Renormalization Group Guided Tensor Network Structure Search
Abstract
Tensor network structure search (TN-SS) aims to automatically discover optimal network topologies and rank configurations for efficient tensor decomposition in high-dimensional data representation. Despite recent advances, existing TN-SS methods face significant limitations in computational tractability, structure adaptivity, and optimization robustness across diverse tensor characteristics. They struggle with three key challenges: single-scale optimization missing multi-scale structures, discrete search spaces hindering smooth structure evolution, and separated structure-parameter optimization causing computational inefficiency. We propose RGTN (Renormalization Group guided Tensor Network search), a physics-inspired framework transforming TN-SS via multi-scale renormalization group flows. Unlike fixed-scale discrete search methods, RGTN uses dynamic scale-transformation for continuous structure evolution across resolutions. Its core innovation includes learnable edge gates for optimization-stage topology modification and intelligent proposals based on physical quantities like node tension measuring local stress and edge information flow quantifying connectivity importance. Starting from low-complexity coarse scales and refining to finer ones, RGTN finds compact structures while escaping local minima via scale-induced perturbations. Extensive experiments on light field data, high-order synthetic tensors, and video completion tasks show RGTN achieves state-of-the-art compression ratios and runs 4-600 faster than existing methods, validating the effectiveness of our physics-inspired approach.
Cite
@article{arxiv.2512.24663,
title = {Renormalization Group Guided Tensor Network Structure Search},
author = {Maolin Wang and Bowen Yu and Sheng Zhang and Linjie Mi and Wanyu Wang and Yiqi Wang and Pengyue Jia and Xuetao Wei and Zenglin Xu and Ruocheng Guo and Xiangyu Zhao},
journal= {arXiv preprint arXiv:2512.24663},
year = {2026}
}
Comments
Accepted to AAAI 2026