Two Newton methods on the manifold of fixed-rank matrices endowed with Riemannian quotient geometries

Abstract

We consider two Riemannian geometries for the manifold M(p,m× n) of all m× n matrices of rank p. The geometries are induced on M(p,m× n) by viewing it as the base manifold of the submersion π:(M,N) MNT, selecting an adequate Riemannian metric on the total space, and turning π into a Riemannian submersion. The theory of Riemannian submersions, an important tool in Riemannian geometry, makes it possible to obtain expressions for fundamental geometric objects on M(p,m× n) and to formulate the Riemannian Newton methods on M(p,m× n) induced by these two geometries. The Riemannian Newton methods admit a stronger and more streamlined convergence analysis than the Euclidean counterpart, and the computational overhead due to the Riemannian geometric machinery is shown to be mild. Potential applications include low-rank matrix completion and other low-rank matrix approximation problems.