Overcomplete Tensor Decomposition via Koszul-Young Flattenings

TL;DR

This paper introduces a new algorithm for tensor decomposition using Koszul-Young flattenings, achieving improved rank bounds and certifying uniqueness, with implications for algebraic complexity and overcomplete tensor analysis.

Contribution

The paper presents a novel tensor decomposition algorithm based on Koszul-Young flattenings, improving over existing methods in overcomplete regimes and providing new theoretical bounds.

Findings

Algorithm succeeds for tensor rank up to approximately n_2 + n_3 with high probability.

Improves over classical and recent tensor decomposition algorithms in overcomplete settings.

Shows limitations of flattening techniques, indicating fundamental hardness in certain tensor decomposition problems.

Abstract

Motivated by connections between algebraic complexity lower bounds and tensor decompositions, we investigate Koszul-Young flattenings, which are the main ingredient in recent lower bounds for matrix multiplication. Based on this tool we give a new algorithm for decomposing an $n_1 \times n_2 \times n_3$ tensor as the sum of a minimal number of rank-1 terms, and certifying uniqueness of this decomposition. For $n_1 \le n_2 \le n_3$ with $n_1 \to \infty$ and $n_3/n_2 = O(1)$, our algorithm is guaranteed to succeed when the tensor rank is bounded by $r \le (1-\epsilon)(n_2 + n_3)$ for an arbitrary $\epsilon > 0$, provided the tensor components are generically chosen. For any fixed $\epsilon$, the runtime is polynomial in $n_3$. When $n_2 = n_3 = n$, our condition on the rank gives a factor-of-2 improvement over the classical simultaneous diagonalization algorithm, which requires $r \le n$, and also improves on the recent algorithm of Koiran (2024) which requires $r \le 4n/3$. It also improves on the PhD thesis of Persu (2018) which solves rank detection for $r \leq 3n/2$. We complement our upper bounds by showing limitations, in particular that no flattening of the style we consider can surpass rank $n_2 + n_3$. Furthermore, for $n \times n \times n$ tensors, we show that an even more general class of degree-$d$ polynomial flattenings cannot surpass rank $Cn$ for a constant $C = C(d)$. This suggests that for tensor decompositions, the case of generic components may be fundamentally harder than that of random components, where efficient decomposition is possible even in highly overcomplete settings.