A. Ezekiel, Kennedy Chinedu Okafor, Sena Timothy Tersoo, Christopher Akinyemi Alabi, Jamiu Abdulsalam, A. Imoize, Olamide Jogunola, K. Anoh
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An energy-efficient resource allocation scheme is developed that integrates the UE–BS connection approach with joint optimization of power control, time allocation, antenna selection, and subcarrier assignment. The proposed scheme improves EE by 24.72% and 33.76% under perfect and imperfect CSI conditions, respectively, compared to a benchmark scheme without UE–BS connections. The scheme requires fewer BS antennas to maximize EE and the distributed algorithm exhibits fast convergence. Furthermore, UE–BS connections’ impact on EE provided significant gains. Dedicated links improve EE by 24.72% (perfect CSI) and 33.76% (imperfect CSI) over standard connections. Imperfect CSI reduces EE, with the proposed scheme outperforming by 6.97% to 12.75% across error rates. More antennas enhance EE, with improvements of up to 123.12% (conventional MIMO) and 38.14% (massive MIMO) over standard setups. 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引用次数: 0
摘要
无线功率传输(WPT)与大规模多输入多输出(MIMO)非正交多址(NOMA)网络的集成,可为智能自动驾驶汽车等网络物理系统中能源受限的物联网(IoT)设备提供运行能力。然而,在下行 WPT 期间,同信道干扰(CCI)会限制此类系统的能效(EE)收益。本文提出了一种用户设备(UE)-基站(BS)连接模型,将每个 UE 分配给单个 BS 进行 WPT,以减轻 CCI。本文开发了一种高能效资源分配方案,将 UE-BS 连接方法与功率控制、时间分配、天线选择和子载波分配的联合优化相结合。与没有 UE-BS 连接的基准方案相比,所提出的方案在完美和不完美 CSI 条件下的 EE 分别提高了 24.72% 和 33.76%。该方案只需较少的 BS 天线即可实现 EE 最大化,而且分布式算法收敛速度快。此外,UE-BS 连接对 EE 的影响也非常显著。与标准连接相比,专用链路将 EE 提高了 24.72%(完美 CSI)和 33.76%(不完美 CSI)。不完美的 CSI 会降低 EE,而所提出的方案在各种错误率下的 EE 优于标准 EE 6.97% 至 12.75%。天线越多,EE 越高,与标准设置相比,EE 提高了 123.12%(传统 MIMO)和 38.14%(大规模 MIMO)。收敛参数越大,收敛性越好,在不同收敛速率下,EE 比基线提高了 7.09% 至 11.31%。研究结果验证了所提出的技术在提高无线供电 MIMO-NOMA 网络的 WPT 效率和 EE 方面的有效性。
Enhanced Energy Transfer Efficiency for IoT-Enabled Cyber-Physical Systems in 6G Edge Networks with WPT-MIMO-NOMA
The integration of wireless power transfer (WPT) with massive multiple-input multiple-output (MIMO) non-orthogonal multiple access (NOMA) networks can provide operational capabilities to energy-constrained Internet of Things (IoT) devices in cyber-physical systems such as smart autonomous vehicles. However, during downlink WPT, co-channel interference (CCI) can limit the energy efficiency (EE) gains in such systems. This paper proposes a user equipment (UE)–base station (BS) connection model to assign each UE to a single BS for WPT to mitigate CCI. An energy-efficient resource allocation scheme is developed that integrates the UE–BS connection approach with joint optimization of power control, time allocation, antenna selection, and subcarrier assignment. The proposed scheme improves EE by 24.72% and 33.76% under perfect and imperfect CSI conditions, respectively, compared to a benchmark scheme without UE–BS connections. The scheme requires fewer BS antennas to maximize EE and the distributed algorithm exhibits fast convergence. Furthermore, UE–BS connections’ impact on EE provided significant gains. Dedicated links improve EE by 24.72% (perfect CSI) and 33.76% (imperfect CSI) over standard connections. Imperfect CSI reduces EE, with the proposed scheme outperforming by 6.97% to 12.75% across error rates. More antennas enhance EE, with improvements of up to 123.12% (conventional MIMO) and 38.14% (massive MIMO) over standard setups. Larger convergence parameters improve convergence, achieving EE gains of 7.09% to 11.31% over the baseline with different convergence rates. The findings validate the effectiveness of the proposed techniques in improving WPT efficiency and EE in wireless-powered MIMO–NOMA networks.