智能城市交通:利用 5G 网络最小化延迟和延时的 VANET 边缘计算模型

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-02-08 DOI:10.1007/s10723-024-09747-5
Mengqi Wang, Jiayuan Mao, Wei Zhao, Xinya Han, Mengya Li, Chuanjun Liao, Haomiao Sun, Kexin Wang
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引用次数: 0

摘要

智能城市的运行离不开可实现无线连接、蜂窝连接和处理的自主设备。边缘计算为移动设备和云搭建了桥梁,使移动设备能够通过车载临时网络(VANET)访问计算、内存和通信功能。VANET 是一种受时间限制的技术,可以在较短时间内处理来自车辆的请求。边缘计算和 VANET 最为人熟知的问题是延迟和延时。该网络中的任何拥堵或无效现象都会导致延迟,从而影响其整体效率。受延迟影响,智慧城市中的数据处理会产生不规则的决策。有些数据,如流量、拥堵等需要及时处理。决策延迟会导致应用失败,造成错误的信息处理。在这项研究中,我们为智能城市车辆交通创建了基于概率的混合鲸-蜻蜓优化(p-H-WDFOA)边缘计算模型,该模型可降低边缘计算的延迟和时延,从而解决此类问题。此外,还采用了 5G 本地化多接入边缘计算(MEC)服务器,大大减少了等待时间和延迟,从而增强了边缘技术资源,满足了延迟和服务质量(QoS)标准。与采用纯云计算架构的实验相比,我们减少了 20% 的数据延迟。与云计算架构相比,我们还将处理时间缩短了 35%。所提出的 WDFO-VANET 方法改善了 VANET 的能耗并最大限度地降低了通信成本。
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Smart City Transportation: A VANET Edge Computing Model to Minimize Latency and Delay Utilizing 5G Network

Smart cities cannot function without autonomous devices that connect wirelessly and enable cellular connectivity and processing. Edge computing bridges mobile devices and the cloud, giving mobile devices access to computing, memory, and communication capabilities via vehicular ad hoc networks (VANET). VANET is a time-constrained technology that can handle requests from vehicles in a shorter amount of time. The most well-known problems with edge computing and VANET are latency and delay. Any congestion or ineffectiveness in this network can result in latency, which affects its overall efficiency. The data processing in smart city affected by latency can produce irregular decision making. Some data, like traffics, congestions needs to be addressed in time. Delay decision making can make application failure and results in wrong information processing. In this study, we created a probability-based hybrid Whale -Dragonfly Optimization (p–H-WDFOA) edge computing model for smart urban vehicle transportation that lowers the delay and latency of edge computing to address such issues. The 5G localized Multi-Access Edge Computing (MEC) servers were additionally employed, significantly reducing the wait and the latency to enhance the edge technology resources and meet the latency and Quality of Service (QoS) criteria. Compared to an experiment employing a pure cloud computing architecture, we reduced data latency by 20%. We also reduced processing time by 35% compared to cloud computing architecture. The proposed method, WDFO-VANET, improves energy consumption and minimizes the communication costs of VANET.

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4.30%
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