A New Framework for Matrix Discrepancy: Partial Coloring Bounds via Mirror Descent

Abstract

Motivated by the Matrix Spencer conjecture, we study the problem of finding signed sums of matrices with a small matrix norm. A well-known strategy to obtain these signs is to prove, given matrices A1, …, An ∈ Rm × m, a Gaussian measure lower bound of 2-O(n) for a scaling of the discrepancy body \x ∈ Rn: \| Σi=1n xi Ai\| ≤ 1\. We show this is equivalent to covering its polar with 2O(n) translates of the cube 1n Bn∞, and construct such a cover via mirror descent. As applications of our framework, we show: Matrix Spencer for Low-Rank Matrices. If the matrices satisfy \|Ai\|op ≤ 1 and rank(Ai) ≤ r, we can efficiently find a coloring x ∈ \ 1\n with discrepancy \|Σi=1n xi Ai \|op n ((rm/n, r)). This improves upon the naive O(n r) bound for random coloring and proves the matrix Spencer conjecture when r m ≤ n. Matrix Spencer for Block Diagonal Matrices. For block diagonal matrices with \|Ai\|op ≤ 1 and block size h, we can efficiently find a coloring x ∈ \ 1\n with \|Σi=1n xi Ai \|op n (hm/n). Using our proof, we reduce the matrix Spencer conjecture to the existence of a O((m/n)) quantum relative entropy net on the spectraplex. Matrix Discrepancy for Schatten Norms. We generalize our discrepancy bound for matrix Spencer to Schatten norms 2 p ≤ q. Given \|Ai\|Sp ≤ 1 and rank(Ai) ≤ r, we can efficiently find a partial coloring x ∈ [-1,1]n with |\i : |xi| = 1\| n/2 and \|Σi=1n xi Ai\|Sq n (p, (rk)) · k1/p-1/q, where k := (1,m/n).