On the computational and statistical complexity of over-parameterized matrix sensing

Abstract

We consider solving the low rank matrix sensing problem with Factorized Gradient Descend (FGD) method when the true rank is unknown and over-specified, which we refer to as over-parameterized matrix sensing. If the ground truth signal X* ∈ Rd*d is of rank r, but we try to recover it using F F where F ∈ Rd*k and k>r, the existing statistical analysis falls short, due to a flat local curvature of the loss function around the global maxima. By decomposing the factorized matrix F into separate column spaces to capture the effect of extra ranks, we show that \|Ft Ft - X*\|F2 converges to a statistical error of O (k d σ2/n) after O(σrσnd) number of iterations where Ft is the output of FGD after t iterations, σ2 is the variance of the observation noise, σr is the r-th largest eigenvalue of X*, and n is the number of sample. Our results, therefore, offer a comprehensive picture of the statistical and computational complexity of FGD for the over-parameterized matrix sensing problem.

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