Improving Convergence Guarantees of Random Subspace Second-order Algorithm for Nonconvex Optimization

Abstract

In recent years, random subspace methods have been actively studied for large-dimensional nonconvex problems. Recent subspace methods have improved theoretical guarantees such as iteration complexity and local convergence rate while reducing computational costs by deriving descent directions in randomly selected low-dimensional subspaces. This paper proposes the Random Subspace Homogenized Trust Region (RSHTR) method with the best theoretical guarantees among random subspace algorithms for nonconvex optimization. RSHTR achieves an -approximate first-order stationary point in O(-3/2) iterations, converging locally at a linear rate. Furthermore, under rank-deficient conditions, RSHTR satisfies -approximate second-order necessary conditions in O(-3/2) iterations and exhibits a local quadratic convergence. Experiments on real-world datasets verify the benefits of RSHTR.