How Over-Parameterization Slows Down Gradient Descent in Matrix Sensing: The Curses of Symmetry and Initialization
Abstract
This paper rigorously shows how over-parameterization changes the convergence behaviors of gradient descent (GD) for the matrix sensing problem, where the goal is to recover an unknown low-rank ground-truth matrix from near-isotropic linear measurements. First, we consider the symmetric setting with the symmetric parameterization where M* ∈ Rn × n is a positive semi-definite unknown matrix of rank r n, and one uses a symmetric parameterization XX to learn M*. Here X ∈ Rn × k with k > r is the factor matrix. We give a novel (1/T2) lower bound of randomly initialized GD for the over-parameterized case (k >r) where T is the number of iterations. This is in stark contrast to the exact-parameterization scenario (k=r) where the convergence rate is (- (T)). Next, we study asymmetric setting where M* ∈ Rn1 × n2 is the unknown matrix of rank r \n1,n2\, and one uses an asymmetric parameterization FG to learn M* where F ∈ Rn1 × k and G ∈ Rn2 × k. Building on prior work, we give a global exact convergence result of randomly initialized GD for the exact-parameterization case (k=r) with an (-(T)) rate. Furthermore, we give the first global exact convergence result for the over-parameterization case (k>r) with an (-(α2 T)) rate where α is the initialization scale. This linear convergence result in the over-parameterization case is especially significant because one can apply the asymmetric parameterization to the symmetric setting to speed up from (1/T2) to linear convergence. On the other hand, we propose a novel method that only modifies one step of GD and obtains a convergence rate independent of α, recovering the rate in the exact-parameterization case.
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