A PTAS for p-Low Rank Approximation

Abstract

A number of recent works have studied algorithms for entrywise p-low rank approximation, namely, algorithms which given an n × d matrix A (with n ≥ d), output a rank-k matrix B minimizing \|A-B\|pp=Σi,j|Ai,j-Bi,j|p when p > 0; and \|A-B\|0=Σi,j[Ai,j≠ Bi,j] for p=0. On the algorithmic side, for p ∈ (0,2), we give the first (1+ε)-approximation algorithm running in time npoly(k/ε). Further, for p = 0, we give the first almost-linear time approximation scheme for what we call the Generalized Binary 0-Rank-k problem. Our algorithm computes (1+ε)-approximation in time (1/ε)2O(k)/ε2 · nd1+o(1). On the hardness of approximation side, for p ∈ (1,2), assuming the Small Set Expansion Hypothesis and the Exponential Time Hypothesis (ETH), we show that there exists δ := δ(α) > 0 such that the entrywise p-Rank-k problem has no α-approximation algorithm running in time 2kδ.