In this article, we propose a new error bound for Koopman operator approximation using Kernel Extended Dynamic Mode Decomposition. The new estimate is O(N−1/2), with a constant related to the probability of success of the bound, given by Hoeffding's inequality, similar to other methodologies, such as Philipp et al. Furthermore, we propose a \textit{lifting back} operator to obtain trajectories generated by embedding the initial state and iterating a linear system in a higher dimension. This naturally yields an O(N−1/2) error bound for mean trajectories. Finally, we show numerical results including an example of nonlinear system, exhibiting successful approximation with exponential decay faster than −1/2, as suggested by the theoretical results.
@article{arxiv.2506.09266,
title = {Improved error bounds for Koopman operator and reconstructed trajectories approximations with kernel-based methods},
author = {Diego Olguín and Axel Osses and Héctor Ramírez},
journal= {arXiv preprint arXiv:2506.09266},
year = {2025}
}