Robust Lasso With Missing and Grossly Corrupted Observations

This paper studies the problem of accurately recovering a k -sparse vector β^* ∈ BBRp from highly corrupted linear measurements y=Xβ^*+e^*+w , where e^* ∈ BBRn is a sparse error vector whose nonzero entries may be unbounded and w is a stochastic noise term. We propose a so-called extended Lasso optimization which takes into consideration sparse prior information of both β^* and e^*. Our first result shows that the extended Lasso can faithfully recover both the regression as well as the corruption vector. Our analysis relies on the notion of extended restricted eigenvalue for the design matrix X. Our second set of results applies to a general class of Gaussian design matrix X with i.i.d. rows N(0,Σ), for which we can establish a surprising result: the extended Lasso can recover exact signed supports of both β^* and e^* from only Ω(klogplogn) observations, even when a linear fraction of observations is grossly corrupted. Our analysis also shows that this amount of observations required to achieve exact signed support is indeed optimal.