawy, Ahmed
Arenz, Oleg
Trojak, Will
Cranmer, Miles
D'Eramo, Carlo
Bülow, Fabian
Goyal, Tanmay
Peters, Jan
Hoffman, Martin W.
contents This survey examines the broad suite of methods and models for combining machine learning with physics knowledge for prediction and forecast, with a focus on partial differential equations. These methods have attracted significant interest due to their potential impact on advancing scientific research and industrial practices by improving predictive models with small- or large-scale datasets and expressive predictive models with useful inductive biases. The survey has two parts. The first considers incorporating physics knowledge on an architectural level through objective functions, structured predictive models, and data augmentation. The second considers data as physics knowledge, which motivates looking at multi-task, meta, and contextual learning as an alternative approach to incorporating physics knowledge in a data-driven fashion. Finally, we also provide an industrial perspective on the application of these methods and a survey of the open-source ecosystem for physics-informed machine learning.
format Preprint
id arxiv_https___arxiv_org_abs_2408_09840
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Machine Learning with Physics Knowledge for Prediction: A Survey
Watson, Joe
Song, Chen
Weeger, Oliver
Gruner, Theo
Le, An T.
Pompetzki, Kay
Hendawy, Ahmed
Arenz, Oleg
Trojak, Will
Cranmer, Miles
D'Eramo, Carlo
Bülow, Fabian
Goyal, Tanmay
Peters, Jan
Hoffman, Martin W.
Machine Learning
Numerical Analysis
Computational Physics
This survey examines the broad suite of methods and models for combining machine learning with physics knowledge for prediction and forecast, with a focus on partial differential equations. These methods have attracted significant interest due to their potential impact on advancing scientific research and industrial practices by improving predictive models with small- or large-scale datasets and expressive predictive models with useful inductive biases. The survey has two parts. The first considers incorporating physics knowledge on an architectural level through objective functions, structured predictive models, and data augmentation. The second considers data as physics knowledge, which motivates looking at multi-task, meta, and contextual learning as an alternative approach to incorporating physics knowledge in a data-driven fashion. Finally, we also provide an industrial perspective on the application of these methods and a survey of the open-source ecosystem for physics-informed machine learning.
title Machine Learning with Physics Knowledge for Prediction: A Survey
topic Machine Learning
Numerical Analysis
Computational Physics
url https://arxiv.org/abs/2408.09840