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面向智能校园的软件定义与虚拟化物联网网关部署的规划与优化

Planning and Optimization of Software-Defined and Virtualized IoT Gateway Deployment for Smart Campuses.

作者信息

Ferreira Divino, Oliveira João Lucas, Santos Carlos, Filho Tércio, Ribeiro Maria, Freitas Leandro Alexandre, Moreira Waldir, Oliveira-Jr Antonio

机构信息

Campus Senador Canedo, Federal Institute of Education, Science and Technology of Goiás (IFG), Senador Canedo 75250-000, Brazil.

Institute of Informatics (INF), Federal University of Goiás (UFG), Goiânia 74690-900, Brazil.

出版信息

Sensors (Basel). 2022 Jun 22;22(13):4710. doi: 10.3390/s22134710.

DOI:10.3390/s22134710
PMID:35808207
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9268935/
Abstract

The Internet of Things (IoT) is based on objects or "things" that have the ability to communicate and transfer data. Due to the large number of connected objects and devices, there has been a rapid growth in the amount of data that are transferred over the Internet. To support this increase, the heterogeneity of devices and their geographical distributions, there is a need for IoT gateways that can cope with this demand. The SOFTWAY4IoT project, which was funded by the National Education and Research Network (RNP), has developed a software-defined and virtualized IoT gateway that supports multiple wireless communication technologies and fog/cloud environment integration. In this work, we propose a planning method that uses optimization models for the deployment of IoT gateways in smart campuses. The presented models aimed to quantify the minimum number of IoT gateways that is necessary to cover the desired area and their positions and to distribute IoT devices to the respective gateways. For this purpose, the communication technology range and the data link consumption were defined as the parameters for the optimization models. Three models are presented, which use LoRa, Wi-Fi, and BLE communication technologies. The gateway deployment problem was solved in two steps: first, the gateways were quantified using a linear programming model; second, the gateway positions and the distribution of IoT devices were calculated using the classical K-means clustering algorithm and the metaheuristic particle swarm optimization. Case studies and experiments were conducted at the Samambaia Campus of the Federal University of Goiás as an example. Finally, an analysis of the three models was performed, using metrics such as the silhouette coefficient. Non-parametric hypothesis tests were also applied to the performed experiments to verify that the proposed models did not produce results using the same population.

摘要

物联网(IoT)基于具有通信和传输数据能力的物体或“事物”。由于连接的物体和设备数量众多,通过互联网传输的数据量迅速增长。为了支持这种增长,应对设备的异构性及其地理分布,需要能够满足这一需求的物联网网关。由国家教育和研究网络(RNP)资助的SOFTWAY4IoT项目开发了一种软件定义和虚拟化的物联网网关,该网关支持多种无线通信技术以及雾/云环境集成。在这项工作中,我们提出了一种规划方法,该方法使用优化模型在智能校园中部署物联网网关。所提出的模型旨在量化覆盖所需区域所需的物联网网关的最小数量及其位置,并将物联网设备分配到各个网关。为此,将通信技术范围和数据链路消耗定义为优化模型的参数。提出了三种模型,它们分别使用LoRa、Wi-Fi和BLE通信技术。网关部署问题分两步解决:首先,使用线性规划模型对网关进行量化;其次,使用经典的K均值聚类算法和元启发式粒子群优化算法计算网关位置和物联网设备的分布。以戈亚斯联邦大学的萨曼巴亚校区为例进行了案例研究和实验。最后,使用轮廓系数等指标对这三种模型进行了分析。还对所进行的实验应用了非参数假设检验,以验证所提出的模型不会使用相同总体产生结果。

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