Laila H. Afify scite author profile

Abstract-This paper addresses the problem of estimating sparse channels in massive MIMO-OFDM systems. Most wireless channels are sparse in nature with large delay spread. In addition, these channels as observed by multiple antennas in a neighborhood have approximately common support. The sparsity and common support properties are attractive when it comes to the efficient estimation of large number of channels in massive MIMO systems. Moreover, to avoid pilot contamination and to achieve better spectral efficiency, it is important to use a small number of pilots. We present a novel channel estimation approach which utilizes the sparsity and common support properties to estimate sparse channels and require a small number of pilots. Two algorithms based on this approach have been developed which perform Bayesian estimates of sparse channels even when the prior is non-Gaussian or unknown. Neighboring antennas share among each other their beliefs about the locations of active channel taps to perform estimation. The coordinated approach improves channel estimates and also reduces the required number of pilots. Further improvement is achieved by the data-aided version of the algorithm. Extensive simulation results are provided to demonstrate the performance of the proposed algorithms.

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The Influence of Gaussian Signaling Approximation on Error Performance in Cellular Networks

Afify

ElSawy

Al-Naffouri

et al. 2015

IEEE Commun. Lett.

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A Unified Stochastic Geometry Model for MIMO Cellular Networks With Retransmissions

Afify

ElSawy

Al-Naffouri

et al. 2016

IEEE Trans. Wireless Commun.

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Abstract-This paper presents a unified mathematical paradigm, based on stochastic geometry, for downlink cellular networks with multiple-input-multiple-output (MIMO) base stations (BSs). The developed paradigm accounts for signal retransmission upon decoding errors, in which the temporal correlation among the signal-to-interference-plus-noise-ratio (SINR) of the original and retransmitted signals is captured. In addition to modeling the effect of retransmission on the network performance, the developed mathematical model presents twofold analysis unification for MIMO cellular networks literature. First, it integrates the tangible decoding error probability and the abstracted (i.e., modulation scheme and receiver type agnostic) outage probability analysis, which are largely disjoint in the literature. Second, it unifies the analysis for different MIMO configurations. The unified MIMO analysis is achieved by abstracting unnecessary information conveyed within the interfering signals by Gaussian signaling approximation along with an equivalent SISO representation for the per-data stream SINR in MIMO cellular networks. We show that the proposed unification simplifies the analysis without sacrificing the model accuracy. To this end, we discuss the diversity-multiplexing tradeoff imposed by different MIMO schemes and shed light on the diversity loss due to the temporal correlation among the SINRs of the original and retransmitted signals. Finally, several design insights are highlighted.

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Error performance analysis in K-tier uplink cellular networks using a stochastic geometric approach

Afify

ElSawy

Al-Naffouri

et al. 2015

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LTE dynamic scheduling scheme for massive M2M and H2H communication

Alaa

ElAttar

Digham

et al. 2017

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Laila H. Afify

Efficient Coordinated Recovery of Sparse Channels in Massive MIMO

The Influence of Gaussian Signaling Approximation on Error Performance in Cellular Networks

A Unified Stochastic Geometry Model for MIMO Cellular Networks With Retransmissions

Error performance analysis in K-tier uplink cellular networks using a stochastic geometric approach

LTE dynamic scheduling scheme for massive M2M and H2H communication

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