English

Large Average Subtensor Problem: Ground-State, Algorithms, and Algorithmic Barriers

Statistics Theory 2025-06-23 v1 Computational Complexity Data Structures and Algorithms Probability Statistics Theory

Abstract

We introduce the large average subtensor problem: given an order-pp tensor over RN××N\mathbb{R}^{N\times \cdots \times N} with i.i.d. standard normal entries and a kNk\in\mathbb{N}, algorithmically find a k××kk\times \cdots \times k subtensor with a large average entry. This generalizes the large average submatrix problem, a key model closely related to biclustering and high-dimensional data analysis, to tensors. For the submatrix case, Bhamidi, Dey, and Nobel~\cite{bhamidi2017energy} explicitly highlight the regime k=Θ(N)k=\Theta(N) as an intriguing open question. Addressing the regime k=Θ(N)k=\Theta(N) for tensors, we establish that the largest average entry concentrates around an explicit value EmaxE_{\mathrm{max}}, provided that the tensor order pp is sufficiently large. Furthermore, we prove that for any γ>0\gamma>0 and large pp, this model exhibits multi Overlap Gap Property (mm-OGP) above the threshold γEmax\gamma E_{\mathrm{max}}. The mm-OGP serves as a rigorous barrier for a broad class of algorithms exhibiting input stability. These results hold for both k=Θ(N)k=\Theta(N) and k=o(N)k=o(N). Moreover, for small kk, specifically k=o(log1.5N)k=o(\log^{1.5}N), we show that a certain polynomial-time algorithm identifies a subtensor with average entry 2pp+1Emax\frac{2\sqrt{p}}{p+1}E_{\mathrm{max}}. In particular, the mm-OGP is asymptotically sharp: onset of the mm-OGP and the algorithmic threshold match as pp grows. Our results show that while the case k=Θ(N)k=\Theta(N) remains open for submatrices, it can be rigorously analyzed for tensors in the large pp regime. This is achieved by interpreting the model as a Boolean spin glass and drawing on insights from recent advances in the Ising pp-spin glass model.

Keywords

Cite

@article{arxiv.2506.17118,
  title  = {Large Average Subtensor Problem: Ground-State, Algorithms, and Algorithmic Barriers},
  author = {Abhishek Hegade K. R. and Eren C. Kızıldağ},
  journal= {arXiv preprint arXiv:2506.17118},
  year   = {2025}
}
R2 v1 2026-07-01T03:26:50.240Z