Congestion Detection in Wireless Sensor Networks Based on Artificial Neural Network and Support Vector Machine

2020 IEEE 12th International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment, and Management (HNICEM) Pub Date : 2020-12-03 DOI:10.1109/HNICEM51456.2020.9400062

Jonnel D. Alejandrino, Ronnie S. Concepcion, Sandy C. Lauguico, Maria Gemel B. Palconit, A. Bandala, E. Dadios

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引用次数: 11

Abstract

A wireless sensor network (WSN) monitors a certain phenomenon through interconnecting voluminous quantity of interconnected sensor nodes that are implemented in the sensing space and event. Transmission reliability is the key contributing factor in of WSN. Network latency, data packet loss, throughput reduction, and low energy efficiency is caused by a congested network. To solve the network congestion issue, a proposed strategy of congestion detection using ANN (artificial neural network) in comparison to SVM (support vector machine) is presented in this paper. The number of sensor nodes, traffic rate, and node retention are the parameter used. These were generated from the WSN setup in the lettuce smart farm located in Rizal, Philippines. Network Simulator 2 (NS-2) is used for network design, traffic generation, and data gathering. The 3-layer feedforward ANN is optimized using scaled conjugate gradient with sigmoidal function as output activation. SVM is configured using box constraint of 564.22 and kernel scale of 0.1475. There is 0.00776625 CE performance (cross-entropy) and 98.8% accuracy through network training. Conversely, SVM shows 95.18% accuracy. Thus, the developed ANN-based WSN congestion detection model with +3.62% accuracy is an effective tool for agricultural wireless network where array of sensors for crop and environmental monitoring is connected.

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基于人工神经网络和支持向量机的无线传感器网络拥塞检测

无线传感器网络(WSN)通过在感知空间和事件中实现大量互连的传感器节点的互连来监测某一现象。传输可靠性是影响无线传感器网络性能的关键因素。网络拥塞会导致网络延迟、丢包、吞吐量降低、能效降低等问题。为了解决网络拥塞问题，本文提出了一种基于人工神经网络的拥塞检测策略，并与支持向量机进行了比较。传感器节点数、流量速率和节点保持率是使用的参数。这些是由位于菲律宾黎萨尔的生菜智能农场的WSN设置产生的。网络模拟器2 (NS-2)用于网络设计、流量生成和数据收集。以s型函数作为输出激活，采用缩放共轭梯度对三层前馈神经网络进行优化。使用盒约束564.22，核尺度0.1475配置支持向量机。通过网络训练的CE性能(交叉熵)为0.00776625，准确率为98.8%。相反，SVM准确率为95.18%。因此，所开发的基于人工神经网络的WSN拥塞检测模型具有+3.62%的准确率，是连接作物和环境监测传感器阵列的农业无线网络的有效工具。

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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来源期刊

2020 IEEE 12th International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment, and Management (HNICEM)

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