Asymptotically Exact Error Analysis for the Generalized 22-LASSO

Abstract

Given an unknown signal x0∈Rn and linear noisy measurements y=Ax0+σv∈Rm, the generalized 22-LASSO solves x:=x12\|y-Ax\|22 + σλ f(x). Here, f is a convex regularization function (e.g. 1-norm, nuclear-norm) aiming to promote the structure of x0 (e.g. sparse, low-rank), and, λ≥ 0 is the regularizer parameter. A related optimization problem, though not as popular or well-known, is often referred to as the generalized 2-LASSO and takes the form x:=x\|y-Ax\|2 + λ f(x), and has been analyzed in [1]. [1] further made conjectures about the performance of the generalized 22-LASSO. This paper establishes these conjectures rigorously. We measure performance with the normalized squared error NSE(σ):=\|x-x0\|22/σ2. Assuming the entries of A and v be i.i.d. standard normal, we precisely characterize the "asymptotic NSE" aNSE:=σ→ 0NSE(σ) when the problem dimensions m,n tend to infinity in a proportional manner. The role of λ,f and x0 is explicitly captured in the derived expression via means of a single geometric quantity, the Gaussian distance to the subdifferential. We conjecture that aNSE = σ>0NSE(σ). We include detailed discussions on the interpretation of our result, make connections to relevant literature and perform computational experiments that validate our theoretical findings.