English

Tucker Diffusion Model for High-dimensional Tensor Generation

Methodology 2026-04-02 v1 Machine Learning

Abstract

Statistical inference on large-dimensional tensor data has been extensively studied in the literature and widely used in economics, biology, machine learning, and other fields, but how to generate a structured tensor with a target distribution is still a new problem. As profound AI generators, diffusion models have achieved remarkable success in learning complex distributions. However, their extension to generating multi-linear tensor-valued observations remains underexplored. In this work, we propose a novel Tucker diffusion model for learning high-dimensional tensor distributions. We show that the score function admits a structured decomposition under the low Tucker rank assumption, allowing it to be both accurately approximated and efficiently estimated using a carefully tailored tensor-shaped architecture named Tucker-Unet. Furthermore, the distribution of generated tensors, induced by the estimated score function, converges to the true data distribution at a rate depending on the maximum of tensor mode dimensions, thereby offering a clear theoretical advantage over the naive vectorized approach, which has a product dependence. Empirically, compared to existing approaches, the Tucker diffusion model demonstrates strong practical potential in synthetic and real-world tensor generation tasks, achieving comparable and sometimes even superior statistical performance with significantly reduced training and sampling costs.

Keywords

Cite

@article{arxiv.2604.00481,
  title  = {Tucker Diffusion Model for High-dimensional Tensor Generation},
  author = {Jianhua Guo and Xinbing Kong and Zeyu Li and Junfan Mao},
  journal= {arXiv preprint arXiv:2604.00481},
  year   = {2026}
}
R2 v1 2026-07-01T11:47:37.444Z