Sketching the Heat Kernel: Using Gaussian Processes to Embed Data
Abstract
This paper introduces a novel, non-deterministic method for embedding data in low-dimensional Euclidean space based on computing realizations of a Gaussian process depending on the geometry of the data. This type of embedding first appeared in (Adler et al, 2018) as a theoretical model for a generic manifold in high dimensions. In particular, we take the covariance function of the Gaussian process to be the heat kernel, and computing the embedding amounts to sketching a matrix representing the heat kernel. The Karhunen-Lo\`eve expansion reveals that the straight-line distances in the embedding approximate the diffusion distance in a probabilistic sense, avoiding the need for sharp cutoffs and maintaining some of the smaller-scale structure. Our method demonstrates further advantage in its robustness to outliers. We justify the approach with both theory and experiments.
Cite
@article{arxiv.2403.07929,
title = {Sketching the Heat Kernel: Using Gaussian Processes to Embed Data},
author = {Anna C. Gilbert and Kevin O'Neill},
journal= {arXiv preprint arXiv:2403.07929},
year = {2024}
}
Comments
28 pages