面向智能移动的无线传感器网络技术研究

Q3 Mathematics

International Journal of Sensors, Wireless Communications and Control Pub Date : 2022-08-05 DOI:10.2174/2210327912666220805124234

R. Gill, Tarun Dubey

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引用次数: 0

摘要

无线传感器网络(WSN)由大量随机部署在一个区域内的传感器节点组成，这些传感器节点可以感知周围环境，收集一些数据，并通过无线通道相互连接，通过互联网与邻近节点或某些用户共享信息。WSN在军事、医疗、工业、农业、畜牧业、智慧城市等领域有着广泛的应用。本文的背景部分详细讨论了WSN在医疗保健、国防、农业和工业中的针对性。本文的目的是对wsn中应用于路由的Dijkstra算法、Bellman Ford算法和Floyd-Warshall算法进行检验和仿真，在CupCarbon U-one 4.2模拟器上对这些算法进行仿真，以计算不同规模网络中随机部署的源节点与目的节点之间的最短距离。考虑传感器半径、无线电距离和通信量等重要仿真参数，对三种算法进行了仿真。并通过仿真展示了Floyd Warshall算法在智能移动领域的实现。结果表明，三种算法计算从源到目的的最短路径的仿真时间相同，适用于智能出行、智能事故管理和智能交通管理的各种应用。仿真结果验证了各算法的性能及其在无线传感器网络中的适用性。结语部分是本文的结语。

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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Study of Different Techniques used in WSN for Smart Mobility

A Wireless Sensor Network (WSN) consists of a large number of sensor nodes deployed randomly over an area that can sense the surrounding environment to gather some data and interconnect over a wireless channel to share the information with neighboring nodes or with some user over the internet. WSN has a wide range of applications in the field of military, healthcare, industry, agriculture, livestock farming, and smart cities. The pertinence of WSN in healthcare, defense, agriculture, and industry is discussed in detail in the background section of this paper. The objective of this paper is to examine and simulate Dijkstra’s Algorithm, Bellman Ford’s Algorithm, and Floyd-Warshall’s Algorithm applied for routing in WSN Simulation is completed on CupCarbon U-one 4.2 simulator for these algorithms to compute the shortest distance between a randomly deployed source node and a destination node in different sized networks. Simulation of the three algorithms is carried out considering the vital simulation parameters including sensor radius, radio range, and traffic. Also, Simulation is carried out to show the implementation of Floyd Warshall’s algorithm in the field of smart mobility. The results obtained show that the simulation time for the calculation of the shortest route from source to destinations for the three algorithms is the same which is also suitable for various applications of smart mobility, smart accident management, and smart traffic management. The simulation results are also examined to measure the performance of each algorithm and its suitability in the context of WSN. The epilogue of this paper is provided in the conclusion section.

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来源期刊

International Journal of Sensors, Wireless Communications and Control Engineering-Electrical and Electronic Engineering

CiteScore

2.20

自引率

0.00%

发文量

期刊介绍： International Journal of Sensors, Wireless Communications and Control publishes timely research articles, full-length/ mini reviews and communications on these three strongly related areas, with emphasis on networked control systems whose sensors are interconnected via wireless communication networks. The emergence of high speed wireless network technologies allows a cluster of devices to be linked together economically to form a distributed system. Wireless communication is playing an increasingly important role in such distributed systems. Transmitting sensor measurements and control commands over wireless links allows rapid deployment, flexible installation, fully mobile operation and prevents the cable wear and tear problem in industrial automation, healthcare and environmental assessment. Wireless networked systems has raised and continues to raise fundamental challenges in the fields of science, engineering and industrial applications, hence, more new modelling techniques, problem formulations and solutions are required.