Data-Efficient Kernel Methods for Learning Differential Equations and Their Solution Operators: Algorithms and Error Analysis
By: Yasamin Jalalian , Juan Felipe Osorio Ramirez , Alexander Hsu and more
Potential Business Impact:
Teaches computers to solve math problems faster.
We introduce a novel kernel-based framework for learning differential equations and their solution maps that is efficient in data requirements, in terms of solution examples and amount of measurements from each example, and computational cost, in terms of training procedures. Our approach is mathematically interpretable and backed by rigorous theoretical guarantees in the form of quantitative worst-case error bounds for the learned equation. Numerical benchmarks demonstrate significant improvements in computational complexity and robustness while achieving one to two orders of magnitude improvements in terms of accuracy compared to state-of-the-art algorithms.
Similar Papers
A joint optimization approach to identifying sparse dynamics using least squares kernel collocation
Methodology
Finds hidden math rules from messy data.
Learning functions, operators and dynamical systems with kernels
Machine Learning (CS)
Teaches computers to learn from data.
A Kernel-based Stochastic Approximation Framework for Nonlinear Operator Learning
Machine Learning (Stat)
Teaches computers to solve hard math problems.