English

Natural Riemannian gradient for learning functional tensor networks

Optimization and Control 2026-04-13 v1 Machine Learning Numerical Analysis Numerical Analysis

Abstract

We consider machine learning tasks with low-rank functional tree tensor networks (TTN) as the learning model. While in the case of least-squares regression, low-rank functional TTNs can be efficiently optimized using alternating optimization, this is not directly possible in other problems, such as multinomial logistic regression. We propose a natural Riemannian gradient descent type approach applicable to arbitrary losses which is based on the natural gradient by Amari. In particular, the search direction obtained by the natural gradient is independent of the choice of basis of the underlying functional tensor product space. Our framework applies to both the factorized and manifold-based approach for representing the functional TTN. For practical application, we propose a hierarchy of efficient approximations to the true natural Riemannian gradient for computing the updates in the parameter space. Numerical experiments confirm our theoretical findings on common classification datasets and show that using natural Riemannian gradient descent for learning considerably improves convergence behavior when compared to standard Riemannian gradient methods.

Keywords

Cite

@article{arxiv.2604.09263,
  title  = {Natural Riemannian gradient for learning functional tensor networks},
  author = {Nikolas Klug and Michael Ulbrich and André Uschmajew and Marius Willner},
  journal= {arXiv preprint arXiv:2604.09263},
  year   = {2026}
}
R2 v1 2026-07-01T12:02:50.224Z