English

Learning manifold diffusion semigroups from graph transition matrices

Machine Learning 2026-05-26 v1 Machine Learning Statistics Theory Statistics Theory

Abstract

We consider graph diffusion processes constructed from finite i.i.d. samples drawn from an unknown manifold embedded in ambient Euclidean space, where the graph affinity is defined by an ambient Gaussian kernel matrix. We show that the manifold heat semigroup Qt=etΔQ_t = e^{t\Delta} can be approximated directly by iterating the graph transition matrix PP, under only low regularity assumptions on the test function ff, including the case fLf \in L^\infty. We bound PnfQtf\| P^n f - Q_t f \| in \infty-norm, with the operator application to ff properly defined, and we recover the classical graph-Laplacian pointwise rate O(N2/(d+6))O(N^{-2/(d+6)}) up to logarithmic factors, for diffusion times tt up to O(1)O(1) and longer. The rate holds for in-sample error as well as out-of-sample generalization, where the estimator of QtfQ_t f at a new point is defined via kernel convolution. To handle non-uniform sampling densities on the manifold, we introduce a right-normalization of the graph transition matrix; under the assumption that the sampling density pp is C3C^3 and bounded away from zero, the same convergence rates hold. We numerically demonstrate the performance of the proposed estimator on simulated data.

Keywords

Cite

@article{arxiv.2605.25383,
  title  = {Learning manifold diffusion semigroups from graph transition matrices},
  author = {Xiuyuan Cheng and Nan Wu},
  journal= {arXiv preprint arXiv:2605.25383},
  year   = {2026}
}