基于自适应 MLP 的设备对设备通信中资源分配和中继选择联合优化混合元启发式算法

IF 2.3 4区 计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Ramesh Babu Chennaboin, S. Nandakumar
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引用次数: 0

摘要

通过一种称为设备对设备(D2D)通信的先进技术,可以提高蜂窝网络的能效和频谱效率。这些效率的提高是通过再次利用蜂窝用户(CU)资源,以有效的频谱方式与附近的蜂窝设备进行通信来实现的。由于 D2D 通信技术能够有效地提供与附近设备的直接通信链路,并提高频谱效率,因此这种方法被认为是未来蜂窝通信网络的理想解决方案。需要利用 D2D 技术实现灵活可靠的中继辅助通信,在 D2D 设备之间的信道衰减变大时充当中间中继。由于 D2D 通信技术使用蜂窝设备内的直接数据传输,因此利用这种技术可以提高系统的吞吐量。当蜂窝用户之间相距甚远时,利用中继技术可将 D2D 通信系统中的数据损失降至最低。当信道良好时,中继节点(RN)就会为蜂窝用户服务。然而,人们注意到 D2D 系统受到较高能耗和频谱共享等问题的影响。此外,在中继辅助 D2D 通信系统中,资源共享蜂窝设备之间的相互干扰也会导致总和速率下降。在传统的中继辅助 D2D 通信系统中,D2D 接收机(DR)和 D2D 发射机(DT)之间的数据传输仅利用 RN 自身的能量。传统联合资源分配方案中的中继选择和资源分配问题,通过执行优化中继选择和联合资源分配任务的方案得到了解决。提高 D2D 通信的总和速率是实施方案的主要动机。在实现这一目标的同时,还要尽量降低蜂窝网络和 D2D 网络中的链路速率。中继站的理想选择和联合资源分配的执行是利用一种名为 "混合流向与变色龙蜂群算法(HFDCSA)"的新优化方案完成的,其中流向算法(FDA)与变色龙蜂群算法相融合。考虑到网络总和率和网络能效等约束条件,这种中继站的优化选择有助于实现高性能。从不同来源获得的数据将提供给自适应多层感知器(AMLP),该感知器在建议的 HFDCSA 的帮助下进行优化资源分配和中继选择。MLP 中的参数由相同的 HFDCSA 调整。最后,在此阶段进行性能验证,以验证所建议方法的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

An adaptive MLP-based joint optimization of resource allocation and relay selection in device-to-device communication using hybrid meta-heuristic algorithm

An adaptive MLP-based joint optimization of resource allocation and relay selection in device-to-device communication using hybrid meta-heuristic algorithm

Enhancement in both energy efficiency and spectral efficiency in cellular networks is made possible by means of an advanced technique called device-to device (D2D) communication. The enhancement of these efficiencies is done by utilizing the cellular user (CU) resources once again to make communication with nearby cellular devices in an effective manner by spectral means. As the D2D communication technology is capable of providing a direct communication link with nearby devices effectively with enhanced spectral efficacy, this approach is considered as an ideal solution for the futuristic cellular communication network. A flexible and reliable relay-assisted communication by means of D2D technology is required that acts as an intermediate relay when the attenuation between the channels across the D2D devices becomes high. The throughput of the system is increased by utilizing D2D communication technology as it uses direct data transmission within cellular devices. When the cellular user is far apart from one another, the data loss in the D2D communication system is minimized with the utilization of the relay. When the channels are good, then the relay nodes (RNs) serve the cellular user. However, it is noted that the D2D systems are affected by issues such as higher consumption of energy and spectral sharing. Also, the sum rate gets degraded as a result of mutual interference between resource-sharing cellular devices in the relay-assisted D2D communication system. The transmission of the data in a traditional relay-assisted D2D communication system is carried out between the D2D receiver (DR) and D2D transmitter (DT) only with the utilization of its own energy by the RN. The issues in relay selection and resource allocation in the conventional joint resource allocation schemes are tackled by executing a scheme for performing the task of optimal relay selection and joint resource allocation. The enhancement of the overall sum rate in the D2D communication is the main motive behind the implemented scheme. This goal is attained along with the minimization of the link rates in the cellular and D2D networks. The ideal selection of the relay and the execution of the joint resource allocation are done with the utilization of a new optimization scheme called the hybrid flow direction with the chameleon swarm algorithm (HFDCSA), in which the flow direction algorithm (FDA) is fused along with chameleon swarm algorithm. This optimal selection of the relays is assisted by considering constraints like the network’s sum rate and energy efficiency in the network to achieve high performance. The data obtained from distinct sources are given to the adaptive multi-layer perceptron (AMLP) in which optimal resource allocation and the relay selection are performed with the help of the suggested HFDCSA. The parameters in the MLP are tuned by the same HFDCSA. Finally, the performance validation is conducted in the stage to verify the working of the suggested approach.

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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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