Your search keyword '"Chaaban, Anas"' showing total 8 results

1. Low-SNR Asymptotic Capacity of MIMO Optical Intensity Channels With Peak and Average Constraints.

Author

Chaaban, Anas, Rezki, Zouheir, and Alouini, Mohamed-Slim

Subjects

*MIMO systems, *ANTENNAS (Electronics), *SIGNAL processing, *BANDWIDTHS, *WIRELESS communications

Abstract

The low-SNR asymptotic capacity of the multiple-input multiple-output (MIMO) optical intensity channel is studied under both average and peak intensity constraints. We focus on low SNR, which can be modeled as the scenario where both constraints proportionally vanish, or where the peak constraint is held constant while the average constraint vanishes. A capacity upper bound is derived and is shown to be tight at low SNR under both scenarios. The capacity achieving input distribution at low SNR is shown to be a maximally correlated vector-binary input distribution. Consequently, the low-SNR capacity of the channel is characterized. As a byproduct, it is shown that for a channel with peak intensity constraints only, or with peak intensity constraints and individual (per aperture) average intensity constraints, a simple scheme composed of coded ON–OFF keying, spatial repetition, and maximum-ratio combining is optimal at low SNR. [ABSTRACT FROM AUTHOR]

Published

2018

2. Fundamental Limits of Parallel Optical Wireless Channels: Capacity Results and Outage Formulation.

Author

Chaaban, Anas, Rezki, Zouheir, and Alouini, Mohamed-Slim

Subjects

*OPTICAL communications, *WIRELESS communications, *SIGNAL-to-noise ratio, *MIMO systems, *RADIO frequency

Abstract

Multi-channel (MC) optical wireless communication (OWC) systems employing wave-division multiplexing for outdoors free-space optical communications, or multi-user time-division multiple access for indoors visible-light communications, e.g., can be modeled as parallel channels. Multi-input multi-output OWC systems can also be transformed, possibly with some performance loss, to parallel channels using pre-/post-coding. Studying the performance of such MC-OWC systems requires characterizing the capacity of the underlying parallel channels. In this paper, upper and lower bounds on the capacity of constant parallel OWC channels with a total average intensity constraint are derived. Then, this paper focuses on finding intensity allocations that maximize the lower bounds given channel-state information at the transmitter (CSIT). Due to its nonconvexity, the Karush–Kuhn–Tucker conditions are used to describe a list of candidate allocations. Instead searching exhaustively for the best solution, low-complexity near-optimal algorithms are proposed. The resulting optimized lower bound nearly coincides with capacity at high signal-to-noise ratio (SNR). Under a quasi-static channel model and in the absence of CSIT, outage probability upper and lower bounds are derived. Those bounds also meet at high SNR, thus characterizing the outage capacity in this regime. Finally, the results are extended to a system with both average and peak intensity constraints. [ABSTRACT FROM PUBLISHER]

Published

2017

3. Expanded GDoF-optimality Regime of Treating Interference as Noise in the $M\times 2$ X-Channel.

Author

Gherekhloo, Soheil, Chaaban, Anas, and Sezgin, Aydin

Subjects

*INTERFERENCE (Telecommunication), *DEGREES of freedom, *GAUSSIAN channels, *BROADCAST channels, *RANDOM noise theory

Abstract

Treating interference as noise (TIN) as the most appropriate approach in dealing with interference and the conditions on its optimality has attracted the interest of researchers recently. However, our knowledge on necessary and sufficient conditions of TIN is restricted to a few setups with limited number of users. In this paper, we study the optimality of TIN in terms of the generalized degrees of freedom (GDoF) for a fundamental network, namely, the $M\times 2$ X-channel. To this end, the achievable GDoF of TIN with power allocations at the transmitters is studied. It turns out that the transmit power allocation maximizing the achievable GDOF is given by on–off signaling as long as the receivers use TIN. This leads to two variants of TIN, namely, P2P-TIN and 2-IC-TIN. While in the first variant the $M\times 2$ X-channel is reduced to a point-to-point (P2P) channel, in the second variant, the setup is reduced to a two-user interference channel in which the receivers use TIN. The optimality of these two variants is studied separately. To this end, novel genie-aided upper bounds on the capacity of the X-channel are established. The conditions on the optimality of P2P-TIN can be summarized as follows. P2P-TIN is GDoF-optimal if there exists a dominant multiple access channel or a dominant broadcast channel embedded in the X channel. Furthermore, the necessary and sufficient conditions on the GDoF-optimality of 2-IC-TIN are presented. Interestingly, it turns out that operating the $M\times 2$ X-channel in the 2-IC-TIN mode might be still GDOF optimal, although the conditions given by Geng et al. are violated. However, 2-IC-TIN is sub-optimal if there exists a single interferer which causes sufficiently strong interference at both receivers. The comparison of the results with the state of the art shows that the GDOF optimality of TIN is expanded significantldy. [ABSTRACT FROM PUBLISHER]

Published

2017

4. The Approximate Capacity Region of the Symmetric $K$ -User Gaussian Interference Channel With Strong Interference.

Author

Chaaban, Anas and Sezgin, Aydin

Subjects

*MULTIPLEXING, *BROADCAST data systems, *ELECTRIC currents, *BROADCAST channels, *CODING theory, *SIGNAL theory, *ELECTROMAGNETIC noise, *INFORMATION theory

Abstract

The symmetric $K$ -user interference channel (IC) is studied with the goal of characterizing its capacity region in the strong interference regime within a constant gap. The achievable rate region of a scheme combining rate splitting at the transmitters and interference alignment and successive decoding/computation at the receivers is derived. Next, it is shown that this scheme achieves the so-called greedy-max corner points of the capacity region within a constant gap. By combining this result with previous results by Ordentlich et al. on the sum-capacity of the symmetric IC, a constant gap characterization of the capacity region for the strong interference regime is obtained. This leads to the first approximate characterization of the capacity region of the symmetric $K$ -user IC. Furthermore, a new scheme that achieves the sum-capacity of the channel in the strong interference regime within a constant gap is also proposed, and the corresponding gap is calculated. The advantage of the new scheme is that it leads to a characterization within a constant gap without leaving an outage set contrary to the scheme by Ordentlich et al. [ABSTRACT FROM AUTHOR]

Published

2016

5. (Sub-)Optimality of Treating Interference as Noise in the Cellular Uplink With Weak Interference.

Author

Gherekhloo, Soheil, Chaaban, Anas, Di, Chen, and Sezgin, Aydin

Subjects

*INTERFERENCE (Telecommunication), *ELECTRONIC noise, *GAUSSIAN channels, *MULTIPLE access protocols (Computer network protocols), *MOBILE communication systems

Abstract

Despite the simplicity of the scheme of treating interference as noise (TIN), it was shown to be sum-capacity optimal in the Gaussian interference channel (IC) with very-weak (noisy) interference. In this paper, the two-user IC is altered by introducing an additional transmitter that wants to communicate with one of the receivers of the IC. The resulting network thus consists of a point-to-point channel interfering with a multiple access channel (MAC) and is denoted by PIMAC. The sum-capacity of the PIMAC is studied with main focus on the optimality of TIN. It turns out that TIN in its naive variant, where all transmitters are active and both receivers use TIN for decoding, is not the best choice for the PIMAC. In fact, a scheme that combines both time division multiple access and TIN (TDMA–TIN) strictly outperforms the naive-TIN scheme. Furthermore, it is shown that in some regimes, TDMA–TIN achieves the sum-capacity for the deterministic PIMAC and the sum-capacity within a constant gap for the Gaussian PIMAC. In addition, it is shown that, even for very-weak interference, there are some regimes where a combination of interference alignment with power control and TIN at the receiver side outperforms TDMA–TIN. As a consequence, on the one hand, TIN in a cellular uplink is approximately optimal in certain regimes. On the other hand, those regimes cannot be simply described by the strength of interference. [ABSTRACT FROM PUBLISHER]

Published

2016

6. Sub-optimality of treating interference as noise in the cellular uplink.

Author

Chaaban, Anas and Sezgin, Aydin

Abstract

Despite the simplicity of the scheme of treating interference as noise (TIN), it was shown to be sum-capacity optimal in the noisy interference regime of the Gaussian 2-user interference channel in [1]–[3]. In this paper, an interference network consisting of a point-to-point channel interfering with a multiple access channel (MAC) is considered, with focus on the weak interference scenario. Naive TIN in this network is performed by using Gaussian codes at the transmitters, joint decoding at the MAC receiver while treating interference as noise, and single user decoding at the point-to-point receiver while treating both interferers as noise. It is shown that this naive TIN scheme is never optimal in this scenario. In fact, a scheme that combines both time division multiple access and TIN outperforms the naive TIN scheme. An upper bound on the sum-capacity of the given network is also derived. [ABSTRACT FROM PUBLISHER]

Published

2012

7. Relaying strategies for the interference relay channel.

Author

Chaaban, Anas and Sezgin, Aydin

Abstract

In this paper, the two-user interference relay channel (IRC) is studied. Transmission schemes for this network are compared. Namely, compress-and-forward (CF) and functional decode-and-forward (FDF) are presented. In CF, the relay establishes cooperation with the users by compressing its observation and forwarding it to the receivers. In FDF, the relay decodes a linear combination of the transmitted signals, and forwards this linear combination. We compare these schemes with decode-and-forward (DF) and with a upper bound on the rates in the IRC. It turns out that these schemes outperform DF, and approach the upper bound for some cases. [ABSTRACT FROM PUBLISHER]

Published

2012

8. On the Generalized Degrees of Freedom of the Gaussian Interference Relay Channel.

Author

Chaaban, Anas and Sezgin, Aydin

Subjects

*INTERFERENCE channels (Telecommunications), *DEGREES of freedom, *GAUSSIAN processes, *GENERALIZATION, *MATHEMATICAL bounds, *RADIO transmitter-receivers, *DECODERS & decoding, *INTEGRATED circuits

Abstract

The symmetric two-user Gaussian interference relay channel (IRC) is studied from a generalized degrees of freedom (GDoF) perspective. While it is known that the relay does not increase the DoF of the IRC, such a characterization has not been reported for the GDoF yet. The focus of this paper is on all cases where the interference link is stronger than the link from the source to the relay. This regime basically covers half the space of all possible parameters of the IRC. By using genie-aided approaches, new sum-capacity upper bounds are derived. These bounds are then compared with rates achieved with a novel transmission scheme, which is based on a functional decode-and-forward (FDF) strategy. It is shown that the GDoF of the IRC is achieved by FDF in the given regime, and that a relay can indeed increase the GDoF of IRC. Finally, the FDF scheme is compared with other schemes like decode-and-forward as well as compress-and-forward at low, moderate, and high signal-to-noise ratios. [ABSTRACT FROM PUBLISHER]

Published

2012