Elliptic PDE learning is provably data-efficient.

Researchers

Alex Townsend Diana Halikias Nicolas Boullé

Journal

Proceedings of the National Academy of Sciences of the United States of America

Modalities

Models

Abstract

Partial differential equations (PDE) learning is an emerging field that combines physics and machine learning to recover unknown physical systems from experimental data. While deep learning models traditionally require copious amounts of training data, recent PDE learning techniques achieve spectacular results with limited data availability. Still, these results are empirical. Our work provides theoretical guarantees on the number of input-output training pairs required in PDE learning. Specifically, we exploit randomized numerical linear algebra and PDE theory to derive a provably data-efficient algorithm that recovers solution operators of three-dimensional uniformly elliptic PDEs from input-output data and achieves an exponential convergence rate of the error with respect to the size of the training dataset with an exceptionally high probability of success.

Show Full Text

Elliptic PDE learning is provably data-efficient.

Researchers

Journal

Modalities

Models

Abstract

Decoding phenotypic screening: A comparative analysis of image representations.

Optimizing clinico-genomic disease prediction across ancestries: a machine learning strategy with Pareto improvement.

Automatic dementia screening and scoring by applying deep learning on clock-drawing tests.

Application of deep learning and feature selection technique on external root resorption identification on CBCT images.

Breast Tumor Detection Using Robust and Efficient Machine Learning and Convolutional Neural Network Approaches.

Knowledge-based BERT: a method to extract molecular features such as computational chemists.

Leave a Reply Cancel reply

Researchers

Journal

Modalities

Models

Abstract

Similar Posts

Leave a Reply Cancel reply