Performance analysis of Q-learning-based NOMA in Satellite–Terrestrial Relay Networks

IF 2 4区计算机科学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Physical Communication Pub Date : 2025-02-11 DOI:10.1016/j.phycom.2025.102619

Leonardo Pacheco de Aguiar , Marcos Eduardo Pivaro Monteiro , Jamil Farhat , Guilherme de Santi Peron , Glauber Brante

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Abstract

In this paper, we analyze the performance of

Q

-learning-based Non-Orthogonal Multiple Access (NOMA) in Satellite–Terrestrial Relay Networks (STRNs), addressing key challenges in massive Internet of Things (IoT) communications. Specifically, we focus on energy efficiency and normalized throughput metrics in uplink scenarios. By integrating a distributed

Q

-learning algorithm with NOMA, IoT devices can autonomously optimize transmission parameters – such as time slots, channels, and power levels – enhancing overall network performance. The proposed scheme outperforms fixed-power strategies by achieving higher normalized throughput and energy efficiency under varying network densities, offering up to 73% improvement in energy efficiency. Simulation results validate the protocol’s effectiveness, demonstrating its potential for large-scale IoT deployments in STRNs through efficient power allocation and reduced collision rates.

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卫星-地面中继网络中基于 Q 学习的 NOMA 性能分析

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来源期刊

Physical Communication ENGINEERING, ELECTRICAL & ELECTRONICTELECO-TELECOMMUNICATIONS

CiteScore

5.00

自引率

9.10%

发文量

212

审稿时长

55 days

期刊介绍： PHYCOM: Physical Communication is an international and archival journal providing complete coverage of all topics of interest to those involved in all aspects of physical layer communications. Theoretical research contributions presenting new techniques, concepts or analyses, applied contributions reporting on experiences and experiments, and tutorials are published. Topics of interest include but are not limited to: Physical layer issues of Wireless Local Area Networks, WiMAX, Wireless Mesh Networks, Sensor and Ad Hoc Networks, PCS Systems; Radio access protocols and algorithms for the physical layer; Spread Spectrum Communications; Channel Modeling; Detection and Estimation; Modulation and Coding; Multiplexing and Carrier Techniques; Broadband Wireless Communications; Wireless Personal Communications; Multi-user Detection; Signal Separation and Interference rejection: Multimedia Communications over Wireless; DSP Applications to Wireless Systems; Experimental and Prototype Results; Multiple Access Techniques; Space-time Processing; Synchronization Techniques; Error Control Techniques; Cryptography; Software Radios; Tracking; Resource Allocation and Inference Management; Multi-rate and Multi-carrier Communications; Cross layer Design and Optimization; Propagation and Channel Characterization; OFDM Systems; MIMO Systems; Ultra-Wideband Communications; Cognitive Radio System Architectures; Platforms and Hardware Implementations for the Support of Cognitive, Radio Systems; Cognitive Radio Resource Management and Dynamic Spectrum Sharing.