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Main Authors: Kapoor, Taniya, Chandra, Abhishek, Stamou, Anastasios, Roberts, Stephen J
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.12556
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author Kapoor, Taniya
Chandra, Abhishek
Stamou, Anastasios
Roberts, Stephen J
author_facet Kapoor, Taniya
Chandra, Abhishek
Stamou, Anastasios
Roberts, Stephen J
contents Real-world systems, from aerospace to railway engineering, are modeled with partial differential equations (PDEs) describing the physics of the system. Estimating robust solutions for such problems is essential. Deep learning-based architectures, such as neural PDE solvers, have recently gained traction as a reliable solution method. The current state of development of these approaches, however, primarily focuses on improving accuracy. The environmental impact of excessive computation, leading to increased carbon emissions, has largely been overlooked. This paper introduces a carbon emission measure for a range of PDE solvers. Our proposed metric, EcoL2, balances model accuracy with emissions across data collection, model training, and deployment. Experiments across both physics-informed machine learning and operator learning architectures demonstrate that the proposed metric presents a holistic assessment of model performance and emission cost. As such solvers grow in scale and deployment, EcoL2 represents a step toward building performant scientific machine learning systems with lower long-term environmental impact.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12556
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond Accuracy: EcoL2 Metric for Sustainable Neural PDE Solvers
Kapoor, Taniya
Chandra, Abhishek
Stamou, Anastasios
Roberts, Stephen J
Machine Learning
Artificial Intelligence
Real-world systems, from aerospace to railway engineering, are modeled with partial differential equations (PDEs) describing the physics of the system. Estimating robust solutions for such problems is essential. Deep learning-based architectures, such as neural PDE solvers, have recently gained traction as a reliable solution method. The current state of development of these approaches, however, primarily focuses on improving accuracy. The environmental impact of excessive computation, leading to increased carbon emissions, has largely been overlooked. This paper introduces a carbon emission measure for a range of PDE solvers. Our proposed metric, EcoL2, balances model accuracy with emissions across data collection, model training, and deployment. Experiments across both physics-informed machine learning and operator learning architectures demonstrate that the proposed metric presents a holistic assessment of model performance and emission cost. As such solvers grow in scale and deployment, EcoL2 represents a step toward building performant scientific machine learning systems with lower long-term environmental impact.
title Beyond Accuracy: EcoL2 Metric for Sustainable Neural PDE Solvers
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2505.12556