Towards a Zero-One Law for Column Subset Selection

Abstract

There are a number of approximation algorithms for NP-hard versions of low rank approximation, such as finding a rank-k matrix B minimizing the sum of absolute values of differences to a given n-by-n matrix A, rank-k~B\|A-B\|1, or more generally finding a rank-k matrix B which minimizes the sum of p-th powers of absolute values of differences, rank-k~B\|A-B\|pp. Many of these algorithms are linear time columns subset selection algorithms, returning a subset of poly(k n) columns whose cost is no more than a poly(k) factor larger than the cost of the best rank-k matrix. The above error measures are special cases of the following general entrywise low rank approximation problem: given an arbitrary function g:R → R≥ 0, find a rank-k matrix B which minimizes \|A-B\|g = Σi,jg(Ai,j-Bi,j). A natural question is which functions g admit efficient approximation algorithms? Indeed, this is a central question of recent work studying generalized low rank models. In this work we give approximation algorithms for every function g which is approximately monotone and satisfies an approximate triangle inequality, and we show both of these conditions are necessary. Further, our algorithm is efficient if the function g admits an efficient approximate regression algorithm. Our approximation algorithms handle functions which are not even scale-invariant, such as the Huber loss function, which we show have very different structural properties than p-norms, e.g., one can show the lack of scale-invariance causes any column subset selection algorithm to provably require a n factor larger number of columns than p-norms; nevertheless we design the first efficient column subset selection algorithms for such error measures.