Sharp thresholds for high-dimensional and noisy recovery of sparsity
Abstract
The problem of consistently estimating the sparsity pattern of a vector βstar ∈ based on observations contaminated by noise arises in various contexts, including subset selection in regression, structure estimation in graphical models, sparse approximation, and signal denoising. We analyze the behavior of 1-constrained quadratic programming (QP), also referred to as the Lasso, for recovering the sparsity pattern. Our main result is to establish a sharp relation between the problem dimension , the number of non-zero elements in βstar, and the number of observations that are required for reliable recovery. For a broad class of Gaussian ensembles satisfying mutual incoherence conditions, we establish existence and compute explicit values of thresholds and with the following properties: for any ε > 0, if > 2 ( + ε) ( - ) + + 1, then the Lasso succeeds in recovering the sparsity pattern with probability converging to one for large problems, whereas for < 2 ( - ε) ( - ) + + 1, then the probability of successful recovery converges to zero. For the special case of the uniform Gaussian ensemble, we show that = = 1, so that the threshold is sharp and exactly determined.
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