In millimeter wave (mmWave) systems, it is challenging to ensure the reliable connectivity of communications due to its sensitivity to the presence of blockages. In order to improve the robustness of the mmWave system under the presence of the random blockages, multiple reconfigurable intelligent surfaces (RISs) are deployed to enhance the spatial diversity gain, and robust beamforming is then designed based on a stochastic optimization for minimizing the maximum outage probability among multiple users to ensure the fairness. Under the stochastic optimization framework, we adopt the stochastic majorization--minimization (SMM) method and the stochastic successive convex approximation (SSCA) method to construct deterministic surrogate problems at each iteration for new channel realizations, and obtain the closed-form solutions of the precoding matrix at the base station (BS) and the passive beamforming vectors at the RISs. Both stochastic optimization methods have been proved to converge to the set of stationary points of the original stochastic problems. Finally, simulation results show that the proposed robust beamforming in the RIS-aided system can effectively compensate for the performance loss caused by the presence of the random blockages, especially at high blockage probability, compared with the benchmark solutions.
翻译:在毫米波(mmWave)系统中,由于对阻塞的敏感度,确保通信的可靠连通具有挑战性。为了在随机阻塞下提高毫米波的稳健性,安装了多种可重新配置的智能表面(RIS),以提高空间多样性的增益,然后根据随机优化设计了稳健的波束成型,以尽量减少多个用户的最大断流概率,确保公平性。在随机优化框架下,我们采用了随机主控-最小化(SMM)方法和随机连续相近(SSCA)系统,以在每次循环中制造确定性代谢问题,为新的频道实现,并获得基础站(BS)预校准矩阵的封闭式解决方案和风险系统被动成型矢量。两种随机优化方法已被证明与原始诊断性解决方案的固定点汇合在一起。最后,模拟结果显示,通过随机测试的概率可以有效补偿高性能测试系统,特别通过对高性标定的概率进行测试,从而对高性压性定位进行可靠的测试。