Complete Dictionary Recovery over the Sphere I: Overview and the Geometric Picture

Abstract

We consider the problem of recovering a complete (i.e., square and invertible) matrix A0, from Y ∈ Rn × p with Y = A0 X0, provided X0 is sufficiently sparse. This recovery problem is central to theoretical understanding of dictionary learning, which seeks a sparse representation for a collection of input signals and finds numerous applications in modern signal processing and machine learning. We give the first efficient algorithm that provably recovers A0 when X0 has O(n) nonzeros per column, under suitable probability model for X0. In contrast, prior results based on efficient algorithms either only guarantee recovery when X0 has O(n) zeros per column, or require multiple rounds of SDP relaxation to work when X0 has O(n1-δ) nonzeros per column (for any constant δ ∈ (0, 1)). Our algorithmic pipeline centers around solving a certain nonconvex optimization problem with a spherical constraint. In this paper, we provide a geometric characterization of the objective landscape. In particular, we show that the problem is highly structured: with high probability, (1) there are no "spurious" local minimizers; and (2) around all saddle points the objective has a negative directional curvature. This distinctive structure makes the problem amenable to efficient optimization algorithms. In a companion paper (arXiv:1511.04777), we design a second-order trust-region algorithm over the sphere that provably converges to a local minimizer from arbitrary initializations, despite the presence of saddle points.