Title :
The LASSO Risk for Gaussian Matrices
Author :
Bayati, Mohsen ; Montanari, Andrea
Author_Institution :
Grad. Sch. of Bus., Stanford Univ., Stanford, CA, USA
fDate :
4/1/2012 12:00:00 AM
Abstract :
We consider the problem of learning a coefficient vector xο ∈ RN from noisy linear observation y = Axo + ∈ Rn. In many contexts (ranging from model selection to image processing), it is desirable to construct a sparse estimator x̂. In this case, a popular approach consists in solving an ℓ1-penalized least-squares problem known as the LASSO or basis pursuit denoising. For sequences of matrices A of increasing dimensions, with independent Gaussian entries, we prove that the normalized risk of the LASSO converges to a limit, and we obtain an explicit expression for this limit. Our result is the first rigorous derivation of an explicit formula for the asymptotic mean square error of the LASSO for random instances. The proof technique is based on the analysis of AMP, a recently developed efficient algorithm, that is inspired from graphical model ideas. Simulations on real data matrices suggest that our results can be relevant in a broad array of practical applications.
Keywords :
Gaussian processes; least mean squares methods; matrix algebra; signal denoising; signal reconstruction; vectors; AMP analysis; Gaussian matrix sequence; LASSO risk; asymptotic mean square error explicit formula; basis pursuit denoising; coefficient vector learning; compressed sensing; image processing; least-square problem; noisy linear observation; sparse estimator construction; Algorithm design and analysis; Calibration; Equations; Mean square error methods; Noise; Noise measurement; Vectors; Compressed sensing; graphical models; message passing algorithms; random matrix theory; state evolution; statistical learning.;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2011.2174612
