The requirements of vehicular communications grow with increasing level of automated driving and future applications of intelligent transportation systems (ITS). Beside the ever-increasing need for high capacity radio links, reliability and latency constraints challenge the mobile network supply. While for example the millimeter-wave spectrum and THz-bands offer a vast amount of radio resources, their applicability is limited due to delicate radio channel conditions and signal propagation characteristics. Reconfigurable intelligent surfaces (RISs) as part of smart radio environments (SREs) of future ITS infrastructure promise improved radio link qualities by means of purposeful cultivation of passive reflections. With this, obstructed mmWave or THz beams can be guided around obstacles through RIS reflection paths to improve the otherwise limited coverage. In this article, application use cases of RIS-enhanced vehicular communications are proposed. Beside static deployments of RISs at exterior walls of buildings, unmanned aerial vehicles (UAV) could provide reflection capabilities on demand, while future vehicles could - in a visionary approach - consist of meta-material allowing for their opportunistic utilization within an enriched SRE. Results of a case study based on our multi-scale mobility and network simulation model clearly highlight the potential of RIS deployment for hybrid vehicular communication scenarios. Path loss and outage percentages can be reduced considerably.
翻译:随着智能运输系统(ITS)自动化驾驶和未来应用水平的提高,对车辆通信的需求随着智能运输系统(ITS)的自动化驾驶水平和未来应用的不断增长而增长。除了对高容量无线电连接、可靠性和潜伏性限制的日益增加的需求外,移动网络的供应也面临挑战。例如,千米波频谱和THZ波段提供了大量的无线电资源,但由于无线电频道条件和信号传播特点微妙,这些通信的可应用性有限。作为未来ITS基础设施智能无线电环境的一部分的可配置智能地面(RIS)有望通过有目的地培养被动反射器来改善无线电联系的质量。随着这种需求不断增加的需求的增加,阻断的毫米瓦夫或THZ光束可以通过IRS反射路径绕障碍绕开障碍,以改善本来有限的覆盖范围。在本篇文章中,提出了应用RIS增强的车辆通信案例。除了在建筑物外墙上静态地部署RIS外,无人驾驶航空飞行器(UAVAV)可以提供需求反射能力,而未来的车辆则可以 -- -- 富有远见的方法 -- 包括元材料,允许在更丰富的空间模型内利用其机会性利用,从而可改进SRE反射镜反射镜反射系统。移动网络的结果可以明显地进行多级的模拟反射线定位。