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Efficient Generative Modeling with Unitary Matrix Product States Using Riemannian Optimization

Machine Learning 2026-03-13 v1

Abstract

Tensor networks, which are originally developed for characterizing complex quantum many-body systems, have recently emerged as a powerful framework for capturing high-dimensional probability distributions with strong physical interpretability. This paper systematically studies matrix product states (MPS) for generative modeling and shows that unitary MPS, which is a tensor-network architecture that is both simple and expressive, offers clear benefits for unsupervised learning by reducing ambiguity in parameter updates and improving efficiency. To overcome the inefficiency of standard gradient-based MPS training, we develop a Riemannian optimization approach that casts probabilistic modeling as an optimization problem with manifold constraints, and further derive an efficient space-decoupling algorithm. Experiments on Bars-and-Stripes and EMNIST datasets demonstrate fast adaptation to data structure, stable updates, and strong performance while maintaining the efficiency and expressive power of MPS.

Keywords

Cite

@article{arxiv.2603.12026,
  title  = {Efficient Generative Modeling with Unitary Matrix Product States Using Riemannian Optimization},
  author = {Haotong Duan and Zhongming Chen and Ngai Wong},
  journal= {arXiv preprint arXiv:2603.12026},
  year   = {2026}
}
R2 v1 2026-07-01T11:16:54.966Z