Learning Spatio-Temporal Dynamics via Operator-Valued RKHS and Kernel Koopman Methods
By: Mahishanka Withanachchi
Potential Business Impact:
Predicts how things change over time and space.
We introduce a unified framework for learning the spatio-temporal dynamics of vector valued functions by combining operator valued reproducing kernel Hilbert spaces (OV-RKHS) with kernel based Koopman operator methods. The approach enables nonparametric and data driven estimation of complex time evolving vector fields while preserving both spatial and temporal structure. We establish representer theorems for time dependent OV-RKHS interpolation, derive Sobolev type approximation bounds for smooth vector fields, and provide spectral convergence guarantees for kernel Koopman operator approximations. This framework supports efficient reduced order modeling and long term prediction of high dimensional nonlinear systems, offering theoretically grounded tools for forecasting, control, and uncertainty quantification in spatio-temporal machine learning.
Similar Papers
A Kernel-based Stochastic Approximation Framework for Nonlinear Operator Learning
Machine Learning (Stat)
Teaches computers to solve hard math problems.
Kernel-based Stochastic Approximation Framework for Nonlinear Operator Learning
Machine Learning (Stat)
Teaches computers to solve hard math problems.
Learning functions, operators and dynamical systems with kernels
Machine Learning (CS)
Teaches computers to learn from data.