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

Abstract

We introduce the large average subtensor problem: given an order-p tensor over RN× ·s × N with i.i.d. standard normal entries and a k∈N, algorithmically find a k× ·s × 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~bhamidi2017energy explicitly highlight the regime k=(N) as an intriguing open question. Addressing the regime k=(N) for tensors, we establish that the largest average entry concentrates around an explicit value Emax, provided that the tensor order p is sufficiently large. Furthermore, we prove that for any γ>0 and large p, this model exhibits multi Overlap Gap Property (m-OGP) above the threshold γ Emax. The m-OGP serves as a rigorous barrier for a broad class of algorithms exhibiting input stability. These results hold for both k=(N) and k=o(N). Moreover, for small k, specifically k=o(1.5N), we show that a certain polynomial-time algorithm identifies a subtensor with average entry 2pp+1Emax. In particular, the m-OGP is asymptotically sharp: onset of the m-OGP and the algorithmic threshold match as p grows. Our results show that while the case k=(N) remains open for submatrices, it can be rigorously analyzed for tensors in the large p regime. This is achieved by interpreting the model as a Boolean spin glass and drawing on insights from recent advances in the Ising p-spin glass model.