Information Theory, IEEE Transactions on - new TOC

June 2013

Presents the cover/table of contents for this issue of the periodical.

IEEE Transactions on Information Theory publication information

June 2013

Linear-Algebraic List Decoding for Variants of Reed–Solomon Codes

June 2013

Folded Reed–Solomon (RS) codes are an explicit family of codes that achieve the optimal tradeoff between rate and list error-correction capability: specifically, for any $ {varepsilon }> 0$, Guruswami and Rudra presented an $n^{O(1/ {varepsilon })}$ time algorithm to list decode appropriate folded RS codes of rate $R$ from a fraction $1-R- {varepsilon }$ of errors. The algorithm is based on multivariate polynomial interpolation and root-finding over extension fields. It was noted by Vadhan that interpolating a linear polynomial suffices for a statement of the above form. Here, we give a simple linear-algebra-based analysis of this variant that eliminates the need for the computationally expensive root-finding step over extension fields (and indeed any mention of extension fields). The entire list-decoding algorithm is linear-algebraic, solving one linear system for the interpolation step, and another linear system to find a small subspace of candidate solutions. Except for the step of pruning this subspace, the algorithm can be implemented to run in quadratic time. We also consider a closely related family of codes, called (order $m$) derivative codes and defined over fields of large characteristic, which consist of the evaluations of $f$ as well as its first $m-1$ formal derivatives at $N$ distinct field elements. We show how our linear-algebraic methods for folded RS codes can be used to show that derivative codes can also achiev- the above optimal tradeoff. The theoretical drawback of our analysis for folded RS codes and derivative codes is that both the decoding complexity and proven worst-case list-size bound are $n^{Omega (1/ {varepsilon })}$ . By combining the above idea with a pseudorandom subset of all polynomials as messages, we get a Monte Carlo construction achieving a list-size bound of $O(1/ {varepsilon }^{2})$ which is quite close to the existential $O(1/ {varepsilon })$ bound (however, the decoding complexity remains $n^{Omega (1/ {varepsilon })}$ ). Our work highlights that constructing an explicit subspace-evasive subset that has small intersection with low-dimensional subspaces—an interesting problem in pseudorandomness in its own right—could lead to explicit codes with better list-decoding guarantees.

On Rational Interpolation-Based List-Decoding and List-Decoding Binary Goppa Codes

June 2013

We derive the Wu list-decoding algorithm for generalized Reed–Solomon (GRS) codes by using Gröbner bases over modules and the Euclidean algorithm as the initial algorithm instead of the Berlekamp–Massey algorithm. We present a novel method for constructing the interpolation polynomial fast. We give a new application of the Wu list decoder by decoding irreducible binary Goppa codes up to the binary Johnson radius. Finally, we point out a connection between the governing equations of the Wu algorithm and the Guruswami–Sudan algorithm, immediately leading to equality in the decoding range and a duality in the choice of parameters needed for decoding, both in the case of GRS codes and in the case of Goppa codes.

Localized Error Correction in Projective Space

June 2013

In this paper, we extend the localized error correction code introduced by L. A. Bassalygo and coworkers from Hamming space to projective space. For constant dimensional localized error correction codes in projective space, we have a lower bound and an upper bound of the capacity, which are asymptotically tight when $z< xleq {{ n-z}over { 2}}$, where $x$ , $z$, and $n$ are dimensions of codewords, error configurations, and the ground space, respectively. We determine the capacity of nonconstant dimensional localized error correction codes when $z < {{ n}over { 3}}$.

A Classification of Unimodular Lattice Wiretap Codes in Small Dimensions

June 2013

Lattice coding over a Gaussian wiretap channel, where an eavesdropper listens to transmissions between a transmitter and a legitimate receiver, is considered. A new lattice invariant called the secrecy gain is used as a code design criterion for wiretap lattice codes since it was shown to characterize the confusion that a chosen lattice can cause at the eavesdropper: the higher the secrecy gain of the lattice, the more confusion. In this paper, secrecy gains of extremal odd unimodular lattices as well as unimodular lattices in dimension $n$, $16leq nleq 23$, are computed, covering the four extremal odd unimodular lattices and all the 111 nonextremal unimodular lattices (both odd and even), providing thus a classification of the best wiretap lattice codes coming from unimodular lattices in dimension $n$, $8. Finally, to permit lattice encoding via Construction A, the corresponding error correction codes of the best lattices are determined.

Codes Against Online Adversaries: Large Alphabets

June 2013

In this paper, we consider the communication of information in the presence of an online adversarial jammer. In the setting under study, a sender wishes to communicate a message to a receiver by transmitting a codeword ${bf x}=(x_{1},ldots,x_{n})$ symbol-by-symbol over a communication channel. The adversarial jammer can view the transmitted symbols $x_{i}$ one at a time and can change up to a ${p}$-fraction of them. However, for each symbol $x_{i}$, the jammer's decision on whether to corrupt it or not (and on how to change it) must depend only on $x_{j}$ for $jleq i$. This is in contrast to the “classical” adversarial jammer which may base its decisions on its complete knowledge of ${bf x}$. More generally, for a delay parameter ${delta}in (0,1)$, we study the scenario in which the jammer's decision on the corruption of $x_{i}$ must depend solely on $x_{j}$ for $jleq i-{delta}{n}$. In this study, the transmitted symbols are assumed to be over a sufficiently large field $BBF$ . The sender and receiver do not share resources such as common randomness (though the sender is allowed to use stochastic encoding). We present a tight characterization of the amount - f information one can transmit in both the 0-delay and, more generally, the ${delta}$-delay online setting. We show that for 0-delay adversaries, the achievable rate asymptotically equals that of the classical adversarial model. For positive values of ${delta}$ , we consider two types of jamming: additive and overwrite. We also extend our results to a jam-or-listen online model, where the online adversary can either jam a symbol or eavesdrop on it. We present computationally efficient achievability schemes even against computationally unrestricted jammers.

Hybrid Noncoherent Network Coding

June 2013

We describe a novel extension of subspace codes for noncoherent networks, suitable for use when the network is viewed as a communication system that introduces both dimension and symbol errors. We show that when symbol erasures occur in a significantly large number of different basis vectors transmitted through the network and when the min-cut of the network is much smaller than the length of the transmitted codewords, the new family of codes outperforms their subspace code counterparts. For the proposed coding scheme, termed hybrid network coding, we derive two upper bounds on the size of the codes. These bounds represent a variation of the Singleton and of the sphere-packing bound. We show that a simple concatenated scheme that consists of subspace codes and Reed–Solomon codes is asymptotically optimal with respect to the Singleton bound. Finally, we describe two efficient decoding algorithms for concatenated subspace codes that in certain cases have smaller complexity than their subspace decoder counterparts.

Parity-Check Matrices Separating Erasures From Errors

June 2013

Most decoding algorithms of linear codes, in general, are designed to correct or detect errors. However, many channels cause erasures in addition to errors. In principle, decoding over such channels can be accomplished by deleting the erased symbols and decoding the resulting vector with respect to a punctured code. For any given linear code and any given maximum number of correctable erasures, parity-check matrices are introduced that yield parity-check equations which do not check any of the erased symbols and which are sufficient to characterize all punctured codes corresponding to this maximum number of erasures. These matrices allow for the separation of erasures from errors to facilitate decoding. Several constructions of such separating parity-check matrices are presented. To reduce decoding complexity, separating parity-check matrices with small number of rows are preferred. The minimum number of rows in a parity-check matrix separating a given maximum number of erasures is called the separating redundancy. Upper and lower bounds on the separating redundancies are derived. In particular, it is shown that the separating redundancies tend to grow linearly with the number of rows in full-rank parity-check matrices of codes. The separating redundancies of some classes of codes are determined for some maximum numbers of erasures.

A Characterization of Entanglement-Assisted Quantum Low-Density Parity-Check Codes

June 2013

As in classical coding theory, quantum analogs of low-density parity-check (LDPC) codes have offered good error correction performance and low decoding complexity by employing the Calderbank–Shor–Steane construction. However, special requirements in the quantum setting severely limit the structures such quantum codes can have. While the entanglement-assisted stabilizer formalism overcomes this limitation by exploiting maximally entangled states (ebits), excessive reliance on ebits is a substantial obstacle to implementation. This paper gives necessary and sufficient conditions for the existence of quantum LDPC codes which are obtainable from pairs of identical LDPC codes and consume only one ebit, and studies the spectrum of attainable code parameters.

Tree-Structure Expectation Propagation for LDPC Decoding Over the BEC

June 2013

We present the tree-structure expectation propagation (Tree-EP) algorithm to decode low-density parity-check (LDPC) codes over discrete memoryless channels (DMCs). Expectation propagation generalizes belief propagation (BP) in two ways. First, it can be used with any exponential family distribution over the cliques in the graph. Second, it can impose additional constraints on the marginal distributions. We use this second property to impose pairwise marginal constraints over pairs of variables connected to a check node of the LDPC code's Tanner graph. Thanks to these additional constraints, the Tree-EP marginal estimates for each variable in the graph are more accurate than those provided by BP. We also reformulate the Tree-EP algorithm for the binary erasure channel (BEC) as a peeling-type algorithm (TEP) and we show that the algorithm has the same computational complexity as BP and it decodes a higher fraction of errors. We describe the TEP decoding process by a set of differential equations that represents the expected residual graph evolution as a function of the code parameters. The solution of these equations is used to predict the TEP decoder performance in both the asymptotic regime and the finite-length regimes over the BEC. While the asymptotic threshold of the TEP decoder is the same as the BP decoder for regular and optimized codes, we propose a scaling law for finite-length LDPC codes, which accurately approximates the TEP improved performance and facilitates its optimization.

Automorphisms of Order $2p$ in Binary Self-Dual Extremal Codes of Length a Multiple of 24

June 2013

Let $C$ be a binary self-dual code with an automorphism $g$ of order $2p$, where $p$ is an odd prime, such that $g^{p}$ is a fixed point free involution. If $C$ is extremal of length a multiple of 24, all the involutions are fixed point free, except the Golay Code and eventually putative codes of length 120. Connecting module theoretical properties of a self-dual code $C$ with coding theoretical ones of the subcode $C(g^{p})$ which consists of the set of fixed points of $g^{p}$, we prove that $C$ is a projective $ {BBF }_{2}langle g rangle $-module if and only if a natural projection of $C(g^{p})$ is a self-dual code. We then discuss easy-to-handle criteria to decide if $C$ is projective or not. As an application, we consider in the last part extremal self-dual codes of length 120, proving that their automorphism group does not contain elements of order 38 and 58.

There is No Self-Dual $ BBZ _{4}$-Linear Code Whose Gray Image Has the Parameters $(72,2^{36},16)$

June 2013

It is shown that there is no self-dual $ BBZ _{4}$-linear code whose Gray image has the parameters $(72,2^{36},16)$.

Characterization of Negabent Functions and Construction of Bent-Negabent Functions With Maximum Algebraic Degree

June 2013

We present necessary and sufficient conditions for a Boolean function to be a negabent function for both an even and an odd number of variables, which demonstrates the relationship between negabent functions and bent functions. By using these necessary and sufficient conditions for Boolean functions to be negabent, we obtain that the nega spectrum of a negabent function has at most four values. We determine the nega spectrum distribution of negabent functions. Further, we provide a method to construct bent-negabent functions in $n$ variables ($n$ even) of algebraic degree ranging from 2 to ${{n} over {2}}$, which implies that the maximum algebraic degree of an $n$-variable bent-negabent function is equal to ${{n} over {2}}$. Thus, we answer two open problems proposed by Parker and Pott and by Stănică

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

June 2013

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 $ {varepsilon }= k/N$ and $delta = n/N$ denote the generalized sparsity and undersampling fractions for sampling the $k$-generalized-sparse $N$ -vector $x_{0}$ according to $y=Ax_{0}$ . Here, $A$ is an $ntimes N$ measurement matrix whose entries are iid standard Gaussian. The formula states that the phase transition curve $ delta = delta ({varepsilon })$ separating successful from unsuccessful reconstruction of $x_{0}$ by AMP is given by $delta = M({v- repsilon }vert {rm Denoiser})$ where $M({varepsilon }vert {rm Denoiser})$ 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.

Reconstruction From Anisotropic Random Measurements

June 2013

Random matrices are widely used in sparse recovery problems, and the relevant properties of matrices with i.i.d. entries are well understood. This paper discusses the recently introduced restricted eigenvalue (RE) condition, which is among the most general assumptions on the matrix, guaranteeing recovery. We prove a reduction principle showing that the RE condition can be guaranteed by checking the restricted isometry on a certain family of low-dimensional subspaces. This principle allows us to establish the RE condition for several broad classes of random matrices with dependent entries, including random matrices with sub-Gaussian rows and nontrivial covariance structure, as well as matrices with independent rows, and uniformly bounded entries.

Certifying the Restricted Isometry Property is Hard

June 2013

This paper is concerned with an important matrix condition in compressed sensing known as the restricted isometry property (RIP). We demonstrate that testing whether a matrix satisfies RIP is ${ssr NP}$-hard. As a consequence of our result, it is impossible to efficiently test for RIP provided ${ssr P}ne{ssr NP}$.

Approximate Sparsity Pattern Recovery: Information-Theoretic Lower Bounds

June 2013

Recovery of the sparsity pattern (or support) of an unknown sparse vector from a small number of noisy linear measurements is an important problem in compressed sensing. In this paper, the high-dimensional setting is considered. It is shown that if the measurement rate and per-sample signal-to-noise ratio (SNR) are finite constants independent of the length of the vector, then the optimal sparsity pattern estimate will have a constant fraction of errors. Lower bounds on the measurement rate needed to attain a desired fraction of errors are given in terms of the SNR and various key parameters of the unknown vector. The tightness of the bounds in a scaling sense, as a function of the SNR and the fraction of errors, is established by comparison with existing achievable bounds. Near optimality is shown for a wide variety of practically motivated signal models.

Compressed Sensing With Nonlinear Observations and Related Nonlinear Optimization Problems

June 2013

Nonconvex constraints are valuable regularizers in many optimization problems. In particular, sparsity constraints have had a significant impact on sampling theory, where they are used in compressed sensing and allow structured signals to be sampled far below the rate traditionally prescribed. Nearly, all of the theory developed for compressed sensing signal recovery assumes that samples are taken using linear measurements. In this paper, we instead address the compressed sensing recovery problem in a setting where the observations are nonlinear. We show that, under conditions similar to those required in the linear setting, the iterative hard thresholding algorithm can be used to accurately recover sparse or structured signals from few nonlinear observations. Similar ideas can also be developed in a more general nonlinear optimization framework. In the second part of this paper, we therefore present related result that shows how this can be done under sparsity and union of subspaces constraints, whenever a generalization of the restricted isometry property traditionally imposed on the compressed sensing system holds.

Matched Filtering From Limited Frequency Samples

June 2013

In this paper, we study a simple correlation-based strategy for estimating the unknown delay and amplitude of a signal based on a small number of noisy, randomly chosen frequency-domain samples. We model the output of this “compressive matched filter” as a random process whose mean equals the scaled, shifted autocorrelation function of the template signal. Using tools from the theory of empirical processes, we prove that the expected maximum deviation of this process from its mean decreases sharply as the number of measurements increases, and we also derive a probabilistic tail bound on the maximum deviation. Putting all of this together, we bound the minimum number of measurements required to guarantee that the empirical maximum of this random process occurs sufficiently close to the true peak of its mean function. We conclude that for broad classes of signals, this compressive matched filter will successfully estimate the unknown delay (with high probability and within a prescribed tolerance) using a number of random frequency-domain samples that scales inversely with the signal-to-noise ratio and only logarithmically in the observation bandwidth and the possible range of delays.

Stationary Random Fields Arising From Second-Order Partial Differential Equations on Compact Lie Groups

June 2013

Wide sense stationary processes are a mainstay of classical signal processing. It is well known that they can be obtained by solving ordinary differential equations with constant coefficients whose right-hand side is a white noise. This paper addresses the extension of this construction to random fields defined on compact Lie groups. On an underlying compact Lie group, the paper studies left invariant second-order elliptic partial differential equations whose right-hand side is a spatial white noise. Quite often, the solution of a partial differential equation is not defined as a function but as a distribution. To adapt to this situation, the paper introduces a definition of wide sense stationary distributions on a compact Lie group. This is shown to be consistent with the more restricted definition of wide sense stationary fields given in a classic paper by Yaglom. It is proved that the solution of a partial differential equation, of the kind being studied, is a wide sense stationary distribution whose covariance structure is determined by the fundamental solution of the equation. As a concrete example, this paper describes the fundamental solution of the Helmholtz equation on the rotation group and the resulting covariance structure.

Nonparametric Sequential Signal Change Detection Under Dependent Noise

June 2013

A nonparametric version of the sequential signal detection problem is studied. Our signal model includes a class of time-limited signals for which we collect data in the sequential fashion at discrete points in the presence of correlated noise. For such a setup we introduce a novel signal detection algorithm relying on the postfiltering smooth correction of the classical Whittaker–Shannon interpolation series. Given a finite frame of noisy samples of the signal, we design a detection algorithm being able to detect a departure from a reference signal as quickly as possible. Our detector is represented as a normalized partial-sum continuous time stochastic process, for which we obtain a functional central limit theorem under weak assumptions on the correlation structure of the noise. Particularly, our results allow for noise processes such as ARMA and general linear processes as well as $ alpha $-mixing processes. The established limit theorems allow us to design monitoring algorithms with the desirable level of the probability of false alarm and able to detect a change with probability approaching one.

Linear Coherent Estimation With Spatial Collaboration

June 2013

A power-constrained sensor network that consists of multiple sensor nodes and a fusion center (FC) is considered, where the goal is to estimate a random parameter of interest. In contrast to the distributed framework, the sensor nodes may be partially connected, where individual nodes can update their observations by (linearly) combining observations from other adjacent nodes. The updated observations are communicated to the FC by transmitting through a coherent multiple access channel. The optimal collaborative strategy is obtained by minimizing the expected mean-square error subject to power constraints at the sensor nodes. Each sensor can utilize its available power for both collaboration with other nodes and transmission to the FC. Two kinds of constraints, namely the cumulative and individual power constraints, are considered. The effects due to imperfect information about observation and channel gains are also investigated. The resulting performance improvement is illustrated analytically through the example of a homogeneous network with equicorrelated parameters. Assuming random geometric graph topology for collaboration, numerical results demonstrate a significant reduction in distortion even for a moderately connected network, particularly in the low local signal-to-noise ratio regime.

Coset Sum: An Alternative to the Tensor Product in Wavelet Construction

June 2013

A multivariate biorthogonal wavelet system can be obtained from a pair of multivariate biorthogonal refinement masks in multiresolution analysis setup. Some multivariate refinement masks may be decomposed into lower dimensional refinement masks. Tensor product is a popular way to construct a decomposable multivariate refinement mask from lower dimensional refinement masks. We present an alternative method, which we call coset sum, for constructing multivariate refinement masks from univariate refinement masks. The coset sum shares many essential features of the tensor product that make it attractive in practice: 1) it preserves the biorthogonality of univariate refinement masks, 2) it preserves the accuracy number of the univariate refinement mask, and 3) the wavelet system associated with it has fast algorithms for computing and inverting the wavelet coefficients. The coset sum can even provide a wavelet system with faster algorithms in certain cases than the tensor product. These features of the coset sum suggest that it is worthwhile to develop and practice alternative methods to the tensor product for constructing multivariate wavelet systems. Some experimental results using 2-D images are presented to illustrate our findings.

Secure Symmetrical Multilevel Diversity Coding

June 2013

Symmetrical multilevel diversity coding (SMDC) is a network compression problem introduced by Roche (1992) and Yeung (1995). In this setting, a simple separate encoding strategy known as superposition coding was shown to be optimal in terms of achieving the minimum sum rate (Roche–Yeung–Hau 1997) and the entire admissible rate region (Yeung–Zhang 1999) of the general problem. This paper considers a natural generalization of SMDC to the secure communication setting with an additional eavesdropper. It is required that all sources need to be kept perfectly secret from the eavesdropper as long as the number of encoder outputs available at the eavesdropper is no more than a given threshold. First, the problem of encoding individual sources is studied. A precise characterization of the entire admissible rate region is established via a connection to the problem of ramp-type secret sharing (Yamamoto 1985 and Blakley–Meadows 1985) and utilizing some basic polyhedral structure of the admissible rate region. Building on this result, it is then shown that superposition coding remains optimal in terms of achieving the minimum sum rate for the general secure SMDC problem.

Real-Time Coding With Limited Lookahead

June 2013

A real-time coding system with lookahead consists of a memoryless source, a memoryless channel, an encoder, which encodes the source symbols sequentially with knowledge of future source symbols up to a fixed finite lookahead $d$ , with or without feedback of the past channel output symbols and a decoder, which sequentially constructs the source symbols using the channel output. The objective is to minimize the expected per-symbol distortion. For a fixed finite lookahead $dgeq 1$, we invoke the theory of controlled Markov chains to obtain an average cost optimality equation (ACOE), the solution of which, denoted by $D(d)$, is the minimum expected per-symbol distortion. With increasing $d$, $D(d)$ bridges the gap between causal encoding, $d=0$, where symbol-by-symbol encoding–decoding is optimal and the infinite lookahead case, $d=infty$, where Shannon Theoretic arguments show that separation is optimal. We extend the analysis to a system with finite-state decoders, with or without noise-free feedback. For a Bernoulli source and binary symmetric channel, under Hamming loss, we compute the optimal distortion for various source and channel parameters, and thus obtain computable bounds on $D(d)$. We also identify regions of source and channel parameters where symbol-by-symbol encoding–decoding is suboptimal. Finally, we demonstrate the wide applicability of our approach by applying it in additional coding scenarios, such as the cas- where the sequential decoder can take cost-constrained actions affecting the quality or availability of side information about the source.

Source Coding When the Side Information May Be Delayed

June 2013

For memoryless sources, delayed side information at the decoder does not improve the rate-distortion function. However, this is not the case for sources with memory, as demonstrated by a number of works focusing on the special case of (delayed) feedforward. In this paper, a setting is studied in which the encoder is potentially uncertain about the delay with which measurements of the side information, which is available at the encoder, are acquired at the decoder. Assuming a hidden Markov model for the source sequences, at first, a single-letter characterization is given for the setup where the side information delay is arbitrary and known at the encoder, and the reconstruction at the destination is required to be asymptotically lossless. Then, with delay equal to zero or one source symbol, a single-letter characterization of the rate-distortion region is given for the case where, unbeknownst to the encoder, the side information may be delayed or not. Finally, examples for binary and Gaussian sources are provided.

Separate Source–Channel Coding for Transmitting Correlated Gaussian Sources Over Degraded Broadcast Channels

June 2013

The problem of transmitting a pair of correlated Gaussian sources over degraded broadcast channels using optimal separate source and channel codes is studied. Upper bounds are derived for the rate penalty (in terms of channel uses per source symbol) and the power loss endured by separate coding compared to joint coding. Although source–channel separation is suboptimal in general, it is demonstrated that the performance of separate coding comes close to that of optimal joint coding, especially for low distortion pairs. In fact, in some cases, separate coding performs better than the best known joint schemes so far. It is also shown analytically that separate coding is optimal when either of the sources is to be reconstructed in a near-lossless fashion.

Gaussian Robust Sequential and Predictive Coding

June 2013

We introduce two new source coding problems: robust sequential coding and robust predictive coding. For the Gauss–Markov source model with the mean squared error distortion measure, we characterize certain supporting hyperplanes of the rate region of these two coding problems. Our investigation also reveals an information-theoretic minimax theorem and the associated extremal inequalities.

Multiterminal Source Coding With Action-Dependent Side Information

June 2013

We consider multiterminal source coding with a single encoder and multiple decoders where either the encoder or the decoders can take cost-constrained actions which affect the quality of the side information present at the decoders. For the scenario where decoders take actions, we characterize the rate–cost tradeoff region for lossless source coding, and give an achievability scheme for lossy source coding for two decoders which is optimum for a variety of special cases of interest. For the case where the encoder takes actions, we characterize the rate–cost tradeoff for a class of lossless source coding scenarios with multiple decoders. Finally, we also consider extensions to other multiterminal source coding settings with actions, and characterize the rate–distortion–cost tradeoff for a case of successive refinement with actions.

Secure Multiterminal Source Coding With Side Information at the Eavesdropper

June 2013

The problem of secure multiterminal source coding with side information at the eavesdropper is investigated. This scenario consists of a main encoder (referred to as Alice) that wishes to compress a single source but simultaneously satisfying the desired requirements on the distortion level at a legitimate receiver (referred to as Bob) and the equivocation rate—average uncertainty—at an eavesdropper (referred to as Eve). It is further assumed the presence of a (public) rate-limited link between Alice and Bob. In this setting, Eve perfectly observes the information bits sent by Alice to Bob and has also access to a correlated source which can be used as side information. A second encoder (referred to as Charlie) helps Bob in estimating Alice's source by sending a compressed version of its own correlated observation via a (private) rate-limited link, which is only observed by Bob. For instance, the problem at hands can be seen as the unification between the Berger–Tung and the secure source coding setups. Inner and outer bounds on the so-called rate-distortion-equivocation region are derived. The inner region turns to be tight for two cases: 1) uncoded side information at Bob and 2) lossless reconstruction of both sources at Bob—secure distributed lossless compression. Application examples to secure lossy source coding of Gaussian and binary sources in the presence of Gaussian and binary/ternary (respectively) side informations are also considered. Optimal coding schemes are characterized for some cases of interest where the statistical differences between the side information at the decoders and the presence of a nonzero distortion at Bob can be fully exploited to guarantee secrecy.

Vector Gaussian Two-Terminal Source Coding

June 2013

We derive a lower bound on each supporting line of the rate region of the vector Gaussian two-terminal CEO problem, which is a special case of the indirect vector Gaussian two-terminal source coding problem. The key technical ingredient is a new extremal inequality. It is shown that the lower bound coincides with the Berger–Tung upper bound in the high-resolution regime. Similar results are derived for the direct vector Gaussian two-terminal source coding problem.

Causal State Communication

June 2013

The problem of state communication over a discrete memoryless channel with discrete memoryless state is studied when the state information is available strictly causally at the encoder. It is shown that block Markov encoding, in which the encoder communicates a description of the state sequence in the previous block by incorporating side information about the state sequence at the decoder, yields the minimum state estimation error. When the same channel is used to send additional independent information at the expense of a higher channel state estimation error, the optimal tradeoff between the rate of the independent information and the state estimation error is characterized via the capacity–distortion function. It is shown that any optimal tradeoff pair can be achieved via rate-splitting. These coding theorems are then extended optimally to the case of causal channel state information at the encoder using the Shannon strategy.

Universal Communication Over Arbitrarily Varying Channels

June 2013

Consider the problem of universally communicating over an arbitrarily varying channel, i.e., a channel comprised of an unknown, arbitrary sequence of memoryless channels. It is shown that there is a communication system using feedback and common randomness that asymptotically attains, with high probability, the capacity of the time-averaged channel, universally for every sequence of channels. This attainable rate is optimal under certain conditions. While no prior knowledge of the channel sequence is assumed, the capacity of the time-averaged channel meets or exceeds the traditional arbitrarily varying channel (AVC) capacity for every memoryless AVC defined over the same alphabets, and therefore, the system universally attains the random code AVC capacity, without knowledge of the AVC parameters. The presented system combines rateless coding with a universal prediction scheme for the input “prior” distribution, from which the codebook is randomly drawn. Because at each point in time, the future of the channel sequence is unknown to the communicators, the adaptation of the input behavior, by universally predicting the prior, plays a major role in the result.

Upper Bounds on the Capacity of Binary Channels With Causal Adversaries

June 2013

In this paper, we consider the communication of information in the presence of a causal adversarial jammer. In the setting under study, a sender wishes to communicate a message to a receiver by transmitting a codeword ${bf x}=(x_{1}, dots, x_{n})$ bit-by-bit over a communication channel. The sender and the receiver do not share common randomness. The adversarial jammer can view the transmitted bits $x_{i}$ one at a time and can change up to a $p$-fraction of them. However, the decisions of the jammer must be made in a causal manner. Namely, for each bit $x_{i}$, the jammer's decision on whether to corrupt it or not must depend only on $x_{j}$ for $j leq i$. This is in contrast to the “classical” adversarial jamming situations in which the jammer has no knowledge of ${bf x}$, or knows ${bf x}$ completely. In this study, we present upper bounds (that hold under both the average and maximal probability of error criteria) on the capacity which hold for both deterministic and stochastic encoding schemes.

Worst-Case Expected-Capacity Loss of Slow-Fading Channels

June 2013

For delay-limited communication over block-fading channels, the difference between the ergodic capacity and the maximum achievable expected rate for coding over a finite number of coherent blocks represents a fundamental measure of the penalty incurred by the delay constraint. This paper introduces a notion of worst-case expected-capacity loss. Focusing on the slow-fading scenario (one-block delay), the worst-case additive and multiplicative expected-capacity losses are precisely characterized for the point-to-point fading channel. Extension to the problem of writing on fading paper is also considered, where both the ergodic capacity and the additive expected-capacity loss over one-block delay are characterized to within one bit per channel use.

On the Multiple-Access Channel With Common Rate-Limited Feedback

June 2013

This paper studies the multiple-access channel (MAC) with rate-limited feedback. The channel output is encoded into one stream of bits, which is provided causally to the two users at the channel input. An achievable rate region for this setup is derived, based on superposition of information, block Markov coding, and coding with various degrees of side information for the feedback link. The suggested region coincides with the Cover–Leung inner bound for large feedback rates. The result is then extended for cases where there is only a feedback link to one of the transmitters, and for a more general case where there are two separate feedback links to both transmitters. We compute achievable regions for the Gaussian MAC and for the binary erasure MAC. The Gaussian region is computed for the case of common rate-limited feedback, whereas the region for the binary erasure MAC is computed for one-sided feedback. It is known that for the latter, the Cover–Leung region is tight, and we obtain results that coincide with the feedback capacity region for high feedback rates.

Minimum Energy per Bit in Broadcast and Interference Channels With Correlated Information

June 2013

This paper develops a methodology for finding minimum energy per bit in networks with correlated information, without at need for finding bounds on capacity. This is used to derive the exact minimum energy per bit for some broadcast and interference channels with common and correlated messages, and bounds on the minimum energy per bit for some other channels.

Computation Alignment: Capacity Approximation Without Noise Accumulation

June 2013

Consider several source nodes communicating across a wireless network to a destination node with the help of several layers of relay nodes. Recent work by Avestimehr has approximated the capacity of this network up to an additive gap. The communication scheme achieving this capacity approximation is based on compress-and-forward, resulting in noise accumulation as the messages traverse the network. As a consequence, the approximation gap increases linearly with the network depth. This paper develops a computation alignment strategy that can approach the capacity of a class of layered, time-varying wireless relay networks up to an approximation gap that is independent of the network depth. This strategy is based on the compute-and-forward framework, which enables relays to decode deterministic functions of the transmitted messages. Alone, compute-and-forward is insufficient to approach the capacity as it incurs a penalty for approximating the wireless channel with complex-valued coefficients by a channel with integer coefficients. Here, this penalty is circumvented by carefully matching channel realizations across time slots to create integer-valued effective channels that are well suited to compute-and-forward. Unlike prior constant gap results, the approximation gap obtained in this paper also depends closely on the fading statistics, which are assumed to be i.i.d. Rayleigh.

Worst-Case Additive Noise in Wireless Networks

June 2013

A classical result in information theory states that the Gaussian noise is the worst-case additive noise in point-to-point channels, meaning that, for a fixed noise variance, the Gaussian noise minimizes the capacity of an additive noise channel. In this paper, we significantly generalize this result and show that the Gaussian noise is also the worst-case additive noise in wireless networks with additive noises that are independent from the transmit signals. More specifically, we show that if we fix the noise variance at each node, then the capacity region with Gaussian noises is a subset of the capacity region with any other set of noise distributions. We prove this result by showing that a coding scheme that achieves a given set of rates on a network with Gaussian additive noises can be used to construct a coding scheme that achieves the same set of rates on a network that has the same topology and traffic demands, but with non-Gaussian additive noises.

Capacity of a Class of Multicast Tree Networks

June 2013

In this paper, we characterize the capacity of a new class of discrete memoryless multicast networks having a tree topology. For achievability, a novel coding scheme is constructed where some relays employ a combination of decode-and-forward and compress-and-forward and the other relays perform a random binning such that codebook constructions and relay operations are independent for each node and do not depend on the network topology. For converse, a new technique of iteratively manipulating inequalities exploiting the tree topology is used. This class of multicast tree networks includes the class of diamond networks studied by Kang and Ulukus as a special case.

Reduced-Dimension Multiuser Detection

June 2013

We present a reduced-dimension multiuser detector (RD-MUD) structure for synchronous systems that significantly decreases the number of required correlation branches at the receiver front end, while still achieving performance similar to that of the conventional matched-filter (MF) bank. RD-MUD exploits the fact that, in some wireless systems, the number of active users may be small relative to the total number of users in the system. Hence, the ideas of analog compressed sensing may be used to reduce the number of correlators. The correlating signals used by each correlator are chosen as an appropriate linear combination of the users' spreading waveforms. We derive the probability of symbol error when using two methods for recovery of active users and their transmitted symbols: the reduced-dimension decorrelating (RDD) detector, which combines subspace projection and thresholding to determine active users and sign detection for data recovery, and the reduced-dimension decision-feedback (RDDF) detector, which combines decision-feedback matching pursuit for active user detection and sign detection for data recovery. We derive probability of error bounds for both detectors, and show that the number of correlators needed to achieve a small probability of symbol error is on the order of the logarithm of the number of users in the system. The theoretical performance results are validated via numerical simulations.

DMT of Parallel-Path and Layered Networks Under the Half-Duplex Constraint

June 2013

In this paper, we study the diversity-multiplexing-gain tradeoff (DMT) of wireless relay networks under the half-duplex constraint. It is often unclear what penalty if any, is imposed by the half-duplex constraint on the DMT of such networks. We study two classes of networks; the first class, called KPP(I) networks, is the class of networks with the relays organized in $K$ parallel paths between the source and the destination. While we assume that there is no direct source-destination path, the $K$ relaying paths can interfere with each other. The second class, termed as layered networks, is comprised of relays organized in layers, where links exist only between adjacent layers.

Diversity-Multiplexing Tradeoff in Multiantenna Multirelay Networks: Improvements and Some Optimality Results

June 2013

This paper investigates the benefits of amplify-and-forward (AF) relaying in the setup of multiantenna wireless networks. For this purpose, random sequential (RS) relaying is studied. It is shown that random unitary matrix multiplication at the relay nodes empowers the RS scheme to achieve a better diversity-multiplexing tradeoff (DMT) as compared to the traditional AF relaying. First, the RS scheme is proved to achieve the optimum DMT for a multiantenna full-duplex single-relay two-hop network. Applying this result, a new achievable DMT is derived for the case of multiantenna half-duplex parallel relay network. Interestingly, it turns out that the DMT of the RS scheme is optimum for the case of multiantenna two parallel noninterfering half-duplex relays. Furthermore, random unitary matrix multiplication is shown to also improve the DMT of the nonorthogonal AF relaying scheme for the case of a multiantenna single relay channel. Finally, the general case of multiantenna full-duplex relay networks is studied. First, a new lower-bound is derived on its DMT using the RS scheme. Furthermore, maximum multiplexing gain of the network is also shown to be achievable by traditional amplify-forward relaying. The gain value is equal to the minimum vertex cut-set of the underlying graph of the network, which can be computed in polynomial time in terms of the number of network nodes.

Degenerate Viterbi Decoding

June 2013

We present a decoding algorithm for quantum convolutional codes that finds the class of degenerate errors with the largest probability conditioned on a given error syndrome. The algorithm runs in time linear with the number of qubits. Previous decoding algorithms for quantum convolutional codes optimized the probability over individual errors instead of classes of degenerate errors. Using Monte Carlo simulations, we show that this modification to the decoding algorithm results in a significantly lower block error rate.

A Representation for the Symbol Error Rate Using Completely Monotone Functions

June 2013

The symbol error rate of an arbitrary multidimensional constellation in the absence of coding impaired by additive white Gaussian noise is characterized as the product of a completely monotone function with a nonnegative power of the signal-to-noise ratio, when the minimum distance detector is used. This representation is also shown to apply to cases when the impairing noise is compound Gaussian. Using this general result, it is proved that the symbol error rate is completely monotone if the rank of its constellation matrix is either one or two. Further, a necessary and sufficient condition for the complete monotonicity of the symbol error rate of a constellation of any dimension is also obtained. Applications to stochastic ordering of wireless system performance are also discussed.

On the Rate Region of CSMA/CA WLANs

June 2013

We characterize the (nonconvex) rate region and its maximal convex subsets for carrier-sense multiple-access with collision-avoidance (CSMA/CA) wireless local-area networks (WLANs), and in particular for 802.11 WLANs. In addition to being of intrinsic interest as fundamental properties of CSMA/CA WLANs, this characterization can be exploited to allow the wealth of convex optimization approaches to be applied to CSMA/CA WLANs, especially to utility fair resource allocation problems.

Optimal Power-Delay Tradeoffs in Fading Channels—Small-Delay Asymptotics

June 2013

When transmitting stochastically arriving data over fading channels, there is an inherent tradeoff between the required average transmission power and the average queueing delay experienced by the data. This tradeoff can be exploited by appropriately scheduling the transmission of data over time. In this paper, we study the behavior of the optimal power-delay tradeoff for a single user in the regime of asymptotically small delays. In this regime, we first lower bound how much average power is required as a function of the average queueing delay. We show that the rate at which this bound increases as the delay becomes asymptotically small depends on the behavior of the fading distribution near zero, as well as the arrival statistics. We lower bound this rate for two different classes of fading distributions: one class that requires infinite power to minimize the queueing delay and one class that requires only finite power. We then show that for both classes, the bounds can essentially be achieved by a sequence of simple “channel threshold” policies, which only transmit when the channel gain is greater than a given threshold. We also consider several other transmission scheduling policies and characterize their convergence behavior in the small-delay regime.

On the Role of Mobility for Multimessage Gossip

June 2013

We consider information dissemination in a large $n$ -user wireless network in which $k$ users wish to share a unique message with all other users. Each of the $n$ users only has knowledge of its own contents and state information; this corresponds to a one-sided push-only scenario. The goal is to disseminate all messages efficiently, hopefully achieving an order-optimal spreading rate over unicast wireless random networks. First, we show that a random-push strategy—where a user sends its own or a received packet at random—is order-wise suboptimal in a random geometric graph: specifically, $Omegaleft(sqrt{n}right)$ times slower than optimal spreading. It is known that this gap can be closed if each user has “full” mobility, since this effectively creates a complete graph. We instead consider velocity-constrained mobility where at each time slot the user moves locally using a discrete random walk with velocity $v(n)$ that is much lower than full mobility. We propose a simple two-stage dissemination strategy that alternates between individual message flooding (“self promotion”) and random gossiping. We prove that this scheme achieves a close to optimal spreading rate (within only a logarithmic gap) as long as the velocity is at least $v(n)=omega (sqrt{log n/k})$. The key insight is that the mixing property introduced by the partial mobility helps users to spread in space within a relatively short period compared to the optimal spreading time, which macroscopically mimics message dissemination over a complete graph.

Broadcast-Based Consensus With Non-Zero-Mean Stochastic Perturbations

June 2013

Bolstered by the growing interest in building wireless sensor and ad hoc networks with applications ranging across different engineering disciplines, distributed consensus algorithms have recently seen a new revival since their inception in the early 1980s. Of particular interest is the recently developed broadcast-based consensus algorithm, which is one special type of randomized consensus algorithms and is amenable to practical implementation in wireless networks. This paper focuses on the performance analysis of this broadcast-based consensus algorithm in the presence of non-zero-mean stochastic perturbations. It is demonstrated that as the algorithm proceeds, the deviation of the node states from their average will converge, in expectation, to a fixed value, which is determined by the Laplacian matrix of the network, the mixing parameter, and the mean of the stochastic perturbations. Asymptotic upper and lower bounds on the total mean-square deviation are derived, which describe the range of distances over which the node states deviate from consensus. These bounds can facilitate evaluation of the applicability of this algorithm in practice. Results are also provided on the algorithm's $epsilon$-converging time, i.e., the earliest time at which the deviation is $epsilon$ close to its steady value, and on the mean and mean-square behaviors of the displacement of node states from their initial states at large iteration number. As a special case study, performance of the broadcast-based consensus algorithm under zero-mean stochastic disturbances is analyzed, and results regarding its convergence, mean-square deviation, and mean-square displacement are given. The theoretical results presented in this study hold true regardless of the statistics of the stochastic disturbances, and are valid for arbitrary network topology as long as th- topology is connected.

New Polyphase Sequence Families With Low Correlation Derived From the Weil Bound of Exponential Sums

June 2013

In this paper, the sequence families of which maximum correlation is determined by the Weil bound of exponential sums are revisited. Using the same approach, two new constructions with large family sizes and low maximum correlation are given. The first construction is an analog of one recent result derived from the interleaved structure of Sidel'nikov sequences. For a prime $p$ and an integer $Mvert (p-1)$, the new $M$-ary sequence families of period $p$ are obtained from irreducible quadratic polynomials and known power residue-based sequence families. The new sequence families increase family sizes of the known power residue-based sequence families, but keep the maximum correlation unchanged. In the second construction, the sequences derived from the Weil representation are generalized, where each new sequence is the elementwise product of a modulated Sidel'nikov sequence and a modulated trace sequence. For positive integers $d and $Mvert (p^{n}-1)$, the new family consists of $(M-1)p^{nd}$ sequences with period $p^{n}-1$, alphabet size $Mp$, and the maximum correlation bounded by $(d+1)sqrt{p^{n}}+3$.

Asymptotically Optimal Optical Orthogonal Codes With New Parameters

June 2013

Optical orthogonal codes (OOCs) are widely used as spreading codes in optical fiber networks. An $(N,w,lambda_{rm a},lambda_{rm c})$-OOC with size $L$ is a family of $L;{0,1}$-sequences with length $N$, weight $w$, maximum autocorrelation $lambda_{rm a}$, and maximum cross correlation $lambda_{rm c}$. In this paper, we present two new constructions for OOCs with $lambda_{rm a}=lambda_{rm c}=1$ which are asymptotically optimal with respect to the Johnson bound. We first construct an asymptotically optimal $left(Mp^{n},M,1,1right)$ -OOC with size $(p^{n}-1)/M$ by using the structure of ${BBZ}_{p^{n}}$, the ring of integers modulo $p^{n}$, where $p$ is an odd prime with $Mvert p-1$, and $n$ is a positive integer. We then present another asymptotically optimal $(Mp_{1}cdots p_{k}, M, 1,1)$-OOC with size $(p_{1}cdots p_{k}-1)/M$ from a prod- ct of $k$ finite fields, where $p_{i}$ is an odd prime and $M$ is a positive integer such that $Mvert ,p_{i}-1$ for $1leq ileq k$. In particular, it is optimal in the case that $k=1$ and $(M-1)^{2} > p_{1}-1$.

On the Density of Irreducible NFSRs

June 2013

Let $n$ be a positive integer. An NFSR of $n$ stages is called irreducible if the family of output sequences of any NFSR of stages less than $n$ is not included in that of the NFSR. In this paper, we prove that the density of the irreducible NFSRs of $n$ stages is larger than 0.39. This implies that it is expected to find an irreducible NFSR of $n$ stages among three randomly chosen NFSRs of $n$ stages.

Further Results on the Distinctness of Binary Sequences Derived From Primitive Sequences Modulo Square-Free Odd Integers

June 2013

This paper studies the distinctness of primitive sequences over ${bf Z}/(M)$ modulo 2, where $M$ is an odd integer that is composite and square-free, and ${bf Z}/(M)$ is the integer residue ring modulo $M$. A new sufficient condition is given for ensuring that primitive sequences generated by a primitive polynomial $fleft(xright)$ over ${bf Z}/(M)$ are pairwise distinct modulo 2. Such result improves a recent result obtained in our previous paper, and consequently, the set of primitive sequences over ${bf Z}/(M)$ that can be proven to be distinct modulo 2 is greatly enlarged.

Duality in Entanglement-Assisted Quantum Error Correction

June 2013

The dual of an entanglement-assisted quantum error-correcting (EAQEC) code is defined from the orthogonal group of a simplified stabilizer group. From the Poisson summation formula, this duality leads to the MacWilliams identities and linear programming bounds for EAQEC codes. We establish a table of upper and lower bounds on the minimum distance of any maximal-entanglement EAQEC code with length up to 15 channel qubits.

New Separations in Zero-Error Channel Capacity Through Projective Kochen–Specker Sets and Quantum Coloring

June 2013

We introduce two generalizations of Kochen–Specker (KS) sets: projective KS sets and generalized KS sets. We then use projective KS sets to characterize all graphs for which the chromatic number is strictly larger than the quantum chromatic number. Here, the quantum chromatic number is defined via a nonlocal game based on graph coloring. We further show that from any graph with separation between these two quantities, one can construct a classical channel for which entanglement assistance increases the one-shot zero-error capacity. As an example, we exhibit a new family of classical channels with an exponential increase.

On the Final Exponentiation in Tate Pairing Computations

June 2013

The Tate pairing computation consists of two parts: Miller step and final exponentiation step. In this paper, we investigate the structure of the final exponentiation step. Consider an order $r$ subgroup of an elliptic curve defined over $BBF _{q}$ with embedding degree $k$. The final exponentiation in the Tate pairing is an exponentiation of an element in $BBF _{q^{k}}$ by $(q^{k}-1)/r$ . The hardest part of this computation is to raise to the power $lambda :=Phi _{k}(q)/r$, where $Phi _{k}(cdot)$ denotes the $k$th cyclotomic polynomial. Write it as $lambda =lambda _{0}+lambda _{1}q+cdots +lambda _{varphi (k)-1}q^{varphi (k)-1}$ in the $q$ -ary representation. The final exponentiation cost mostly depends on $kappa (lambda)$, the size of the maximum of $vert lambda _{i}vert $. In many parameterized pairing-friendly curves, the value $kappa $ is about $left (1- {{ 1}over { rho varphi (k)}}right)log _{2} q$ where $rho =log _{2} q/log _{2} r$, while random curves wil- have $kappa approx log _{2} q$. We investigate how this small $kappa $ is obtained for parameterized pairing-friendly elliptic curves, and show that $left (1- {{ 1}over { rho varphi (k)}}right)log _{2} q$ is the lower bound for all known construction methods of parameterized pairing-friendly curves. In the second part of our paper, we propose a method to obtain a modified Tate pairing with small $kappa $ for any pairing-friendly elliptic curves including those not belonging to parameterized families. More precisely, our method finds an integer $m$ using the lattice basis reduction such that $kappa (mlambda)=left (1- {{ 1}over { rho varphi (k)}}right)log _{2} q$. Using this modified Tate pairing, we can reduce the number of squarings in the final exponentiation by a factor of $left (1- {{ 1}over { rho varphi (k)}}right)$ from the usual Tate pairing. We apply our method to several known pairing-friendly curves to verify the expected speedup.

Secure and Efficient LCMQ Entity Authentication Protocol

June 2013

The simple, computationally efficient HB-like entity authentication protocols based on the learning parity with noise (LPN) problem have attracted a great deal of attention in the past few years due to the broad application prospect in low-cost RFID tags. However, all previous protocols are vulnerable to a man-in-the-middle attack discovered by Ouafi, Overbeck, and Vaudenay. In this paper, we propose a lightweight authentication protocol named LCMQ and prove it secure in a general man-in-the-middle model. The technical core in our proposal is a special type of circulant matrix, for which we prove the linear independence of matrix vectors, present efficient algorithms on matrix operations, and describe a secure encryption against ciphertext-only attack. By combining all of those with LPN and related to the multivariate quadratic problem, the LCMQ protocol not only is provably secure against all probabilistic polynomial-time adversaries, but also transcends HB-like protocols in terms of tag's computation overhead, storage expense, and communication cost.

Comments on “New Inner and Outer Bounds for the Memoryless Cognitive Interference Channel and Some New Capacity Results”

June 2013

In a recent paper [1], Rini et al. proved a capacity result for the discrete memoryless cognitive interference channel, under the condition named “better cognitive decoding.” We show that this capacity region is the same as the capacity region characterized by Wu et al. in [2].

IEEE Transactions on Information Theory information for authors

June 2013

Information Theory, IEEE Transactions on - new TOC

Table of contents

IEEE Transactions on Information Theory publication information

Linear-Algebraic List Decoding for Variants of Reed–Solomon Codes

On Rational Interpolation-Based List-Decoding and List-Decoding Binary Goppa Codes

Localized Error Correction in Projective Space

A Classification of Unimodular Lattice Wiretap Codes in Small Dimensions

Codes Against Online Adversaries: Large Alphabets

Hybrid Noncoherent Network Coding

Parity-Check Matrices Separating Erasures From Errors

A Characterization of Entanglement-Assisted Quantum Low-Density Parity-Check Codes

Tree-Structure Expectation Propagation for LDPC Decoding Over the BEC

Automorphisms of Order $2p$ in Binary Self-Dual Extremal Codes of Length a Multiple of 24

There is No Self-Dual $ BBZ _{4}$-Linear Code Whose Gray Image Has the Parameters $(72,2^{36},16)$

Characterization of Negabent Functions and Construction of Bent-Negabent Functions With Maximum Algebraic Degree

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

Reconstruction From Anisotropic Random Measurements

Certifying the Restricted Isometry Property is Hard

Approximate Sparsity Pattern Recovery: Information-Theoretic Lower Bounds

Compressed Sensing With Nonlinear Observations and Related Nonlinear Optimization Problems

Matched Filtering From Limited Frequency Samples

Stationary Random Fields Arising From Second-Order Partial Differential Equations on Compact Lie Groups

Nonparametric Sequential Signal Change Detection Under Dependent Noise

Linear Coherent Estimation With Spatial Collaboration

Coset Sum: An Alternative to the Tensor Product in Wavelet Construction

Secure Symmetrical Multilevel Diversity Coding

Real-Time Coding With Limited Lookahead

Source Coding When the Side Information May Be Delayed

Separate Source–Channel Coding for Transmitting Correlated Gaussian Sources Over Degraded Broadcast Channels

Gaussian Robust Sequential and Predictive Coding

Multiterminal Source Coding With Action-Dependent Side Information

Secure Multiterminal Source Coding With Side Information at the Eavesdropper

Vector Gaussian Two-Terminal Source Coding

Causal State Communication

Universal Communication Over Arbitrarily Varying Channels

Upper Bounds on the Capacity of Binary Channels With Causal Adversaries

Worst-Case Expected-Capacity Loss of Slow-Fading Channels

On the Multiple-Access Channel With Common Rate-Limited Feedback

Minimum Energy per Bit in Broadcast and Interference Channels With Correlated Information

Computation Alignment: Capacity Approximation Without Noise Accumulation

Worst-Case Additive Noise in Wireless Networks

Capacity of a Class of Multicast Tree Networks

Reduced-Dimension Multiuser Detection

DMT of Parallel-Path and Layered Networks Under the Half-Duplex Constraint

Diversity-Multiplexing Tradeoff in Multiantenna Multirelay Networks: Improvements and Some Optimality Results

Degenerate Viterbi Decoding

A Representation for the Symbol Error Rate Using Completely Monotone Functions

On the Rate Region of CSMA/CA WLANs

Optimal Power-Delay Tradeoffs in Fading Channels—Small-Delay Asymptotics

On the Role of Mobility for Multimessage Gossip

Broadcast-Based Consensus With Non-Zero-Mean Stochastic Perturbations

New Polyphase Sequence Families With Low Correlation Derived From the Weil Bound of Exponential Sums

Asymptotically Optimal Optical Orthogonal Codes With New Parameters

On the Density of Irreducible NFSRs

Further Results on the Distinctness of Binary Sequences Derived From Primitive Sequences Modulo Square-Free Odd Integers

Duality in Entanglement-Assisted Quantum Error Correction

New Separations in Zero-Error Channel Capacity Through Projective Kochen–Specker Sets and Quantum Coloring

On the Final Exponentiation in Tate Pairing Computations

Secure and Efficient LCMQ Entity Authentication Protocol

Comments on “New Inner and Outer Bounds for the Memoryless Cognitive Interference Channel and Some New Capacity Results”

IEEE Transactions on Information Theory information for authors