Universal Matrix Sparsifiers and Fast Deterministic Algorithms for Linear Algebra

Abstract

Let S ∈ Rn × n satisfy \| 1- S\|2ε n, where 1 is the all ones matrix and \|·\|2 is the spectral norm. It is well-known that there exists such an S with just O(n/ε2) non-zero entries: we can let S be the scaled adjacency matrix of a Ramanujan expander graph. We show that such an S yields a universal sparsifier for any positive semidefinite (PSD) matrix. In particular, for any PSD A ∈ Rn× n with entries bounded in magnitude by 1, \| A - A S\|2 ε n, where denotes the entrywise (Hadamard) product. Our techniques also give universal sparsifiers for non-PSD matrices. In this case, letting S be the scaled adjacency matrix of a Ramanujan graph with O(n/ε4) edges, we have \| A - A S \|2 ε · (n,\| A\|1), where \| A\|1 is the nuclear norm. We show that the above bounds for both PSD and non-PSD matrices are tight up to log factors. Since A S can be constructed deterministically, our result for PSD matrices derandomizes and improves upon known results for randomized matrix sparsification, which require randomly sampling O(n nε2) entries. We also leverage our results to give the first deterministic algorithms for several problems related to singular value approximation that run in faster than matrix multiplication time. Finally, if A ∈ \-1,0,1\n × n is PSD, we show that A with \| A - A\|2 ε n can be obtained by deterministically reading O(n/ε) entries of A. This improves the 1/ε dependence on our result for general PSD matrices and is near-optimal.