Renormalization Group Guided Tensor Network Structure Search

Authors

  • Maolin Wang City University of Hong Kong
  • Bowen Yu City University of Hong Kong
  • Sheng Zhang City University of Hong Kong
  • Linjie Mi City University of Hong Kong
  • Wanyu Wang City University of Hong Kong
  • Yiqi Wang National University of Defense Technology
  • Pengyue Jia City University of Hong Kong
  • Xuetao Wei Southern University of Science and Technology
  • Zenglin Xu Fudan University
  • Ruocheng Guo Intuit AI
  • Xiangyu Zhao City University of Hong Kong

DOI:

https://doi.org/10.1609/aaai.v40i31.39840

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 times faster than existing methods, validating the effectiveness of our physics-inspired approach.
AAAI-26 / IAAI-26 / EAAI-26 Proceedings Cover

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Published

2026-03-14

How to Cite

Wang, M., Yu, B., Zhang, S., Mi, L., Wang, W., Wang, Y., … Zhao, X. (2026). Renormalization Group Guided Tensor Network Structure Search. Proceedings of the AAAI Conference on Artificial Intelligence, 40(31), 26346–26354. https://doi.org/10.1609/aaai.v40i31.39840

Issue

Vol. 40 No. 31: AAAI-26 Technical Tracks 31

Section

AAAI Technical Track on Machine Learning VIII