面向 5G 的室内外车联网 (IoV) 应用的智能交通系统性能分析

IF 6.6 1区计算机科学 Q1 Multidisciplinary

Tsinghua Science and Technology Pub Date : 2024-06-20 DOI:10.26599/TST.2023.9010119

Preeti Rani;Rohit Sharma

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引用次数: 0

摘要

由于先进通信技术的进步，车联网（IoVs）得到了快速发展。第五代（5G）系统将被集成到下一代汽车中，使其能够通过与环境合作来提高运行效率。毫米波（mmWave）技术预计将提供较大的带宽，以满足未来对更有效数据速率通信的需求。在自动驾驶车辆之间传输原始传感器数据的可行方法是使用毫米波通信。本文吸引了学术界、室内和室外毫米波操作方面的各种研究兴趣。本文介绍了物联网场景下 66 GHz 频率的室内和室外毫米波传播测量。所提出的模型根据车辆室内和室外通信的发射器和接收器距离，使用自由空间路径损耗（FSPL）检测等效路径损耗。在室内场景中，路径损耗传播的穿透损耗最低，但在室外场景中却不起作用，因为距离随着自由空间路径损耗的增加而增加。由于传播效应、数据包碰撞、接收器繁忙和传感阈值等原因，发送器和接收器距离越远，出错概率越高。所提出的方法显示了更高的数据包传送率和平均吞吐量，同时在传输过程中减少了连接延迟。

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Intelligent Transportation System Performance Analysis of Indoor and Outdoor Internet of Vehicle (IoV) Applications Towards 5G

The Internet of Vehicles (IoVs) has seen rapid development due to advances in advanced communication technologies. The 5-th Generation (5G) systems will be integrated into next-generation vehicles, enabling them to operate more efficiently by cooperating with the environment. The millimeter Wave (mmWave) technology is projected to provide a large bandwidth to meet future needs for more effective data rate communications. A viable approach for transferring raw sensor data among autonomous vehicles would be to use mmWave communication. This paper attracts various research interests in academic, indoor, and outdoor mmWave operations. This paper presents mmWave propagation measurements for indoor and outdoor at 66 GHz frequency for IoVs scenarios. The proposed model examines the equivalent path loss using Free-Space Path Loss (FSPL) based on the transmitter and receiver distances for indoor and outdoor communications of the vehicles. In the indoor scenario, path loss propagation has the lowest penetration loss, but it is ineffective in the outdoor scenario because distance increases as free space path loss increases. The probability of error is increased, concerning the transmitter and receiver distances due to propagation effect, packet collisions, busy receiver, and sensing threshold. The proposed methodology shows a higher packet delivery ratio and average throughput with less delay in the connection during transmission.

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来源期刊

Tsinghua Science and Technology COMPUTER SCIENCE, INFORMATION SYSTEMSCOMPU-COMPUTER SCIENCE, SOFTWARE ENGINEERING

CiteScore

10.20

自引率

10.60%

发文量

2340

期刊介绍： Tsinghua Science and Technology (Tsinghua Sci Technol) started publication in 1996. It is an international academic journal sponsored by Tsinghua University and is published bimonthly. This journal aims at presenting the up-to-date scientific achievements in computer science, electronic engineering, and other IT fields. Contributions all over the world are welcome.