Showing total 165 results

1. Phase Transition Analysis for Covariance-Based Massive Random Access With Massive MIMO.

Author

Chen, Zhilin, Sohrabi, Foad, Liu, Ya-Feng, and Yu, Wei

Subjects

FISHER information, PHASE transitions, MAXIMUM likelihood statistics, COVARIANCE matrices, ERROR probability, BEHAVIORAL assessment

Abstract

This paper considers a massive random access problem in which a large number of sporadically active devices wish to communicate with a base station (BS) equipped with massive multiple-input multiple-output (MIMO) antennas. Each device is preassigned a unique signature sequence, and the BS identifies the active devices by detecting which sequences are transmitted. This device activity detection problem can be formulated as a maximum likelihood estimation (MLE) problem for which the sample covariance matrix of the received signal is a sufficient statistic. The goal of this paper is to characterize the feasible set of problem parameters under which this covariance based approach is able to successfully recover the device activities in the massive MIMO regime. Through an analysis of the asymptotic behaviors of MLE via its associated Fisher information matrix, this paper derives a necessary and sufficient condition on the Fisher information matrix to ensure a vanishing probability of detection error as the number of antennas goes to infinity, based on which a numerical phase transition analysis is obtained. This condition is also examined from a perspective of covariance matching, which relates the phase transition analysis to a recently derived scaling law. Further, we provide a characterization of the distribution of the estimation error in MLE, based on which the error probabilities in device activity detection can be accurately predicted. Finally, this paper studies a random access scheme with joint device activity and data detection and analyzes its performance in a similar way. [ABSTRACT FROM AUTHOR]

Published

2022

2. Converse Bounds on Modulation-Estimation Performance for the Gaussian Multiple-Access Channel.

Author

Unsal, Ayse, Knopp, Raymond, and Merhav, Neri

Subjects

GAUSSIAN distribution, MEAN square algorithms, RANDOM noise theory, MATHEMATICAL models, EXPONENTS

Abstract

This paper focuses on the problem of separately modulating and jointly estimating two independent continuous-valued parameters sent over a Gaussian multiple-access channel (MAC) under the mean square error (MSE) criterion without bandwidth constraints. To this end, we first improve an existing lower bound on the MSE that is obtained using the parameter modulation-estimation techniques for the single-user additive white Gaussian noise (AWGN) channel. As for the main contribution of this paper, this improved modulation-estimation analysis is generalized to the model of the two-user Gaussian MAC. We present outer bounds to the achievable region in the plane of the MSE’s of the two user parameters, which provides a trade-off between the MSE’s, where we used zero-rate lower bounds on the error probability of Gaussian channels by Shannon and Polyanskiy et al. Numerical results showed that, the multi-user adaptation of the zero-rate lower bound by Polyanskiy et al. provides a tighter overall lower bound on the MSE pairs than the classical Shannon bound. In addition, we introduced upper bounds on the MSE exponents, namely, the exponential decay rates of these MSE’s in the asymptotic regime of long blocks that could make use of any bound on the error exponent of a single-user AWGN channel. The obtained results are numerically evaluated for three different bounds on the reliability function of the Gaussian channel. It is shown that the adaptation of the reliability function by Ashikhmin et al. to the MAC provides a significantly tighter characterization than Shannon’s sphere-packing bound and the divergence bound. [ABSTRACT FROM AUTHOR]

Published

2018

3. Generalized Nearest Neighbor Decoding.

Author

Wang, Yizhu and Zhang, Wenyi

Subjects

GAUSSIAN channels, EUCLIDEAN distance, CHANNEL estimation

Abstract

It is well known that for Gaussian channels, a nearest neighbor decoding rule, which seeks the minimum Euclidean distance between a codeword and the received channel output vector, is the maximum likelihood solution and hence capacity-achieving. Nearest neighbor decoding remains a convenient and yet mismatched solution for general channels, and the key message of this paper is that the performance of nearest neighbor decoding can be improved by generalizing its decoding metric to incorporate channel state dependent output processing and codeword scaling. Using generalized mutual information, which is a lower bound to the mismatched capacity under independent and identically distributed codebook ensemble, as the performance measure, this paper establishes the optimal generalized nearest neighbor decoding rule, under Gaussian channel input. Several restricted forms of the generalized nearest neighbor decoding rule are also derived and compared with existing solutions. The results are illustrated through several case studies for fading channels with imperfect receiver channel state information and for channels with quantization effects. [ABSTRACT FROM AUTHOR]

Published

2022

4. Reconstruction of Sequences Over Non-Identical Channels.

Author

Horovitz, Michal and Yaakobi, Eitan

Subjects

NUMERICAL analysis, GEOMETRIC vertices, FOUNDATIONS of arithmetic, DECODING algorithms, NANOPARTICLES

Abstract

Motivated by the error behavior in the DNA storage channel, in this paper, we extend the previously studied sequence reconstruction problem by Levenshtein. The reconstruction problem studies the model in which the information is read through multiple noisy channels, and the decoder, which receives all channel estimations, is required to decode the information. For the combinatorial setup, the assumption is that all the channels cause at most some t errors. Levenshtein considered the case in which all the channels have the same behavior, and we generalize this model and assume that the channels are not identical. Thus, different channels may cause different maximum numbers of errors. For example, we assume that there are N channels, which cause at most t1 or t2 errors, where t1 < t2, and the number of channels with at most t1 errors is at least [pN], for some fixed 0 < p < 1. If the information codeword belongs to a code with minimum distance d, the problem is then to find the minimum number of channels that guarantees successful decoding in the worst case. A different problem we study in this paper is where the number of channels is fixed, and the question is finding the minimum distance d that provides exact reconstruction. We study these problems and show how to apply them for the cases of substitutions and transpositions. [ABSTRACT FROM AUTHOR]

Published

2019

5. Tracking Unstable Autoregressive Sources Over Discrete Memoryless Channels.

Author

Timo, Roy, Vellambi, Badri N., Grant, Alex, and Nguyen, Khoa D.

Subjects

CHANNEL coding, GREEN'S functions, ANDROGEN receptors

Abstract

We consider the problem of tracking, in realtime, an unstable autoregressive (AR) source over a discrete memoryless channel (DMC). We present computable achievable bounds on the optimal tracking error for general DMCs, and we particularize these bounds to the binary erasure, packet erasure, and binary symmetric channels. The achievable bounds in this paper are proved using a partially separate source quantization and channel coding architecture. We do not use complete or strict separation in usual Shannon sense: 1) the quantiser’s resolution is optimized against the error-correction capabilities of the channel code and the channel code is optimized against an AR Hamming distortion function matched to the source (a weighted Hamming distortion function that provides unequal error protection to different parts of the AR source). The achievability results for general DMCs are proved by combining the AR Hamming distortion function with new realtime (streaming) versions of the random coding union and dependence testing bounds. When applied to erasure channels, these general bounds combine with simple converses to demonstrate that the channel’s cutoff rate plays an important role in realtime tracking. [ABSTRACT FROM AUTHOR]

Published

2019

6. Mutual Information, Relative Entropy and Estimation Error in Semi-Martingale Channels.

Author

Jiao, Jiantao, Venkat, Kartik, and Weissman, Tsachy

Subjects

INFORMATION theory, ENTROPY (Information theory), SAMPLING errors, SIGNAL-to-noise ratio, GAUSSIAN channels, POISSON processes

Abstract

Fundamental relations between information and estimation have been established in the literature for the continuous time Gaussian and Poisson channels. In this paper, we demonstrate that such relations hold for a much larger family of continuous-time channels. We introduce the family of semi-martingale channels where the channel output is a semi-martingale stochastic process, and the channel input modulates the characteristics of the semi-martingale. For these channels, which includes as a special case the continuous time Gaussian and Poisson models, we establish new representations relating the mutual information between the channel input and output to an optimal causal filtering loss, thereby unifying and considerably extending results from the Gaussian and Poisson settings. Extensions to the setting of mismatched estimation are also presented where the relative entropy between the laws governing the output of the channel under two different input distributions is equal to the cumulative difference between the estimation loss incurred by using the mismatched and optimal causal filters, respectively. The main tool underlying these results is the Doob–Meyer decomposition of a class of sub-martingales. The results in this paper can be viewed as the continuous-time analogues of recent generalizations for relations between information and estimation for discrete-time Lévy channels. [ABSTRACT FROM AUTHOR]

Published

2018

7. Asymptotically Optimal Pilot Allocation Over Markovian Fading Channels.

Author

Larranaga, Maialen, Assaad, Mohamad, Destounis, Apostolos, and Paschos, Georgios S.

Subjects

PARTIALLY observable Markov decision processes, ASYMPTOTIC expansions, WIRELESS communications, CHANNEL estimation, LAGRANGIAN functions

Abstract

We investigate a pilot allocation problem in wireless networks over Markovian fading channels. In wireless systems, the channel state information (CSI) is collected at the base station, in particular, this paper considers a pilot-aided channel estimation method (TDD mode). Typically, there are less available pilots than users, hence at each slot the scheduler needs to decide an allocation of pilots to users with the goal of maximizing the long-term average throughput. There is an inherent tradeoff in how the limited pilots are used: assign a pilot to a user with up-to-date CSI and good channel condition for exploitation, or assign a pilot to a user with outdated CSI for exploration. As we show, the arising pilot allocation problem is a restless bandit problem and thus its optimal solution is out of reach. In this paper, we propose an approximation based on the Lagrangian relaxation method, which provides a low-complexity Whittle index policy. We prove this policy to be asymptotically optimal in the many users regime (when the number of users in the system and the available pilots for channel sensing grow large). We evaluate the performance of Whittle’s index policy in various scenarios and illustrate its remarkably good performance for small number of users, where it is not guaranteed to be optimal. [ABSTRACT FROM AUTHOR]

Published

2018

8. Complete Characterization of Gorbunov and Pinsker Nonanticipatory Epsilon Entropy of Multivariate Gaussian Sources: Structural Properties.

Author

Charalambous, Charalambos D., Charalambous, Themistoklis, Kourtellaris, Christos, and van Schuppen, Jan H.

Subjects

CHANNEL coding, ESTIMATION theory, ENTROPY, STOCHASTIC processes, GAUSSIAN processes, RDF (Document markup language)

Abstract

This paper derives the optimal test channel distribution and the complete characterization of the classical Gorbunov and Pinsker (1973), Gorbunov and Pinsker (1974) nonanticipatory epsilon entropy of multivariate Gaussian Markov sources with square-error fidelity, which remained an open problem since 1974. The paper also formulates a state dependent nonanticipatory epsilon entropy, in which past reproductions are available to the decoder and not to the encoder, the test channel is specified with respect to an auxiliary (state) random process, and the reproduction process is a causal function of past reproduction and the auxiliary random process. This variation is analogous to the Wyner and Ziv (1976) and Wyner (1978) rate distortion function (RDF), of memoryless sources. It is shown that the operational rate of zero-delay codes, with past reproductions available to the decoder but not to the encoder is bounded below by the state dependent nonanticipatory epsilon entropy rate. For the case of multivariate Gaussian Markov sources with square-error fidelity, the optimal test channel distribution and the complete characterization of the state dependent of nonanticipatory epsilon entropy are derived, and also shown that that the two nonanticipatory epsilon entropies coincide. The derivations are new; they are based on structural properties of the stochastic realizations of the reproduction process that induce the optimal test channel distributions. They are derived using, achievable lower bounds on information theoretic measures, properties of mean-square estimation theory, Hadamard’s inequality, and canonical correlation coefficients of a tuple of multivariate jointly Gaussian random processes. Applications of the nonanticipatory epsilon entropy and its state dependent variation are discussed to the areas of control of unstable Gaussian systems over limited memory channels, design of causal estimators for Gaussian Markov sources with a fidelity criterion, computation of the rate loss of causal and zero-delay codes of Gaussian Markov sources with respect to non-causal codes. [ABSTRACT FROM AUTHOR]

Published

2022

9. Communication Over Quantum Channels With Parameter Estimation.

Subjects

CHANNEL estimation, PARAMETER estimation, QUANTUM communication, QUANTUM states, QUANTUM mechanics, KALMAN filtering

Abstract

Communication over a random-parameter quantum channel when the decoder is required to reconstruct the parameter sequence is considered. We study scenarios that include either strictly-causal, causal, or non-causal channel side information (CSI) available at the encoder, and also when CSI is not available. This model can be viewed as a form of quantum metrology, and as the quantum counterpart of the classical rate-and-state channel with state estimation at the decoder. Regularized formulas for the capacity-distortion regions are derived. In the special case of measurement channels, single-letter characterizations are derived for the strictly-causal and causal settings. Furthermore, in the more general case of entanglement-breaking channels, a single-letter characterization is derived when CSI is not available. As a consequence, we obtain regularized formulas for the capacity of random-parameter quantum channels with CSI, generalizing previous results by Boche et al., 2016, on classical-quantum channels. Bosonic dirty paper coding is introduced as a consequence, where we demonstrate that the optimal coefficient is not necessarily that of minimum mean-square error estimation as in the classical setting. [ABSTRACT FROM AUTHOR]

Published

2022

10. Traffic-Aware Training and Scheduling for MISO Wireless Downlink Systems.

Author

Destounis, Apostolos, Assaad, Mohamad, Debbah, Merouane, and Sayadi, Bessem

Subjects

WIRELESS communications, RAYLEIGH fading channels, TIME division multiple access, TRANSMITTERS (Communication), CHANNEL estimation

Abstract

In this paper, the problem of feedback and active user selection in multiple-input single-output (MISO) wireless systems such that the system’s stability region is as big as possible is examined. The focus is on a system in a Rayleigh fading environment where zero forcing precoding is used to serve all active users in every slot. Acquisition of the channel states is done via uplink training in time division duplexing mode by the active users. Clearly, only a subset of users can perform uplink training and the selection of this subset is a challenging and interesting problem especially in MISO systems. The stability regions of a baseline centralized scheme and two novel decentralized policies are examined analytically. In the decentralized schemes, the transmitter broadcasts periodically the queue state information and the users contend for the channel in a carrier sense multiple access-based manner with parameters based on the outdated queue state information and real-time channel state information. We show that, using infrequent signaling between the base station and the users, the decentralized policies outperform the centralized policy. In addition, a threshold-based user selection and training scheme for discrete-time contention is proposed. The results of this paper imply that, as far as stability is concerned, the users must be involved in the active user selection and feedback/training decision. This should be leveraged in future communication systems. [ABSTRACT FROM AUTHOR]

Published

2015

11. On the Sample Complexity of Multichannel Frequency Estimation via Convex Optimization.

Author

Yang, Zai, Tang, Jinhui, Eldar, Yonina C., and Xie, Lihua

Subjects

MULTICHANNEL communication, CONVEX functions, SIGNAL sampling, DATA compression

Abstract

The use of multichannel data in line spectral estimation (or frequency estimation) is common for improving the estimation accuracy in array processing, structural health monitoring, wireless communications, and more. Recently proposed atomic norm methods have attracted considerable attention due to their provable superiority in accuracy, flexibility, and robustness compared with conventional approaches. In this paper, we analyze atomic norm minimization for multichannel frequency estimation from noiseless compressive data, showing that the sample size per channel that ensures exact estimation decreases with the increase of the number of channels under mild conditions. In particular, given $L$ channels, order $K \left ({\log K}\right) \left ({1+\frac {1}{L}\log N}\right)$ samples per channel, selected randomly from $N$ equispaced samples, suffice to ensure with high probability exact estimation of $K$ frequencies that are normalized and mutually separated by at least $\frac {4}{N}$. Numerical results are provided corroborating our analysis. [ABSTRACT FROM AUTHOR]

Published

2019

12. Free-Space Optical Communication: A Diversity-Multiplexing Tradeoff Perspective.

Author

Jaiswal, Anshul and Bhatnagar, Manav R.

Subjects

MIMO systems, DATA transmission systems, CHANNEL estimation, ANTENNAS (Electronics), RAYLEIGH fading channels, RADIO frequency

Abstract

Due to the rapid growth of free-space optical (FSO) communication over the last few years, there is an exigency to develop diversity-multiplexing tradeoff (DMT) metric in order to compare and design new multiple-input multiple-output (MIMO) FSO schemes. This paper introduces the DMT for MIMO-FSO systems that utilize the intensity modulation and direct detection technique for which the channel gains are real and positive, contrary to MIMO radio-frequency (MIMO-RF) systems where the channel gains are complex. Log-normal, gamma–gamma, and negative exponential channel models are used in this paper to cover weak to saturated turbulence environments. It is shown that at zero multiplexing gain ($r$), the log-normal channel offers maximum but finite diversity order that depends on the block length within which the channel matrix is constant. On the other hand, negative exponential channel offers minimum diversity order. However, for $r \geq 1$ , DMT curves under all channel models are of the same nature; and for a given $r$ , the diversity is half as that observed in the MIMO-RF channels. To gain additional insights into the DMT of an MIMO-FSO system, we also develop upper and lower bound expressions of DMT and determine the minimum block length at which these bounds are identical. [ABSTRACT FROM AUTHOR]

Published

2019

13. Zero-Error Feedback Capacity for Bounded Stabilization and Finite-State Additive Noise Channels.

Author

Saberi, Amir, Farokhi, Farhad, and Nair, Girish N.

Subjects

TOPOLOGICAL entropy, NOISE, LINEAR systems, CHANNEL estimation, ENTROPY, VARIATIONAL principles

Abstract

This article studies the zero-error feedback capacity of causal discrete channels with memory. First, by extending the classical zero-error feedback capacity concept, a new notion of uniform zero-error feedback capacity $C_{0f} $ for such channels is introduced. Using this notion a tight condition for bounded stabilization of unstable noisy linear systems via causal channels is obtained, assuming no channel state information at either end of the channel. Furthermore, the zero-error feedback capacity of a class of additive noise channels is investigated. It is known that for a discrete channel with correlated additive noise, the ordinary capacity with or without feedback is equal $\log q-\mathcal {H}_{ch} $ , where $\mathcal {H}_{ch} $ is the entropy rate of the noise process and $q $ is the input alphabet size. In this paper, for a class of finite-state additive noise channels (FSANCs), it is shown that the zero-error feedback capacity is either zero or $C_{0f} =\log q -h_{ch} $ , where $h_{ch} $ is the topological entropy of the noise process. A condition is given to determine when the zero-error capacity with or without feedback is zero. This, in conjunction with the stabilization result, leads to a “Small-Entropy Theorem”, stating that stabilization over FSANCs can be achieved if the sum of the topological entropies of the linear system and the channel is smaller than $\log q$. [ABSTRACT FROM AUTHOR]

Published

2022

14. Sampling With Replacement vs Poisson Sampling: A Comparative Study in Optimal Subsampling.

Author

Wang, Jing, Zou, Jiahui, and Wang, HaiYing

Subjects

ASYMPTOTIC distribution, SAMPLING (Process), COMPARATIVE studies, PROBABILITY theory, APPROXIMATION algorithms, BAYES' estimation, CHANNEL estimation

Abstract

Faced with massive data, subsampling is a commonly used technique to improve computational efficiency, and using nonuniform subsampling probabilities is an effective approach to improve estimation efficiency. For computational efficiency, subsampling is often implemented with replacement or through Poisson subsampling. However, no rigorous investigation has been performed to study the difference between the two subsampling procedures such as their estimation efficiency and computational convenience. This paper performs a comparative study on these two different sampling procedures. In the context of maximizing a general target function, we first derive asymptotic distributions for estimators obtained from the two sampling procedures. The results show that the Poisson subsampling may have a higher estimation efficiency. Based on the asymptotic distributions for both subsampling with replacement and Poisson subsampling, we derive optimal subsampling probabilities that minimize the variance functions of the subsampling estimators. These subsampling probabilities further reveal the similarities and differences between subsampling with replacement and Poisson subsampling. The theoretical characterizations and comparisons on the two subsampling procedures provide guidance to select a more appropriate subsampling approach in practice. Furthermore, practically implementable algorithms are proposed based on the optimal structural results, which are evaluated through both theoretical and empirical analyses. [ABSTRACT FROM AUTHOR]

Published

2022

15. Estimation in Poisson Noise: Properties of the Conditional Mean Estimator.

Author

Dytso, Alex and Vincent Poor, H.

Subjects

CONDITIONAL expectations, RANDOM variables, NOISE, PROBABILITY density function, ESTIMATION theory

Abstract

This paper considers estimation of a random variable in Poisson noise with signal scaling coefficient and dark current as explicit parameters of the noise model. Specifically, the paper focuses on properties of the conditional mean estimator as a function of the scaling coefficient, the dark current parameter, the distribution of the input random variable and channel realizations. With respect to the scaling coefficient and the dark current, several identities in terms of derivatives are established. For example, it is shown that the gradient of the conditional mean estimator with respect to the scaling coefficient and dark current parameter is proportional to the conditional variance. Moreover, a score function is proposed and a Tweedie-like formula for the conditional expectation is recovered. With respect to the distribution, several regularity conditions are shown. For instance, it is shown that the conditional mean estimator uniquely determines the input distribution. Moreover, it is shown that if the conditional expectation is close to a linear function in terms of mean squared error, then the input distribution is approximately gamma in the Lévy distance. Furthermore, sufficient and necessary conditions for linearity are found. Interestingly, it is shown that the conditional mean estimator cannot be linear when the dark current parameter of the Poisson noise is non-zero. [ABSTRACT FROM AUTHOR]

Published

2020

16. Capacity Scaling of Massive MIMO in Strong Spatial Correlation Regimes.

Author

Nam, Junyoung, Caire, Giuseppe, Debbah, Merouane, and Poor, H. Vincent

Subjects

MIMO systems, INTERFERENCE suppression, COVARIANCE matrices, CHANNEL estimation, RANDOM matrices

Abstract

This paper investigates the capacity scaling of multicell massive MIMO systems in the presence of spatially correlated fading. In particular, we focus on the strong spatial correlation regimes where the covariance matrix of each user channel vector has a rank that scales sublinearly with the number of base station antennas, as the latter grows to infinity. We also consider the case where the covariance eigenvectors corresponding to the non-zero eigenvalues span randomly selected subspaces. For this channel model, referred to as the “random sparse angular support” model, we characterize the asymptotic capacity scaling law in the limit of large number of antennas. To achieve the asymptotic capacity results, statistical spatial despreading based on the second-order channel statistics plays a pivotal role in terms of pilot decontamination and interference suppression. A remarkable result is that even when the number of users scales linearly with base station antennas, a linear growth of the capacity with respect to the number of antennas is achievable under the sparse angular support model. We also note that the achievable rate lower bound based on massive MIMO “channel hardening”, widely used in the massive MIMO literature, yields rather loose results in the strong spatial correlation regimes and may significantly underestimate the achievable rate of massive MIMO. This work therefore considers an alternative bounding technique which is better suited to the strong correlation regimes. In fading channels with sparse angular support, it is further shown that spatial despreading (spreading) in uplink (downlink) has a more prominent impact on the performance of massive MIMO than channel hardening. [ABSTRACT FROM AUTHOR]

Published

2020

17. Spatial CSIT Allocation Policies for Network MIMO Channels.

Author

de Kerret, Paul and Gesbert, David

Subjects

RESOURCE management, MIMO systems, SIGNAL-to-noise ratio, CHANNEL estimation, PARAMETERIZATION

Abstract

In this paper, we study the problem of the optimal dissemination of channel state information (CSI) among $K$ spatially distributed transmitters (TXs) jointly cooperating to serve $K$ receivers. One of the particularities of this paper lies in the fact that the CSI is distributed in the sense that each TX obtains its own estimate of the global multiuser MIMO channel with no further exchange of information being allowed between the TXs. Although this is well suited to model the cooperation between noncolocated TXs, e.g., in cellular coordinated multipoint schemes, this type of setting has received little attention so far in the information theoretic society. We study in this paper what are the CSI requirements at every TX, as a function of the network geometry, to ensure that the maximal number of degrees-of-freedom (DoF) is achieved, i.e., the same DoF as obtained under perfect CSI at all TXs. We advocate the use of the generalized DoF to take into account the geometry of the network in the analysis. Consistent with the intuition, the derived generalized DoF maximizing CSI allocation policy suggests that TX cooperation should be limited to a specific finite neighborhood around each TX. This is in sharp contrast with the conventional (uniform) CSI dissemination policy, which induces CSI requirements that grow unbounded with the network size. The proposed CSI allocation policy suggests an alternative to clustering, which overcomes fundamental limitations, such as: 1) edge interference and 2) unbounded increase of the CSIT requirements with the cluster size. Finally, we show how finite neighborhood CSIT exchange translates into finite neighborhood message exchange so that finally global interference management is possible at finite SNR with only local cooperation. [ABSTRACT FROM AUTHOR]

Published

2014

18. Analysis of Mismatched Estimation Errors Using Gradients of Partition Functions.

Author

Huleihel, Wasim and Merhav, Neri

Subjects

SIGNAL denoising, SIGNAL processing, MEAN square algorithms, SUM of squares, GAUSSIAN processes, GAUSSIAN function

Abstract

We consider the problem of signal estimation (denoising) from a statistical-mechanical perspective, in continuation to a recent work on the analysis of mean-square error (MSE) estimation using a direct relationship between optimum estimation and certain partition functions. This paper consists of essentially two parts. In the first part, using the aforementioned relationship, we derive single-letter expressions of the asymptotic mismatched MSE of a codeword (from a randomly selected code), corrupted by a Gaussian vector channel. In the second part, we provide several examples to demonstrate phase transitions in the behavior of the MSE. These examples enable us to understand more deeply and to gather intuition regarding the roles of the real and the mismatched probability measures in creating these phase transitions. [ABSTRACT FROM PUBLISHER]

Published

2014

19. Fundamental Limits of Cache-Aided Wireless BC: Interplay of Coded-Caching and CSIT Feedback.

Author

Zhang, Jingjing and Elia, Petros

Subjects

WIRELESS communications, DEGREES of freedom, BROADCAST channels, TRANSMITTERS (Communication), ELECTRIC interference

Abstract

Building on the recent coded-caching breakthrough by Maddah-Ali and Niesen, the work here considers the $K$ -user cache-aided wireless multi-antenna symmetric broadcast channel with random fading and imperfect feedback, and analyzes the throughput performance as a function of feedback statistics and cache size. In this setting, this paper identifies the optimal cache-aided degrees-of-freedom (DoF) within a factor of 4, by identifying near-optimal schemes that exploit a new synergy between coded caching and delayed CSIT, as well as by exploiting the unexplored interplay between caching and feedback-quality. The DoF expressions reveal an initial gain due to current CSIT, and an additional gain due to coded caching, which is exponential in the sense that any linear decrease in the required DoF performance, allows for an exponential reduction in the required cache size. In the end, this paper reveals three new aspects of caching: a synergy between memory and delayed feedback, a tradeoff between memory and current CSIT, and a powerful ability to provide cache-aided feedback savings. [ABSTRACT FROM PUBLISHER]

Published

2017

20. Performance Analysis of Likelihood-Based Multiple Access for Detection Over Fading Channels.

Author

Cohen, Kobi and Leshem, Amir

Subjects

RADIO transmitter fading, MULTIPLE access protocols (Computer network protocols), WIRELESS sensor networks, ANALOG electronic systems, FINITE element method, MARKOV processes

Abstract

In this paper, we consider the binary hypothesis testing problem using wireless sensor networks. We analyze the case where sensors transmit their local log-likelihood ratio (LLR) directly to a fusion center (FC) using an analog transmission scheme over multiple-access fading channels. Due to the nature of the wireless medium, the FC receives a superposition of sensor transmissions. The decision is made by the FC and is based on received data from the sensors. In contrast to the case of identical channels and i.i.d observations, the analog transmission of the LLR over multiple-access fading channels does not achieve the centralized error exponent. Large deviation tools are used in this paper to characterize the error exponent in the asymptotic regime (when the number of sensors approaches infinity) in the case of non-i.i.d observations and non-i.i.d fading channels. Chernoff bounding techniques are used to provide bounds on the error probability for a finite number of sensors when the observations and the fading channels are independent across sensors. Specific performance analysis is provided for detection over both i.i.d and spatially correlated Markovian fading channels. Simulation results then illustrate the detector's performance. [ABSTRACT FROM PUBLISHER]

Published

2013

21. Energy-Efficient Full Diversity Collaborative Unitary Space-Time Block Code Designs via Unique Factorization of Signals.

Author

Xia, Dong, Zhang, Jian-Kang, and Dumitrescu, Sorina

Subjects

ENERGY consumption, UNITARY groups, SPACETIME, BLOCK codes, UNIQUE factorization domains, ESTIMATION theory, EUCLIDEAN distance

Abstract

In this paper, a novel concept called a uniquely factorable constellation pair (UFCP) is proposed for the systematic design of a noncoherent full diversity collaborative unitary space-time block code by normalizing two Alamouti codes for a wireless communication system having two transmitter antennas and a single receiver antenna. It is proved that such a unitary UFCP code assures the unique identification of both channel coefficients and transmitted signals in a noise-free case as well as full diversity for the noncoherent maximum likelihood receiver in a noise case. To further improve error performance, an optimal unitary UFCP code is designed by appropriately and uniquely factorizing a pair of energy-efficient cross quadrature amplitude modulation (QAM) constellations to maximize the coding gain subject to a transmission bit rate constraint. After a deep investigation of the fractional coding gain function, a technical approach developed in this paper to maximizing the coding gain is to carefully design an energy scale to compress the first three largest energy points in the corner of the QAM constellations in the denominator of the objective as well as carefully design a constellation triple forming two UFCPs, with one collaborating with the other two so as to make the accumulated minimum Euclidean distance along the two transmitter antennas in the numerator of the objective as large as possible, and at the same time, to avoid as many corner points of the QAM constellations with the largest energy as possible to achieve the minimum of the numerator. In other words, the optimal coding gain is attained by intelligent constellations collaboration and efficient energy compression. Computer simulations demonstrate that error performance of the optimal unitary UFCP code presented in this paper outperforms those of the differential code and the signal-to-noise-ratio-efficient training code. [ABSTRACT FROM AUTHOR]

Published

2013

22. Asymptotically Achieving Centralized Rate on the Decentralized Network MISO Channel.

Author

Bazco-Nogueras, Antonio, De Kerret, Paul, Gesbert, David, and Gresset, Nicolas

Subjects

TRANSMITTERS (Communication), TRANSMITTING antennas, MISO, SPACE-time block codes, CHANNEL estimation, SIGNAL-to-noise ratio

Abstract

In this paper, we analyze the high-SNR regime of the $M\times K$ Network MISO channel in which each transmitter has access to a different channel estimate, possibly with different precision. It has been recently shown that, for some regimes, this setting attains the same Degrees-of-Freedom as the ideal centralized setting with perfect Channel State Information (CSI) sharing, in which all the transmitters are endowed with the best estimate available at any transmitter. This result is restricted by the limitations of the Degrees-of-Freedom metric, as it only provides information about the slope of growth of the capacity as a function of the SNR, without any insight about the possible performance at a given SNR. In order to overcome this limitation, we analyze the affine approximation of the rate on the high-SNR regime for this decentralized Network MISO setting for the antenna configurations in which it achieves the Degrees-of-Freedom of the centralized setting. We show that, for a regime of antenna configurations, it is possible to asymptotically attain the same achievable rate as in the ideal centralized scenario. Consequently, it is possible to achieve the beamforming gain of the ideal perfect-CSI-sharing setting even if only a subset of transmitters is endowed with precise CSI, which can be exploited in scenarios such as distributed massive MIMO where the number of transmit antennas is much bigger than the number of served users. This outcome is a consequence of the synergistic compromise between CSI precision at the transmitters and consistency between the locally-computed precoders, which is an inherent trade-off of decentralized settings that does not exist in the centralized CSI configuration. We propose a precoding scheme achieving the previous result, which is built on an uneven structure in which some transmitters reduce the precision of their own precoding vector for the sake of using transmission parameters that can be more easily predicted by the other transmitters. [ABSTRACT FROM AUTHOR]

Published

2022

23. Erasure/List Random Coding Error Exponents Are Not Universally Achievable.

Author

Huleihel, Wasim, Weinberger, Nir, and Merhav, Neri

Subjects

UNIVERSAL design, RANDOM codes (Coding theory), CHEBYSHEV approximation, THEORY of knowledge

Abstract

We study the problem of universal decoding for unknown discrete memoryless channels in the presence of erasure/list option at the decoder, in the random coding regime. In particular, we harness a universal version of Forney’s classical erasure/list decoder developed in earlier studies, which is based on the competitive minimax methodology, and guarantees universal achievability of a certain fraction of the optimum random coding error exponents. In this paper, we derive an exact single-letter expression for the maximum achievable fraction. Examples are given in which the maximal achievable fraction is strictly less than unity, which imply that, in general, there is no universal erasure/list decoder, which achieves the same random coding error exponents as the optimal decoder for a known channel. This is in contrast to the situation in ordinary decoding (without the erasure/list option), where optimum exponents are universally achievable, as is well known. It is also demonstrated that previous lower bounds derived for the maximal achievable fraction are not tight in general. We then analyze a generalized random coding ensemble, which incorporate a training sequence, in conjunction with a suboptimal practical decoder (“plug-in” decoder), which first estimates the channel using the available training sequence, and then decodes the remaining symbols of the codeword using the estimated channel. One of the implications of our results is setting the stage for a reasonable criterion of optimal training. Finally, we compare the performance of the “plug-in” decoder and the universal decoder, in terms of the achievable error exponents, and show that the latter is noticeably better than the former. [ABSTRACT FROM AUTHOR]

Published

2016

24. Physical-Layer Security in TDD Massive MIMO.

Author

Basciftci, Yuksel Ozan, Koksal, Can Emre, and Ashikhmin, Alexei

Subjects

MIMO systems, INTERNET security, EAVESDROPPING, INFORMATION-theoretic security, PHYSICAL layer security

Abstract

We consider a single-cell downlink time-division duplex-based massive MIMO communication in the presence of an adversary capable of jamming and eavesdropping simultaneously. We show that the massive MIMO communication is naturally resilient to no training-phase jamming attack in which the adversary jams only the data communication and eavesdrops both the data communication and the training. Specifically, we show that the secure degrees of freedom (SDoF) attained in the presence of such an attack are identical to the maximum DoF attainable under no attack. Furthermore, we evaluate the number of base station (BS) antennas necessary in order to establish information theoretic security without even a need for Wyner encoding for a given rate of information leakage to the attacker. Next, we show that things are completely different once the adversary starts jamming the training phase. Specifically, we consider the pilot contamination attack, called training-phase jamming in which the adversary jams and eavesdrops both the training and the data communication. We show that under such an attack, the maximum achieved SDoF is identical to zero. Furthermore, the maximum achievable secure rates of users also vanish, even in the asymptotic regime in the number of the BS antennas. We finally address this attack and show that, under training-phase jamming, if the number of pilot signals is scaled in a certain way and the pilot signal assignments can be hidden from the adversary, the users achieve an SDoF identical to the maximum achievable DoF under no attack. [ABSTRACT FROM AUTHOR]

Published

2018

25. Leveraging Diversity and Sparsity in Blind Deconvolution.

Author

Ahmed, Ali and Demanet, Laurent

Subjects

SPARSE approximations, FOURIER analysis, DECONVOLUTION (Mathematics), IMAGE analysis, SIGNAL processing

Abstract

This paper considers recovering L -dimensional vectors {w} , and {x}_{1}, {x}_{2}, \ldots, {x}_{N} from their circular convolutions yn = {w}* {x}n, \,\,n = 1,2,3, \ldots, N . The vector {w} is assumed to be S -sparse in a known basis that is spread out in the Fourier domain, and each input {x}_{n} is a member of a known K -dimensional random subspace. We prove that whenever K + S\log ^2S \lesssim L /\log ^4(LN) , the problem can be solved effectively by using only the nuclear-norm minimization as the convex relaxation, as long as the inputs are sufficiently diverse and obey N \gtrsim \log ^2(LN) . By “diverse inputs,” we mean that the xn ’s belong to different, generic subspaces. To the best of our knowledge, this is the first theoretical result on blind deconvolution where the subspace to which w belongs is not fixed but needs to be determined. We discuss the result in the context of multipath channel estimation in wireless communications. Both the fading coefficients and the delays in the channel impulse response w are unknown. The encoder codes the K -dimensional message vectors randomly and then transmits coded messages (K+S\log ^{2}S)\log ^{4}(LN) , and the number of messages is roughly at least \log ^{2}(LN)$ . [ABSTRACT FROM PUBLISHER]

Published

2018

26. Optimal Odd-Length Binary Z-Complementary Pairs.

Author

Liu, Zilong, Parampalli, Udaya, and Guan, Yong Liang

Subjects

GOLAY codes, MULTIPLE access protocols (Computer network protocols), CHANNEL estimation, ASYNCHRONOUS circuits, AUTOCORRELATION (Statistics), PHASE shift (Nuclear physics)

Abstract

A pair of sequences is called a Golay complementary pair (GCP) if their aperiodic autocorrelation sums are zero for all out-of-phase time shifts. Existing known binary GCPs only have even-lengths in the form of \(2^\alpha 10^\beta 26^\gamma \) (where \(\alpha ,\beta ,\gamma \) are nonnegative integers). To fill the gap left by the odd-lengths, we investigate the optimal odd-length binary (OB) pairs, which display the closest correlation property to that of GCPs. Our criteria of closeness is that each pair has the maximum possible zero-correlation zone (ZCZ) width and minimum possible out-of-zone aperiodic autocorrelation sums. Such optimal pairs are called optimal OB Z-complementary pairs (OB-ZCP) in this paper. We show that each optimal OB-ZCP has maximum ZCZ width of \((N+1)/2\) , and minimum out-of-zone aperiodic sum magnitude of 2, where \(N\) denotes the sequence length (odd). Systematic constructions of such optimal OP-ZCPs are proposed by insertion and deletion of certain binary GCPs, which settle the 2011 Li–Fan–Tang–Tu open problem positively. The proposed optimal OB-ZCPs may serve as a replacement for GCPs in many engineering applications, where odd sequence lengths are preferred. In addition, they give rise to a new family of base-two almost difference families, which are useful in studying partially balanced incomplete block design. [ABSTRACT FROM AUTHOR]

Published

2014

27. Base Station Cooperation With Feedback Optimization: A Large System Analysis.

Author

Muharar, Rusdha, Zakhour, Randa, and Evans, Jamie

Subjects

SYSTEM analysis, SIGNAL-to-noise ratio, MIMO systems, ANTENNAS (Electronics), CHANNEL estimation, WIRELESS communications, CODING theory

Abstract

In this paper, we study feedback optimization problems that maximize the users' signal to interference plus noise ratio (SINR) in a two-cell multiple-input multiple-output broadcast channel. Assuming the users learn their direct and interfering channels perfectly, they can feed back this information to the base stations (BSs) over the uplink channels. The BSs then use the channel information to design their transmission scheme. Two types of feedback are considered: 1) analog and 2) digital. In the analog feedback case, the users send their unquantized and uncoded channel state information (CSI) over the uplink channels. In this context, given a user's fixed transmit power, we investigate how he/she should optimally allocate it to feed back the direct and interfering (or cross) CSI for two types of BS cooperation schemes, namely, multicell processing (MCP) and coordinated beamforming. In the digital feedback case, the direct and cross link channel vectors of each user are quantized separately, each using the random vector quantization scheme, with different size codebooks. The users then send the index of the quantization vector in the corresponding codebook to the BSs. Similar to the feedback optimization problem for the analog feedback, we investigate the optimal bit partitioning for the direct and interfering link for both types of cooperation. We focus on regularized channel inversion precoding structures and perform our analysis in the large system limit in which the number of users per cell $(K)$ and the number of antennas per BS (N)$ tend to infinity with their ratio \beta=({K}/{N}) held fixed. We show that for both types of cooperation, for some values of interfering channel gain, usually at low values, no cooperation between the BSs is preferred. This is because, for these values of cross channel gain, the channel estimates for the cross link are not accurate enough for their knowledge to contribute to improving the SINR and there is no benefit in doing BS cooperation under that condition. We also show that for the MCP scheme, unlike in the perfect CSI case, the SINR improves only when the interfering channel gain is above a certain threshold. [ABSTRACT FROM PUBLISHER]

Published

2014

28. A Single-Letter Upper Bound to the Mismatch Capacity.

Author

Asadi Kangarshahi, Ehsan and Guillen i Fabregas, Albert

Subjects

ERROR probability, MAXIMUM likelihood statistics, CHANNEL estimation, DECODING algorithms, INFINITY (Mathematics)

Abstract

We derive a single-letter upper bound to the mismatched-decoding capacity for discrete memoryless channels. The bound is expressed as the mutual information of a transformation of the channel, such that a maximum-likelihood decoding error on the translated channel implies a mismatched-decoding error in the original channel. In particular, it is shown that if the rate exceeds the upper-bound, the probability of error tends to one exponentially when the block-length tends to infinity. We also show that the underlying optimization problem is a convex-concave problem and that an efficient iterative algorithm converges to the optimal solution. In addition, we show that, unlike achievable rates in the literature, the multiletter version of the bound cannot not improve. A number of examples are discussed throughout the paper. [ABSTRACT FROM AUTHOR]

Published

2021

29. Coded Caching With Nonuniform Demands.

Author

Niesen, Urs and Maddah-Ali, Mohammad Ali

Subjects

CHANNEL coding, CACHE memory, COMPUTER algorithms, DECODERS & decoding, CHANNEL estimation

Abstract

We consider a network consisting of a file server connected through a shared link to a number of users, each equipped with a cache. Knowing the popularity distribution of the files, the goal is to optimally populate the caches, such as to minimize the expected load of the shared link. For a single cache, it is well known that storing the most popular files is optimal in this setting. However, we show here that this is no longer the case for multiple caches. Indeed, caching only the most popular files can be highly suboptimal. Instead, a fundamentally different approach is needed, in which the cache contents are used as side information for coded communication over the shared link. We propose such a coded caching scheme and prove that it is close to optimal. [ABSTRACT FROM AUTHOR]

Published

2017

30. Coding for Secure Write-Efficient Memories.

Author

Li, Qing and Jiang, Anxiao Andrew

Subjects

REWRITING systems (Computer science), NONVOLATILE memory, DECODERS & decoding, MEMORYLESS systems, COST functions, HAMMING distance

Abstract

Non-volatile memories suffer from two challenges due to their physical and system-level constraints. One challenge is limited memory lifetime, also called the endurance problem. The other is the difficulty in deleting data securely, called the insecure deletion problem. This paper proposes a coding scheme that addresses both challenges jointly. It studies the secure write-efficient memory (WEM) by analyzing its rewriting-rate equivocation region and secrecy rewriting capacity. It also presents an optimal code construction for a large family of secure WEM channels. [ABSTRACT FROM AUTHOR]

Published

2017

31. Fundamental Limits of Cooperation.

Author

Lozano, Angel, Heath, Robert W., and Andrews, Jeffrey G.

Subjects

INTERFERENCE (Telecommunication), CHANNEL estimation, POWER transmission, CELL phone systems, WIRELESS communications, BANDWIDTHS

Abstract

Cooperation is viewed as a key ingredient for interference management in wireless networks. This paper shows that cooperation has fundamental limitations. First, it is established that in systems that rely on pilot-assisted channel estimation, the spectral efficiency is upper-bounded by a quantity that does not depend on the transmit powers; in this framework, cooperation is possible only within clusters of limited size, which are subject to out-of-cluster interference whose power scales with that of the in-cluster signals. Second, an upper bound is also shown to exist if the cooperation extends to an entire (large) system operating as a single cluster; here, pilot-assisted transmission is necessarily transcended. Altogether, it is concluded that cooperation cannot in general change an interference-limited network to a noise-limited one. Consequently, the existing literature that routinely assumes that the high-power spectral efficiency scales with the log-scale transmit power provides only a partial characterization. The complete characterization proposed in this paper subdivides the high-power regime into a degree-of-freedom regime, where the scaling with the log-scale transmit power holds approximately, and a saturation regime, where the spectral efficiency hits a ceiling that is independent of the power. Using a cellular system as an example, it is demonstrated that the spectral efficiency saturates at power levels of operational relevance. [ABSTRACT FROM AUTHOR]

Published

2013

32. Extension of the Blahut–Arimoto Algorithm for Maximizing Directed Information.

Author

Naiss, Iddo and Permuter, Haim H.

Subjects

MASSEY products, COMPUTER algorithms, PROBABILITY theory, INFORMATION science, COMPUTER engineering

Abstract

In this paper, we extend the Blahut–Arimoto algorithm for maximizing Massey's directed information. The algorithm can be used for estimating the capacity of channels with delayed feedback, where the feedback is a deterministic function of the output. In order to maximize the directed information, we apply the ideas from the regular Blahut–Arimoto algorithm, i.e., the alternating maximization procedure, to our new problem. We provide both upper and lower bound sequences that converge to the optimum global value. Our main insight in this paper is that in order to find the maximum of the directed information over a causal conditioning probability mass function, one can use a backward index time maximization combined with the alternating maximization procedure. We give a detailed description of the algorithm, showing its complexity and the memory needed, and present several numerical examples. [ABSTRACT FROM AUTHOR]

Published

2013

33. Optimal Joint Channel Estimation and Data Detection for Massive SIMO Wireless Systems: A Polynomial Complexity Solution.

Author

Xu, Weiyu, Alshamary, Haider Ali, Al-Naffouri, Tareq, and Zaib, Alam

Subjects

CHANNEL estimation, ANTENNA arrays, LIKELIHOOD ratio tests, RECEIVING antennas, MIMO systems, COMPUTATIONAL complexity, POLYNOMIALS, WIRELESS channels

Abstract

By exploiting large antenna arrays, massive MIMO (multiple input multiple output) systems can greatly increase spectral and energy efficiency over traditional MIMO systems. However, increasing the number of antennas at the base station (BS) makes the uplink joint channel estimation and data detection (JED) challenging in massive MIMO systems. In this paper, we consider the JED problem for massive SIMO (single input multiple output) wireless systems, which is a special case of wireless systems with large antenna arrays. We propose exact Generalized Likelihood Ratio Test (GLRT) optimal JED algorithms with low expected complexity, for both constant-modulus and nonconstant-modulus constellations. We show that, despite the large number of unknown channel coefficients, the expected computational complexity of these algorithms is polynomial in channel coherence time ($T$) and the number of receive antennas ($N$), even when the number of receive antennas grows polynomially in the channel coherence time ($N=O(T^{11})$ suffices to guarantee an expected computational complexity cubic in $T$ and linear in $N$). Simulation results show that the GLRT-optimal JED algorithms achieve significant performance gains (up to 5 dB improvement in energy efficiency) with low computational complexity. [ABSTRACT FROM AUTHOR]

Published

2020

34. Sampling of the Wiener Process for Remote Estimation Over a Channel With Random Delay.

Author

Sun, Yin, Polyanskiy, Yury, and Uysal, Elif

Subjects

WIENER processes, CHANNEL estimation, SAMPLING (Process), INFORMATION society, SAMPLING errors, ADAPTIVE sampling (Statistics)

Abstract

In this paper, we consider a problem of sampling a Wiener process, with samples forwarded to a remote estimator over a channel that is modeled as a queue. The estimator reconstructs an estimate of the real-time signal value from causally received samples. We study the optimal online sampling strategy that minimizes the mean square estimation error subject to a sampling rate constraint. We prove that the optimal sampling strategy is a threshold policy, and find the optimal threshold. This threshold is determined by how much the Wiener process varies during the random service time and the maximum allowed sampling rate. Further, if the sampling times are independent of the observed Wiener process, the above sampling problem for minimizing the estimation error is equivalent to a sampling problem for minimizing the age of information. This reveals an interesting connection between the age of information and remote estimation error. Our comparisons show that the estimation error achieved by the optimal sampling policy can be much smaller than those of age-optimal sampling, zero-wait sampling, and periodic sampling. [ABSTRACT FROM AUTHOR]

Published

2020

35. Extensions of the I-MMSE Relationship to Gaussian Channels With Feedback and Memory.

Author

Han, Guangyue and Song, Jian

Subjects

GAUSSIAN channels, INFORMATION theory, FEEDBACK control systems, MATHEMATICAL models, MATHEMATICAL inequalities, TELECOMMUNICATION channels

Abstract

Unveiling a fundamental link between information theory and estimation theory, the I-MMSE relationship by Guo et al., together with its numerous extensions, has great theoretical significance and various practical applications. On the other hand, its influences to date have been restricted to channels without feedback or memory, due to the absence of its extensions to such channels. In this paper, we propose the extensions of the I-MMSE relationship to discrete-time and continuous-time Gaussian channels with feedback and/or memory. Our approach is based on a very simple observation, which can be applied to other scenarios, such as a simple and direct proof of the classical de Bruijn’s identity. [ABSTRACT FROM AUTHOR]

Published

2016

36. Minimax Estimation of Functionals of Discrete Distributions.

Author

Jiao, Jiantao, Venkat, Kartik, Han, Yanjun, and Weissman, Tsachy

Subjects

CHANNEL estimation, DISCRETE uniform distribution, MAXIMUM likelihood statistics, POLYNOMIAL approximation, COMPUTATIONAL complexity

Abstract

We propose a general methodology for the construction and analysis of essentially minimax estimators for a wide class of functionals of finite dimensional parameters, and elaborate on the case of discrete distributions, where the support size S is unknown and may be comparable with or even much larger than the number of observations n . We treat the respective regions where the functional is nonsmooth and smooth separately. In the nonsmooth regime, we apply an unbiased estimator for the best polynomial approximation of the functional whereas, in the smooth regime, we apply a bias-corrected version of the maximum likelihood estimator (MLE). We illustrate the merit of this approach by thoroughly analyzing the performance of the resulting schemes for estimating two important information measures: 1) the entropy H(P) = \sum i = 1^{S} -pi \ln pi and 2) F_\alpha (P) = \sum i = 1^{S} pi^\alpha ,\alpha >0 . We obtain the minimax L2 rates for estimating these functionals. In particular, we demonstrate that our estimator achieves the optimal sample complexity n \asymp S/\ln S for entropy estimation. We also demonstrate that the sample complexity for estimating F_\alpha (P),0<\alpha <1 , is n\asymp S^1/\alpha / \ln S , which can be achieved by our estimator but not the MLE. For 1<\alpha <3/2 , we show the minimax L2 rate for estimating F_\alpha (P) is (n\ln n)^{-2(\alpha -1)} for infinite support size, while the maximum L2 rate for the MLE is n^{-2(\alpha -1^{^{^{}}})}$ . For all the above cases, the behavior of the minimax rate-optimal estimators with $n$ samples is essentially that of the MLE (plug-in rule) with $n\ln n$ samples, which we term “effective sample size enlargement.” We highlight the practical advantages of our schemes for the estimation of entropy and mutual information. We compare our performance with various existing approaches, and demonstrate that our approach reduces running time and boosts the accuracy. Moreover, we show that the minimax rate-optimal mutual information estimator yielded by our framework leads to significant performance boosts over the Chow–Liu algorithm in learning graphical models. The wide use of information measure estimation suggests that the insights and estimators obtained in this paper could be broadly applicable. [ABSTRACT FROM PUBLISHER]

Published

2015

37. Backing Off From Infinity: Performance Bounds via Concentration of Spectral Measure for Random MIMO Channels.

Author

Chen, Yuxin, Goldsmith, Andrea J., and Eldar, Yonina C.

Subjects

MIMO systems, RANDOM matrices, CHANNEL capacity (Telecommunications), SIGNAL processing, CHANNEL coding

Abstract

The performance analysis of random vector channels, particularly multiple-input-multiple-output (MIMO) channels, has largely been established in the asymptotic regime of large channel dimensions, due to the analytical intractability of characterizing the exact distribution of the objective performance metrics. This paper exposes a new nonasymptotic framework that allows the characterization of many canonical MIMO system performance metrics to within a narrow interval under finite channel dimensionality, provided that these metrics can be expressed as a separable function of the singular values of the matrix. The effectiveness of our framework is illustrated through two canonical examples. In particular, we characterize the mutual information and power offset of random MIMO channels, as well as the minimum mean squared estimation error of MIMO channel inputs from the channel outputs. Our results lead to simple, informative, and reasonably accurate control of various performance metrics in the finite-dimensional regime, as corroborated by the numerical simulations. Our analysis framework is established via the concentration of spectral measure phenomenon for random matrices uncovered by Guionnet and Zeitouni, which arises in a variety of random matrix ensembles irrespective of the precise distributions of the matrix entries. [ABSTRACT FROM PUBLISHER]

Published

2015

38. Massive MIMO Systems With Non-Ideal Hardware: Energy Efficiency, Estimation, and Capacity Limits.

Author

Bjornson, Emil, Hoydis, Jakob, Kountouris, Marios, and Debbah, Merouane

Subjects

MIMO systems, ENERGY consumption, ESTIMATION theory, ANTENNAS (Electronics), INFORMATION theory

Abstract

The use of large-scale antenna arrays can bring substantial improvements in energy and/or spectral efficiency to wireless systems due to the greatly improved spatial resolution and array gain. Recent works in the field of massive multiple-input multiple-output (MIMO) show that the user channels decorrelate when the number of antennas at the base stations (BSs) increases, thus strong signal gains are achievable with little interuser interference. Since these results rely on asymptotics, it is important to investigate whether the conventional system models are reasonable in this asymptotic regime. This paper considers a new system model that incorporates general transceiver hardware impairments at both the BSs (equipped with large antenna arrays) and the single-antenna user equipments (UEs). As opposed to the conventional case of ideal hardware, we show that hardware impairments create finite ceilings on the channel estimation accuracy and on the downlink/uplink capacity of each UE. Surprisingly, the capacity is mainly limited by the hardware at the UE, while the impact of impairments in the large-scale arrays vanishes asymptotically and interuser interference (in particular, pilot contamination) becomes negligible. Furthermore, we prove that the huge degrees of freedom offered by massive MIMO can be used to reduce the transmit power and/or to tolerate larger hardware impairments, which allows for the use of inexpensive and energy-efficient antenna elements. [ABSTRACT FROM PUBLISHER]

Published

2014

39. Toward the Performance Versus Feedback Tradeoff for the Two-User MISO Broadcast Channel.

Author

Chen, Jinyuan and Elia, Petros

Subjects

WIRELESS communications, COHERENCE (Physics), SIGNAL processing, DECODING algorithms, RADIO transmitter fading

Abstract

For the two-user MISO broadcast channel with imperfect and delayed channel state information at the transmitter (CSIT), the work explores the tradeoff between performance on the one hand, and CSIT timeliness and accuracy on the other hand. This paper considers a broad setting where communication takes place in the presence of a random fading process, and in the presence of a feedback process that, at any point in time, may provide CSIT estimates—of some arbitrary accuracy—for any past, current or future channel realization. This feedback quality may fluctuate in time across all ranges of CSIT accuracy and timeliness, ranging from perfectly accurate and instantaneously available estimates, to delayed estimates of minimal accuracy. Under standard assumptions, the work derives the degrees-of-freedom (DoF) region, which is tight for a large range of CSIT quality. This derived DoF region concisely captures the effect of channel correlations, the accuracy of predicted, current, and delayed-CSIT, and generally captures the effect of the quality of CSIT offered at any time, about any channel. This paper also introduces novel schemes which—in the context of imperfect and delayed CSIT—employ encoding and decoding with a phase-Markov structure. The results hold for a large class of block and nonblock fading channel models, and they unify and extend many prior attempts to capture the effect of imperfect and delayed feedback. This generality also allows for consideration of novel pertinent settings, such as the new periodically evolving feedback setting, where a gradual accumulation of feedback bits progressively improves CSIT as time progresses across a finite coherence period. [ABSTRACT FROM PUBLISHER]

Published

2013

40. On Optimal Coding of Non-Linear Dynamical Systems.

Author

Kawan, Christoph and Yuksel, Serdar

Subjects

SOURCE code, OBSERVABILITY (Control theory), NONLINEAR dynamical systems, TOPOLOGICAL entropy, INFORMATION theory

Abstract

We consider the problem of zero-delay coding of a dynamical system over a discrete noiseless channel under three estimation criteria concerned with the low-distortion regime. For these three criteria, formulated stochastically in terms of a probability distribution for the initial state, we characterize the smallest channel capacities above which the estimation objectives can be achieved. The results establish further connections between topological and metric entropies of dynamical systems and information theory. [ABSTRACT FROM AUTHOR]

Published

2018

41. Fast and Guaranteed Blind Multichannel Deconvolution Under a Bilinear System Model.

Author

Lee, Kiryung, Tian, Ning, and Romberg, Justin

Subjects

BILINEAR forms, DECONVOLUTION (Mathematics), SENSITIVITY analysis, EIGENVALUE equations, MATHEMATICAL optimization

Abstract

We consider the multichannel blind deconvolution problem where we observe the output of multiple channels that are all excited with the same unknown input. From these observations, we wish to estimate the impulse responses of each of the channels. We show that this problem is well-posed if the channels follow a bilinear model where the ensemble of channel responses is modeled as lying in a low-dimensional subspace but with each channel modulated by an independent gain. Under this model, we show how the channel estimates can be found by minimizing a quadratic function over a non-convex set. We analyze two methods for solving this non-convex program, and provide performance guarantees for each. The first is a method of alternating eigenvectors that breaks the program down into a series of eigenvalue problems. The second is a truncated power iteration, which can roughly be interpreted as a method for finding the largest eigenvector of a symmetric matrix with the additional constraint that it adheres to our bilinear model. As with most non-convex optimization algorithms, the performance of both of these algorithms is highly dependent on having a good starting point. We show how such a starting point can be constructed from the channel measurements. Our performance guarantees are non-asymptotic, and provide a sufficient condition on the number of samples observed per channel in order to guarantee channel estimates of certain accuracy. Our analysis uses a model with a “generic” subspace that is drawn at random, and we show the performance bounds hold with high probability. Mathematically, the key estimates are derived by quantifying how well the eigenvectors of certain random matrices approximate the eigenvectors of their mean. We also present a series of numerical results demonstrating that the empirical performance is consistent with the presented theory. [ABSTRACT FROM AUTHOR]

Published

2018

42. IT Formulae for Gamma Target: Mutual Information and Relative Entropy.

Author

Arras, Benjamin and Swan, Yvik

Subjects

RANDOM noise theory, SIGNAL-to-noise ratio, DE Bruijn graph, FISHER information, MATHEMATICAL statistics

Abstract

In this paper, we introduce new Stein identities for gamma target distribution as well as a new non-linear channel specifically designed for gamma inputs. From these two ingredients, we derive an explicit and simple formula for the derivative of the input-output mutual information of this non-linear channel with respect to the channel quality parameter. This relation is reminiscent of the well-known link between the derivative of the input-output mutual information of additive Gaussian noise channel with respect to the signal-to-noise ratio and the minimum mean-square error. The proof relies on a rescaled version of De Bruijn identity for gamma target distribution together with a stochastic representation for the gamma-specific Fisher information. Finally, we are able to derive precise bounds and asymptotics for the input-output mutual information of the non-linear channel with gamma inputs. [ABSTRACT FROM AUTHOR]

Published

2018

43. Delay-Doppler Channel Estimation in Almost Linear Complexity.

Author

Fish, Alexander, Gurevich, Shamgar, Hadani, Ronny, Sayeed, Akbar M., and Schwartz, Oded

Subjects

CHANNEL estimation, GLOBAL Positioning System, TIME-frequency analysis, DOPPLER effect, RADAR, ZINC

Abstract

A fundamental task in wireless communication is channel estimation: Compute the channel parameters a signal undergoes while traveling from a transmitter to a receiver. In the case of delay-Doppler channel, i.e., a signal undergoes only delay and Doppler shifts, a widely used method to compute the delay-Doppler parameters is the matched filter algorithm. It uses a pseudo-random sequence of length N, and, in case of non-trivial relative velocity between transmitter and receiver, its computational complexity is O(N^2\log N). In this paper we introduce a novel approach of designing sequences that allow faster channel estimation. Using group representation techniques we construct sequences, which enable us to introduce a new algorithm, called the flag method, that significantly improves the matched filter algorithm. The flag method finds m delay-Doppler parameters in O(mN\log N) operations. We discuss applications of the flag method to GPS, and radar systems. [ABSTRACT FROM AUTHOR]

Published

2013

44. On an Achievable Rate of Large Rayleigh Block-Fading MIMO Channels With No CSI.

Author

Takeuchi, Keigo, Muller, Ralf R., Vehkapera, Mikko, and Tanaka, Toshiyuki

Subjects

RAYLEIGH fading channels, MIMO systems, CHANNEL estimation, TELECOMMUNICATION channels, COMPUTER simulation, SIGNAL-to-noise ratio, ENCODING

Abstract

Training-based transmission over Rayleigh block-fading multiple-input multiple-output (MIMO) channels is investigated. As a training method a combination of a pilot-assisted scheme and a biased signaling scheme is considered. The achievable rates of successive decoding (SD) receivers based on the linear minimum mean-squared error (LMMSE) channel estimation are analyzed in the large-system limit, by using the replica method under the assumption of replica symmetry. It is shown that negligible pilot information is best in terms of the achievable rates of the SD receivers in the large-system limit. The obtained analytical formulas of the achievable rates can improve the existing lower bound on the capacity of the MIMO channel with no channel state information (CSI), derived by Hassibi and Hochwald, for all SNRs. The comparison between the obtained bound and a high-SNR approximation of the channel capacity, derived by Zheng and Tse, implies that the high-SNR approximation is unreliable unless quite high SNR is considered. Energy efficiency in the low-SNR regime is also investigated in terms of the power per information bit required for reliable communication. The required minimum power is shown to be achieved at a positive rate for the SD receiver with no CSI, whereas it is achieved in the zero-rate limit for the case of perfect CSI available at the receiver. Moreover, numerical simulations imply that the presented large-system analysis can provide a good approximation for not so large systems. The results in this paper imply that SD schemes can provide a significant performance gain in the low-to-moderate SNR regimes, compared to conventional receivers based on one-shot channel estimation. [ABSTRACT FROM AUTHOR]

Published

2013

45. Performance of Mutual Information Inference Methods Under Unknown Interference.

Author

Kammoun, Abla, Couillet, Romain, Najim, Jamal, and Debbah, Mérouane

Subjects

INTERFERENCE suppression, INFORMATION theory, MIMO systems, TRANSMITTERS (Communication), LIMIT theorems, GAUSSIAN channels

Abstract

In this paper, the problem of fast point-to-point multiple-input-multiple-output channel mutual information estimation is addressed, in the situation where the receiver undergoes unknown colored interference, whereas the channel with the transmitter is perfectly known. The considered scenario assumes that the estimation is based on a few channel use observations during a short sensing period. Using large dimensional random matrix theory, an estimator referred to as G-estimator is derived. This estimator is proved to be consistent as the number of antennas and observations grow large and its asymptotic performance is analyzed. In particular, the G-estimator satisfies a central limit theorem with asymptotic Gaussian fluctuations. Simulations are provided which strongly support the theoretical results, even for small system dimensions. [ABSTRACT FROM AUTHOR]

Published

2013

46. Degrees of Freedom of the Network MIMO Channel With Distributed CSI.

Author

de Kerret, Paul and Gesbert, David

Subjects

DEGREES of freedom, COMPUTER networks, MIMO systems, CRYPTOGRAPHY, SIGNAL-to-noise ratio, WIRELESS communications

Abstract

In this paper, we discuss the joint precoding with finite rate feedback in the so-called network multiple-input multiple-output (MIMO) where the TXs share the knowledge of the data symbols to be transmitted. We introduce a distributed channel state information (DCSI) model where each TX has its own local estimate of the overall multiuser MIMO channel and must make a precoding decision solely based on the available local CSI. We refer to this channel as the DCSI-MIMO channel and the precoding problem as distributed precoding. We extend to the DCSI setting the work from Jindal in 2006 for the conventional MIMO broadcast channel (BC) in which the number of degrees of freedom (DoFs) achieved by zero forcing (ZF) was derived as a function of the scaling in the logarithm of the signal-to-noise ratio of the number of quantizing bits. Particularly, we show the seemingly pessimistic result that the number of DoFs at each user is limited by the worst CSI across all users and across all TXs. This is in contrast to the conventional MIMO BC where the number of DoFs at one user is solely dependent on the quality of the estimation of his own feedback. Consequently, we provide precoding schemes improving on the achieved number of DoFs. For the two-user case, the derived novel precoder achieves a number of DoFs limited by the best CSI accuracy across the TXs instead of the worst with conventional ZF. We also advocate the use of hierarchical quantization of the CSI, for which we show that considerable gains are possible. Finally, we use the previous analysis to derive the DoFs optimal allocation of the feedback bits to the various TXs under a constraint on the size of the aggregate feedback in the network, in the case where conventional ZF is used. [ABSTRACT FROM PUBLISHER]

Published

2012

47. On the SNR Penalties of Ideal and Non-ideal Subset Diversity Systems.

Author

Gifford, Wesley M., Conti, Andrea, Chiani, Marco, and Win, Moe Z.

Subjects

SIGNAL-to-noise ratio, DIVERSITY receiving systems, RADIO transmitter fading, ESTIMATION theory, TRANSMITTING antennas, WIRELESS communications, PERFORMANCE evaluation

Abstract

Subset diversity (SSD) techniques, which select and combine the signals from a subset of the available diversity branches, are important for practical wireless systems. This paper characterizes the performance loss, or signal-to-noise ratio (SNR) penalty, of one SSD system with respect to another. Both ideal and non-ideal channel estimation are considered, and the analysis is valid for the important case of arbitrary two-dimensional signal constellations. Expressions are given for the asymptotic SNR penalty, for both small and large SNR, for all the comparisons considered. Additionally, we develop bounds and approximations to quantify the performance of one system in terms of another for all SNRs of interest. Furthermore, for some signal constellations, we derive the exact SNR penalty of a non-ideal system with respect to an ideal system, as well as the exact penalty associated with two non-ideal systems with varying degrees of estimation energy. The SNR penalty enables the assessment of system sensitivity to channel estimation energy, combining architecture, and signal constellation. [ABSTRACT FROM PUBLISHER]

Published

2012

48. On the Gain of Joint Processing of Pilot and Data Symbols in Stationary Rayleigh Fading Channels.

Author

Dorpinghaus, Meik, Ispas, Adrian, and Meyr, Heinrich

Subjects

STATIONARY processes, RAYLEIGH fading channels, MOBILE communication systems, LINE receivers (Integrated circuits), ENCODING, RELIABILITY in engineering

Abstract

In many typical mobile communication receivers, the channel is estimated based on pilot symbols to allow for a coherent detection and decoding in a separate processing step. Currently, much work is spent on receivers which break up this separation, e.g., by enhancing channel estimation based on reliability information on the data symbols. In this paper, we evaluate the possible gain of a joint processing of data and pilot symbols in comparison to the case of a separate processing in the context of stationary Rayleigh flat-fading channels. Therefore, we discuss the nature of the possible gain of a joint processing of pilot and data symbols. We show that the additional information that can be gained by a joint processing is captured in the temporal correlation of the channel estimation error of the solely pilot-based channel estimation, which is not retrieved by the channel decoder in case of separate processing. In addition, we derive a new lower bound on the achievable rate for joint processing of pilot and data symbols. Finally, the results are extended to multiple-input multiple-output channels. [ABSTRACT FROM PUBLISHER]

Published

2012

49. Large-System Analysis of Joint Channel and Data Estimation for MIMO DS-CDMA Systems.

Author

Takeuchi, Keigo, Vehkapera, Mikko, Tanaka, Toshiyuki, and Muller, Ralf R.

Subjects

CODE division multiple access, MIMO systems, MULTIUSER detection (Telecommunication), PERFORMANCE evaluation, RADIOS, ELECTRONIC data processing

Abstract

This paper presents a large-system analysis of the performance of joint channel estimation, multiuser detection, and per-user decoding (CE-MUDD) for randomly spread multiple-input multiple-output (MIMO) direct-sequence code-division multiple-access (DS-CDMA) systems. A suboptimal receiver based on successive decoding in conjunction with linear minimum mean-squared error (LMMSE) channel estimation is investigated. The replica method, developed in statistical mechanics, is used to evaluate the performance in the large-system limit, where the number of users and the spreading factor tend to infinity while their ratio and the number of transmit and receive antennas are kept constant. Joint CE-MUDD based on LMMSE channel estimation is compared to several methods of one-shot channel estimation, i.e., methods that do not utilize decoded data symbols to refine the initial channel estimates, in terms of spectral efficiency. Joint CE-MUDD is found to significantly reduce the rate loss caused by transmission of pilot signals when compared to the receivers based on one-shot channel estimation. This holds particularly for multiple-antenna systems. As a result, joint CE-MUDD can provide significant performance gains compared to the receivers based on one-shot channel estimation. [ABSTRACT FROM AUTHOR]

Published

2012

50. Spatial Interference Cancellation for Multiantenna Mobile Ad Hoc Networks.

Author

Huang, Kaibin, Andrews, Jeffrey G., Guo, Dongning, Heath, Robert W., and Berry, Randall A.

Subjects

ANTENNAS (Electronics), MOBILE communication systems, AD hoc computer networks, ELECTRIC interference, RADIO transmitter fading, DATA transmission systems, NUMERICAL analysis

Abstract

Interference between nodes is a critical impairment in mobile ad hoc networks. This paper studies the role of multiple antennas in mitigating such interference. Specifically, a network is studied in which receivers apply zero-forcing beamforming to cancel the strongest interferers. Assuming a network with Poisson-distributed transmitters and independent Rayleigh fading channels, the transmission capacity is derived, which gives the maximum number of successful transmissions per unit area. Mathematical tools from stochastic geometry are applied to obtain the asymptotic transmission capacity scaling and characterize the impact of inaccurate channel state information (CSI). It is shown that, if each node cancels L interferers, the transmission capacity decreases as \Theta \big (\epsilon ^ 1\over L+1\big) as the outage probability \epsilon vanishes. For fixed \epsilon , as L grows, the transmission capacity increases as \Theta \big (L^1- 2\over \alpha \big) where \alpha is the path-loss exponent. Moreover, CSI inaccuracy is shown to have no effect on the transmission capacity scaling as \epsilon vanishes, provided that the CSI training sequence has an appropriate length, which we derive. Numerical results suggest that canceling merely one interferer by each node may increase the transmission capacity by an order of magnitude or more, even when the CSI is imperfect. [ABSTRACT FROM AUTHOR]

Published

2012