L. Gong, Wei Xu, Xiaoxiu Ding, Nanrun Zhou, Qibiao Zhu
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引用次数: 0
摘要
为了进一步提高保密率,在由可重构智能表面(RIS)辅助的不可信任中继(UR)网络中,提出了可重构智能表面(RIS)相移和功率分配的联合优化方案。对 UR 的窃听受到基于源的干扰策略的干扰。在单位模数和总功率的约束下,对 RIS 相移、保密信号与干扰信号之间的功率分配以及源节点与 UR 之间的功率分配进行了联合优化,以最大限度地提高保密率。复杂的多变量耦合问题被分解为三个子问题,目标函数和约束条件的非凸性通过半有限松弛求解。仿真结果表明,与等功率分配方案、随机相移方案和无 RIS 方案相比,拟议方案的保密率显著提高。
Joint optimization scheme for the reconfigurable intelligent surface-assisted untrusted relay networks
To further improve the secrecy rate, a joint optimization scheme for the reconfigurable intelligent surface (RIS) phase shift and the power allocation is proposed in the untrusted relay (UR) networks assisted by the RIS. The eavesdropping on the UR is interfered by a source-based jamming strategy. Under the constraints of unit modulus and total power, the RIS phase shift, the power allocation between the confidential signal and the jamming signal, and the power allocation between the source node and the UR are jointly optimized to maximize the secrecy rate. The complex multivariable coupling problem is decomposed into three sub-problems, and the non-convexity of the objective function and the constraints is solved with semi-definite relaxation. Simulation results indicate that the secrecy rate is remarkably enhanced with the proposed scheme compared with the equal power allocation scheme, the random phase shift scheme, and the no-RIS scheme.
期刊介绍:
China Communications (ISSN 1673-5447) is an English-language monthly journal cosponsored by the China Institute of Communications (CIC) and IEEE Communications Society (IEEE ComSoc). It is aimed at readers in industry, universities, research and development organizations, and government agencies in the field of Information and Communications Technologies (ICTs) worldwide.
The journal's main objective is to promote academic exchange in the ICTs sector and publish high-quality papers to contribute to the global ICTs industry. It provides instant access to the latest articles and papers, presenting leading-edge research achievements, tutorial overviews, and descriptions of significant practical applications of technology.
China Communications has been indexed in SCIE (Science Citation Index-Expanded) since January 2007. Additionally, all articles have been available in the IEEE Xplore digital library since January 2013.
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