Joint beamforming and power splitting design for MISO downlink communication with SWIPT: a comparison between cell-free massive MIMO and small-cell deployments

IF 2.3 4区 计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Jain-Shing Liu, Chun-Hung Richard Lin, Wan-Ling Chang
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引用次数: 0

Abstract

Simultaneous wireless information and power transfer (SWIPT) has been advocated as a highly promising technology for enhancing the capabilities of 5G and 6G devices. However, the challenge of dealing with large propagation path loss poses a significant hurdle. To address this issue, massive multiple-input multiple-output (MIMO) is employed to enhance the efficiency of SWIPT in cellular-based networks with multiple small cells, and especially increase the energy for cell-edge users. In addition, by leveraging a large set of spatially distributed base stations to collaboratively serve SWIPT-enabled user equipment, the cell-free massive MIMO has the potential to provide even better performance than the conventional small-cell systems. In this work, we extend the investigation to include the application of SWIPT technology with alternating current (AC) logic in the cell-free networks and the small-cell networks and propose joint beamforming and power splitting optimization frameworks to maximize the system sum-rate, subject to the constraints on harvested energy, AC logic energy supply, and total transmit power. The optimization problem is shown to be non-convex, posing a significant challenge. To address this challenge, we resort to a two-stage decomposition approach. Specifically, we first introduce quadratic transform-based fractional programming (FP) algorithms to iteratively solve the non-convex optimization problems in the first stage, achieving near-optimal solutions with low time complexities. To further reduce the complexities, we also incorporate conventional schemes such as zero forcing, maximum ratio transmission, and signal-to-leakage-and-noise ratio for the design of beamforming vectors. Second, to determine the optimal power splitting ratio within the framework, we develop a one-dimensional (1-D) search algorithm to tackle the single variable optimization problem reduced in the second stage. These algorithms are then evaluated in the context of cell-free MIMO and small-cell networks with numerical experiments. The results show that the FP-based algorithms can consistently outperform those utilizing the conventional beamforming schemes, and the solutions of this work can achieve up to fivefold improvement in the system sum-rate than the small-cell counterpart while providing different but comparable performance trends in energy harvesting (EH).

Abstract Image

采用 SWIPT 的 MISO 下行链路通信的联合波束成形和功率分配设计:无蜂窝大规模 MIMO 和小蜂窝部署之间的比较
同步无线信息和功率传输(SWIPT)被认为是一种极有前途的技术,可增强 5G 和 6G 设备的功能。然而,应对大传播路径损耗的挑战构成了重大障碍。为解决这一问题,我们采用了大规模多输入多输出(MIMO)技术,以提高基于蜂窝的多小蜂窝网络中 SWIPT 的效率,特别是增加蜂窝边缘用户的能量。此外,通过利用大量空间分布基站协同为支持 SWIPT 的用户设备提供服务,无蜂窝大规模 MIMO 有可能提供比传统小蜂窝系统更好的性能。在这项工作中,我们将研究范围扩大到无蜂窝网络和小蜂窝网络中交流逻辑 SWIPT 技术的应用,并提出了波束成形和功率分配联合优化框架,以在收获能量、交流逻辑能量供应和总发射功率的约束下最大化系统总和速率。结果表明,优化问题是非凸的,这给我们带来了巨大的挑战。为应对这一挑战,我们采用了两阶段分解法。具体来说,我们首先引入基于二次变换的分数编程(FP)算法,在第一阶段迭代解决非凸优化问题,以较低的时间复杂度获得接近最优的解决方案。为了进一步降低复杂度,我们还在波束成形矢量设计中采用了零强迫、最大比传输和信漏噪比等传统方案。其次,为了在框架内确定最佳功率分配比例,我们开发了一种一维(1-D)搜索算法,以解决第二阶段减少的单变量优化问题。然后,我们在无小区多输入多输出(MIMO)和小蜂窝网络的背景下,通过数值实验对这些算法进行了评估。结果表明,基于 FP 的算法始终优于那些利用传统波束成形方案的算法,而且与小蜂窝对应算法相比,这项工作的解决方案可实现高达五倍的系统总和速率改进,同时在能量收集(EH)方面提供不同但相当的性能趋势。
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来源期刊
CiteScore
7.70
自引率
3.80%
发文量
109
审稿时长
8.0 months
期刊介绍: The overall aim of the EURASIP Journal on Wireless Communications and Networking (EURASIP JWCN) is to bring together science and applications of wireless communications and networking technologies with emphasis on signal processing techniques and tools. It is directed at both practicing engineers and academic researchers. EURASIP Journal on Wireless Communications and Networking will highlight the continued growth and new challenges in wireless technology, for both application development and basic research. Articles should emphasize original results relating to the theory and/or applications of wireless communications and networking. Review articles, especially those emphasizing multidisciplinary views of communications and networking, are also welcome. EURASIP Journal on Wireless Communications and Networking employs a paperless, electronic submission and evaluation system to promote a rapid turnaround in the peer-review process. The journal is an Open Access journal since 2004.
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