Large Average Subtensor Problem: Ground-State, Algorithms, and Algorithmic Barriers
Abstract
We introduce the large average subtensor problem: given an order- tensor over with i.i.d. standard normal entries and a , algorithmically find a 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 as an intriguing open question. Addressing the regime for tensors, we establish that the largest average entry concentrates around an explicit value , provided that the tensor order is sufficiently large. Furthermore, we prove that for any and large , this model exhibits multi Overlap Gap Property (-OGP) above the threshold . The -OGP serves as a rigorous barrier for a broad class of algorithms exhibiting input stability. These results hold for both and . Moreover, for small , specifically , we show that a certain polynomial-time algorithm identifies a subtensor with average entry . In particular, the -OGP is asymptotically sharp: onset of the -OGP and the algorithmic threshold match as grows. Our results show that while the case remains open for submatrices, it can be rigorously analyzed for tensors in the large regime. This is achieved by interpreting the model as a Boolean spin glass and drawing on insights from recent advances in the Ising -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}
}