城郊有人驾驶和无人驾驶汽车的异构ITS架构

2018 IEEE 23rd International Conference on Emerging Technologies and Factory Automation (ETFA) Pub Date : 2018-09-01 DOI:10.1109/ETFA.2018.8502452

Salma Emara, Aya Elewa, Omar Wasil, Kholoud Moustafa, Nada Abdel Khalek, A. H. Soliman, Hassan H. Halawa, M. Elsalamouny, R. Daoud, H. Amer, Ahmed K. F. Khattab, H. Elsayed, T. Refaat

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引用次数: 2

摘要

车联网(V2X)技术在维护道路安全、避免事故和控制交通流量方面发挥着至关重要的作用。由于自动驾驶汽车有望接管道路，本文讨论了有人驾驶和无人驾驶汽车共存的中间阶段。提出了一种同时满足城郊有人车和无人车不同需求的异构网络架构，并利用Riverbed Modeler进行了仿真。该架构的可行性在三种不同的情况下进行了测试:正常运行、双向拥堵和路旁单元(RSU)故障。在正常运行模式下，交通数据通过IEEE 802.11p通过车辆对车辆(V2V)和车辆对基础设施/基础设施对车辆(V2I/I2V或RSU)发送，信息娱乐信息通过长期演进(LTE)作为V2I/I2V通信。强调并测试了一个特殊的情况，在这个情况下，拥塞是双向的。在这种情况下，需要使用多跳通信将数据中继到最近的RSU。提出了一种容错模型，并对RSU故障的容错模型进行了分析。性能指标包括端到端延迟、LTE响应时间、切换延迟和丢包率。通过满足交通控制实时应用需求，证明了该体系结构的适用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Heterogeneous ITS Architecture for Manned and Unmanned Cars in Suburban Areas

Vehicle-to-Everything (V2X) technology plays a critical role in maintaining road safety, avoiding accidents and controlling traffic flow. As self driving cars are expected to take over the roads, this paper discusses the intermediate phase in which manned and unmanned cars coexist. A heterogeneous network architecture that simultaneously serves manned and unmanned cars' different requirements in a suburban area is proposed and simulated using Riverbed Modeler. The feasibility of this architecture is examined in three different scenarios: Normal operation, congestion in both directions and Road Side Units (RSU) failure. In normal operation mode, traffic data is sent through Vehicle-to-Vehicle (V2V) and Vehicle-to-Infrastructure/Infrastructure-to-Vehicle (V2I/I2V or to RSU) using IEEE 802.11p and infotainment information is communicated as V2I/I2V using Long Term Evolution (LTE). A special case is highlighted and tested, in which congestion is in both directions. In such situation, data needs to be relayed to the nearest RSU using multi-hop communication. A fault-tolerant model is also proposed and analyzed in case of failure of RSU. The performance metrics are end-to-end delay, LTE response time, handover delay and packet loss ratio. The architecture proves its suitability by satisfying traffic control real time application requirements.

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来源期刊

2018 IEEE 23rd International Conference on Emerging Technologies and Factory Automation (ETFA)

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