Exact simultaneous recovery of locations and structure from known orientations and corrupted point correspondences

Abstract

Let t1,…,tnl ∈ Rd and p1,…,pns ∈ Rd and consider the bipartite location recovery problem: given a subset of pairwise direction observations \(ti - pj) / \|ti - pj\|2\i,j ∈ [nl] × [ns], where a constant fraction of these observations are arbitrarily corrupted, find \ti\i ∈ [nll] and \pj\j ∈ [ns] up to a global translation and scale. We study the recently introduced ShapeFit algorithm as a method for solving this bipartite location recovery problem. In this case, ShapeFit consists of a simple convex program over d(nl + ns) real variables. We prove that this program recovers a set of nl+ns i.i.d. Gaussian locations exactly and with high probability if the observations are given by a bipartite Erdos-R\'enyi graph, d is large enough, and provided that at most a constant fraction of observations involving any particular location are adversarially corrupted. This recovery theorem is based on a set of deterministic conditions that we prove are sufficient for exact recovery. Finally, we propose a modified pipeline for the Structure for Motion problem, based on this bipartite location recovery problem.