Ahmed Nasser scite author profile

In this paper, a novel interference management technique based on compressive sensing (CS) theory is investigated for downlink non-orthogonal multiple access (NOMA) heterogeneous networks (HetNets). We mathematically formulate the interference management problem in terms of power and resource blocks (RBs) allocation to maximize the overall sum rate while considering both co-tier and crosstier interferences and then explain its non-convexity. In this paper, we exploit the sparsity of the allocated RBs to relax the non-convexity of the formulated problem by transforming it into a sparse l 1 -norm problem for a near-optimum solution. Then, based on the CS theory, an interference management technique with a restricted weighted fast iterative shrinkage-thresholding (R-WFISTA) algorithm is proposed to solve the equivalent sparse l 1 -norm problem. The simulation results verify that compared with the conventional orthogonal multiple access (OMA) HetNets and conventional NOMA HetNets, the proposed technique improves the system performance in terms of overall sum rate and the outage probability. INDEX TERMSCompressive sensing (CS), heterogeneous networks (HetNets), non-orthogonal multiple access (NOMA), power allocation (PA), sparsity.

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Alternative direction for 3D orthogonal frequency division multiplexing massive MIMO FDD channel estimation and feedback

Nasser¹,

Elsabrouty²,

Muta

2018

IET Communications

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Joint User Pairing and Power Allocation With Compressive Sensing in NOMA Systems

Nasser

Muta

Gacanin

et al. 2021

IEEE Wireless Commun. Lett.

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Cross-Tier Interference Management Scheme for Downlink mMIMIO-NOMA HetNet

Nasser

Muta²,

Elsabrouty

2019

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Adaptive Split Bregman for sparse and low rank massive MIMO channel estimation

Nasser

Elsabrouty

2016

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Cache‐enabled reinforcement learning scheme for power allocation and user selection in opportunistic downlink NOMA transmissions

Gendia

Muta

Nasser

2022

IEEJ Transactions Elec Engng

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Non-orthogonal multiple access (NOMA) allows multiple user equipment (UE) to simultaneously share the same resource blocks using varying levels of transmit power at the base station (BS) side. Proper allocation of transmission power and selection of candidate users for pairing over the same resource block are critical for an efficient utilization of the available resources. Optimal UE selection and power splitting among paired UEs can be made through an exhaustive search over the space of all possible solutions. However, the cost incurred by such approach can render it practically infeasible. Reinforcement learning (RL) deploying double deep-Q networks (DDQN) is a promising framework that can be adopted for tackling the problem. In this article, an RL-based DDQN scheme is proposed for user pairing in opportunistic access to downlink NOMA systems with capacity-limited backhaul link connections. The proposed algorithm relies on proactive data caching to alleviate the throttling caused by backhaul bottlenecks, and optimized UE selection and power allocation are accomplished through the continuous interaction between an RL agent and the NOMA environment to increase the overall system throughput. Simulation results are presented to showcase the near-optimal strategy achieved by the proposed scheme.

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Ahmed Nasser

Interference Mitigation and Power Allocation Scheme for Downlink MIMO–NOMA HetNet

Frequency-selective massive MIMO channel estimation and feedback in angle-time domain

Compressive Sensing Based Spectrum Allocation and Power Control for NOMA HetNets

Alternative direction for 3D orthogonal frequency division multiplexing massive MIMO FDD channel estimation and feedback

Joint User Pairing and Power Allocation With Compressive Sensing in NOMA Systems

Cross-Tier Interference Management Scheme for Downlink mMIMIO-NOMA HetNet

Adaptive Split Bregman for sparse and low rank massive MIMO channel estimation

Cache‐enabled reinforcement learning scheme for power allocation and user selection in opportunistic downlink NOMA transmissions

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