Your search keyword '"Andrea Montanari"' showing total 10 results

1. Information-Theoretically Optimal Compressed Sensing via Spatial Coupling and Approximate Message Passing

Author

David L. Donoho, Andrea Montanari, and Adel Javanmard

Subjects

FOS: Computer and information sciences, Theoretical computer science, Computer Science - Information Theory, FOS: Physical sciences, Mathematics - Statistics Theory, Statistics Theory (math.ST), 02 engineering and technology, Library and Information Sciences, 01 natural sciences, Dimension (vector space), Diagonal matrix, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, 0101 mathematics, Condensed Matter - Statistical Mechanics, Mathematics, Discrete mathematics, Sequence, Statistical Mechanics (cond-mat.stat-mech), Signal reconstruction, Information Theory (cs.IT), 010102 general mathematics, Mathematical analysis, 020206 networking & telecommunications, Coupling (probability), Empirical distribution function, Computer Science Applications, Compressed sensing, Undersampling, Probability distribution, Algorithm, Information Systems

Abstract

We study the compressed sensing reconstruction problem for a broad class of random, band-diagonal sensing matrices. This construction is inspired by the idea of spatial coupling in coding theory. As demonstrated heuristically and numerically by Krzakala et al. \cite{KrzakalaEtAl}, message passing algorithms can effectively solve the reconstruction problem for spatially coupled measurements with undersampling rates close to the fraction of non-zero coordinates. We use an approximate message passing (AMP) algorithm and analyze it through the state evolution method. We give a rigorous proof that this approach is successful as soon as the undersampling rate $\delta$ exceeds the (upper) R\'enyi information dimension of the signal, $\uRenyi(p_X)$. More precisely, for a sequence of signals of diverging dimension $n$ whose empirical distribution converges to $p_X$, reconstruction is with high probability successful from $\uRenyi(p_X)\, n+o(n)$ measurements taken according to a band diagonal matrix. For sparse signals, i.e., sequences of dimension $n$ and $k(n)$ non-zero entries, this implies reconstruction from $k(n)+o(n)$ measurements. For `discrete' signals, i.e., signals whose coordinates take a fixed finite set of values, this implies reconstruction from $o(n)$ measurements. The result is robust with respect to noise, does not apply uniquely to random signals, but requires the knowledge of the empirical distribution of the signal $p_X$., Comment: 60 pages, 7 figures, Sections 3,5 and Appendices A,B are added. The stability constant is quantified (cf Theorem 1.7)

Published

2013

2. Optimal Coding for the Binary Deletion Channel With Small Deletion Probability

Author

Yashodhan Kanoria and Andrea Montanari

Subjects

Discrete mathematics, Binary number, Library and Information Sciences, Binary erasure channel, Binary symmetric channel, Computer Science Applications, Bernoulli's principle, Channel capacity, Deletion channel, Series expansion, Algorithm, Computer Science::Information Theory, Information Systems, Mathematics, Communication channel

Abstract

The binary deletion channel is the simplest point-to-point communication channel that models lack of synchronization. Input bits are deleted independently with probability d, and when they are not deleted, they are not affected by the channel. Despite significant effort, little is known about the capacity of this channel and even less about optimal coding schemes. In this paper, we develop a new systematic approach to this problem, by demonstrating that capacity can be computed in a series expansion for small deletion probability. We compute three leading terms of this expansion, and find an input distribution that achieves capacity up to this order. This constitutes the first optimal random coding result for the deletion channel. The key idea employed is the following: We understand perfectly the deletion channel with deletion probability d=0. It has capacity 1 and the optimal input distribution is iid Bernoulli (1/2). It is natural to expect that the channel with small deletion probabilities has a capacity that varies smoothly with d, and that the optimal input distribution is obtained by smoothly perturbing the iid Bernoulli (1/2) process. Our results show that this is indeed the case.

Published

2013

3. Accurate Prediction of Phase Transitions in Compressed Sensing via a Connection to Minimax Denoising

Author

Iain M. Johnstone, David L. Donoho, and Andrea Montanari

Subjects

Mathematical optimization, Mean squared error, Signal reconstruction, Gaussian, 020206 networking & telecommunications, 02 engineering and technology, Library and Information Sciences, Minimax, 01 natural sciences, Thresholding, Computer Science Applications, 010104 statistics & probability, symbols.namesake, Compressed sensing, Undersampling, 0202 electrical engineering, electronic engineering, information engineering, symbols, Applied mathematics, 0101 mathematics, Gaussian process, Information Systems, Mathematics

Abstract

Compressed sensing posits that, within limits, one can undersample a sparse signal and yet reconstruct it accurately. Knowing the precise limits to such undersampling is important both for theory and practice. We present a formula that characterizes the allowed undersampling of generalized sparse objects. The formula applies to approximate message passing (AMP) algorithms for compressed sensing, which are here generalized to employ denoising operators besides the traditional scalar soft thresholding denoiser. This paper gives several examples including scalar denoisers not derived from convex penalization-the firm shrinkage nonlinearity and the minimax nonlinearity-and also nonscalar denoisers-block thresholding, monotone regression, and total variation minimization. Let the variables e = k/N and δ = n/N denote the generalized sparsity and undersampling fractions for sampling the k-generalized-sparse N-vector x0 according to y=Ax0. Here, A is an n×N measurement matrix whose entries are iid standard Gaussian. The formula states that the phase transition curve δ = δ(e) separating successful from unsuccessful reconstruction of x0 by AMP is given by δ = M(e|Denoiser) where M(e|Denoiser) denotes the per-coordinate minimax mean squared error (MSE) of the specified, optimally tuned denoiser in the directly observed problem y = x + z. In short, the phase transition of a noiseless undersampling problem is identical to the minimax MSE in a denoising problem. We prove that this formula follows from state evolution and present numerical results validating it in a wide range of settings. The above formula generates numerous new insights, both in the scalar and in the nonscalar cases.

Published

2013

4. Iterative Coding for Network Coding

Author

R. Urbanke and Andrea Montanari

Subjects

probabilistic channel models, Theoretical computer science, Shannon channel capacity, Iterative method, Code word, Data_CODINGANDINFORMATIONTHEORY, Library and Information Sciences, Computer Science Applications, Channel capacity, Network coding, Linear network coding, Header, sparse graph codes, Communication complexity, Decoding methods, Computer Science::Information Theory, Information Systems, Coding (social sciences), Mathematics

Abstract

We consider communication over a noisy network under randomized linear network coding. Possible error mechanisms include node- or link-failures, Byzantine behavior of nodes, or an overestimate of the network min-cut. Building on the work of Kotter and Kschischang, we introduce a systematic oblivious random channel model. Within this model, codewords contain a header (this is the systematic part). The header effectively records the coefficients of the linear encoding functions, thus simplifying the decoding task. Under this constraint, errors are modeled as random low-rank perturbations of the transmitted codeword. We compute the capacity of this channel and we define an error-correction scheme based on random sparse graphs and a low-complexity decoding algorithm. By optimizing over the code degree profile, we show that this construction achieves the channel capacity in complexity which is jointly quadratic in the number of coded information bits and sublogarithmic in the error probability.

Published

2013

5. The LASSO Risk for Gaussian Matrices

Author

Mohsen Bayati and Andrea Montanari

Subjects

FOS: Computer and information sciences, Mathematical optimization, Mean squared error, Computer Science - Information Theory, Gaussian, Mathematics - Statistics Theory, Statistics Theory (math.ST), 02 engineering and technology, Library and Information Sciences, 01 natural sciences, 010104 statistics & probability, symbols.namesake, Lasso (statistics), FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Applied mathematics, Limit (mathematics), 0101 mathematics, Gaussian process, Mathematics, Information Theory (cs.IT), Estimator, 020206 networking & telecommunications, 16. Peace & justice, Computer Science Applications, Basis pursuit denoising, symbols, Random matrix, Information Systems

Abstract

We consider the problem of learning a coefficient vector x_0\in R^N from noisy linear observation y=Ax_0+w \in R^n. In many contexts (ranging from model selection to image processing) it is desirable to construct a sparse estimator x'. In this case, a popular approach consists in solving an L1-penalized least squares problem known as the LASSO or Basis Pursuit DeNoising (BPDN). 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 models ideas. Simulations on real data matrices suggest that our results can be relevant in a broad array of practical applications., 43 pages, 5 figures (v3 rectifies some inconsistencies in the formulation of auxiliary lemmas)

Published

2012

6. Applications of the Lindeberg Principle in Communications and Statistical Learning

Author

Andrea Montanari and Satish Babu Korada

Subjects

Theoretical computer science, Covariance matrix, MIMO, Symmetric matrix, Library and Information Sciences, Information theory, Random matrix, Random variable, Computer Science Applications, Information Systems, Universality (dynamical systems), Mathematics, Sparse matrix

Abstract

We use a generalization of the Lindeberg principle developed by S. Chatterjee to prove universality properties for various problems in communications, statistical learning and random matrix theory. We also show that these systems can be viewed as the limiting case of a properly defined sparse system. The latter result is useful when the sparse systems are easier to analyze than their dense counterparts. The list of problems we consider is by no means exhaustive. We believe that the ideas can be used in many other problems relevant for information theory.

Published

2011

7. The Dynamics of Message Passing on Dense Graphs, with Applications to Compressed Sensing

Author

Andrea Montanari and Mohsen Bayati

Subjects

FOS: Computer and information sciences, Independent and identically distributed random variables, Theoretical computer science, Iterative method, Computer science, Computer Science - Information Theory, Gaussian, Mathematics - Statistics Theory, Context (language use), Statistics Theory (math.ST), 02 engineering and technology, Library and Information Sciences, 01 natural sciences, Machine Learning (cs.LG), 010104 statistics & probability, symbols.namesake, Matrix (mathematics), FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, 0101 mathematics, Gaussian process, Information Theory (cs.IT), 010102 general mathematics, Message passing, Approximation algorithm, 020206 networking & telecommunications, Graph theory, Graph, Computer Science Applications, Computer Science - Learning, Compressed sensing, symbols, Algorithm design, Random matrix, Algorithm, Factor graph, Information Systems

Abstract

Approximate message passing algorithms proved to be extremely effective in reconstructing sparse signals from a small number of incoherent linear measurements. Extensive numerical experiments further showed that their dynamics is accurately tracked by a simple one-dimensional iteration termed state evolution. In this paper we provide the first rigorous foundation to state evolution. We prove that indeed it holds asymptotically in the large system limit for sensing matrices with independent and identically distributed gaussian entries. While our focus is on message passing algorithms for compressed sensing, the analysis extends beyond this setting, to a general class of algorithms on dense graphs. In this context, state evolution plays the role that density evolution has for sparse graphs. The proof technique is fundamentally different from the standard approach to density evolution, in that it copes with large number of short loops in the underlying factor graph. It relies instead on a conditioning technique recently developed by Erwin Bolthausen in the context of spin glass theory., Comment: 41 pages

Published

2011

8. Matrix Completion From a Few Entries

Author

Raghunandan H. Keshavan, Andrea Montanari, and Sewoong Oh

Subjects

FOS: Computer and information sciences, Machine Learning (stat.ML), 010103 numerical & computational mathematics, 02 engineering and technology, Library and Information Sciences, 01 natural sciences, Machine Learning (cs.LG), Matrix decomposition, Combinatorics, Matrix (mathematics), Statistics - Machine Learning, 0202 electrical engineering, electronic engineering, information engineering, Rank (graph theory), 0101 mathematics, Time complexity, Mathematics, Sparse matrix, Matrix completion, Spectrum (functional analysis), 020206 networking & telecommunications, Computer Science Applications, Computer Science - Learning, Bounded function, 020201 artificial intelligence & image processing, Random matrix, Information Systems

Abstract

Let M be a random (alpha n) x n matrix of rank r<, Comment: 30 pages, 1 figure, journal version (v1, v2: Conference version ISIT 2009)

Published

2010

9. The Generalized Area Theorem and Some of its Consequences

Author

Andrea Montanari, Thomas Richardson, Rudiger Urbanke, Cyril Measson, Laboratoire de Physique Théorique de l'ENS [École Normale Supérieure] (LPTENS), Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), Department of Electrical Engineering and Statistics, Stanford University, Laboratoire de Physique Théorique de l'ENS (LPTENS), Université Pierre et Marie Curie - Paris 6 (UPMC)-Fédération de recherche du Département de physique de l'Ecole Normale Supérieure - ENS Paris (FRDPENS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

FOS: Computer and information sciences, maximum a posteriori, Computer Science - Information Theory, Area theorem, Data_CODINGANDINFORMATIONTHEORY, 0102 computer and information sciences, 02 engineering and technology, Library and Information Sciences, Information theory, Belief propagation, 01 natural sciences, Upper and lower bounds, Bounds, Information, threshold, 0202 electrical engineering, electronic engineering, information engineering, Maximum a posteriori estimation, Low-density parity-check code, Parity-Check Codes, Computer Science::Information Theory, Mathematics, Maxwell construction, Ldpc, Capacity, Information Theory (cs.IT), EXIT curve, 020206 networking & telecommunications, Binary erasure channel, Computer Science Applications, [INFO.INFO-IT]Computer Science [cs]/Information Theory [cs.IT], belief propagation (BP), phase transition, 010201 computation theory & mathematics, maximum-likelihood, entropy, Convergence, Algorithm, Decoding methods, Information Systems

Abstract

There is a fundamental relationship between belief propagation and maximum a posteriori decoding. The case of transmission over the binary erasure channel was investigated in detail in a companion paper. This paper investigates the extension to general memoryless channels (paying special attention to the binary case). An area theorem for transmission over general memoryless channels is introduced and some of its many consequences are discussed. We show that this area theorem gives rise to an upper-bound on the maximum a posteriori threshold for sparse graph codes. In situations where this bound is tight, the extrinsic soft bit estimates delivered by the belief propagation decoder coincide with the correct a posteriori probabilities above the maximum a posteriori threshold. More generally, it is conjectured that the fundamental relationship between the maximum a posteriori and the belief propagation decoder which was observed for transmission over the binary erasure channel carries over to the general case. We finally demonstrate that in order for the design rate of an ensemble to approach the capacity under belief propagation decoding the component codes have to be perfectly matched, a statement which is well known for the special case of transmission over the binary erasure channel., 27 pages, 46 ps figures

Published

2009

10. Maxwell Construction: The Hidden Bridge Between Iterative and Maximuma PosterioriDecoding

Author

Cyril Measson, Rudiger Urbanke, and Andrea Montanari

Subjects

Iterative method, Maxwell construction, Binary number, Data_CODINGANDINFORMATIONTHEORY, Library and Information Sciences, Belief propagation, Binary erasure channel, Computer Science Applications, Soft-decision decoder, Entropy (information theory), Algorithm, Decoding methods, Computer Science::Information Theory, Information Systems, Mathematics

Abstract

There is a fundamental relationship between belief propagation and maximum a posteriori decoding. A decoding algorithm, which is called the Maxwell decoder, is introduced and provides a constructive description of this relationship. Both the algorithm itself and the analysis of the new decoder are reminiscent of the Maxwell construction in thermodynamics. This paper investigates in detail the case of transmission over the binary erasure channel, while the extension to general binary memoryless channels is discussed in a companion paper.

Published

2008