Classification of HHO-based Machine Learning Techniques for Clone Attack Detection in WSN

Q1 Mathematics

International Journal of Computer Network and Information Security Pub Date : 2023-12-08 DOI:10.5815/ijcnis.2023.06.01

Ramesh Vatambeti, Vijay Kumar Damera, Karthikeyan H., Manohar M., Sharon Roji Priya C., M. S. Mekala

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Abstract

Thanks to recent technological advancements, low-cost sensors with dispensation and communication capabilities are now feasible. As an example, a Wireless Sensor Network (WSN) is a network in which the nodes are mobile computers that exchange data with one another over wireless connections rather than relying on a central server. These inexpensive sensor nodes are particularly vulnerable to a clone node or replication assault because of their limited processing power, memory, battery life, and absence of tamper-resistant hardware. Once an attacker compromises a sensor node, they can create many copies of it elsewhere in the network that share the same ID. This would give the attacker complete internal control of the network, allowing them to mimic the genuine nodes' behavior. This is why scientists are so intent on developing better clone assault detection procedures. This research proposes a machine learning based clone node detection (ML-CND) technique to identify clone nodes in wireless networks. The goal is to identify clones effectively enough to prevent cloning attacks from happening in the first place. Use a low-cost identity verification process to identify clones in specific locations as well as around the globe. Using the Optimized Extreme Learning Machine (OELM), with kernels of ELM ideally determined through the Horse Herd Metaheuristic Optimization Algorithm (HHO), this technique safeguards the network from node identity replicas. Using the node identity replicas, the most reliable transmission path may be selected. The procedure is meant to be used to retrieve data from a network node. The simulation result demonstrates the performance analysis of several factors, including sensitivity, specificity, recall, and detection.

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基于 HHO 的机器学习技术在 WSN 中的克隆攻击检测分类

由于最近的技术进步，具有分配和通信能力的低成本传感器现在是可行的。例如，无线传感器网络(WSN)是一种网络，其中节点是通过无线连接而不是依赖中央服务器相互交换数据的移动计算机。这些廉价的传感器节点特别容易受到克隆节点或复制攻击，因为它们的处理能力、内存、电池寿命有限，而且缺乏防篡改硬件。一旦攻击者破坏了传感器节点，他们就可以在网络的其他地方创建许多共享相同ID的副本。这将使攻击者完全内部控制网络，允许他们模仿真实节点的行为。这就是为什么科学家们如此热衷于开发更好的克隆攻击检测程序。本研究提出一种基于机器学习的克隆节点检测(ML-CND)技术来识别无线网络中的克隆节点。目标是足够有效地识别克隆，以防止克隆攻击的发生。使用低成本的身份验证流程来识别特定地点以及全球范围内的克隆。该技术使用最优极限学习机(OELM)，并通过马群元启发式优化算法(HHO)理想地确定ELM的内核，从而保护网络免受节点身份副本的影响。使用节点身份副本，可以选择最可靠的传输路径。该过程旨在用于从网络节点检索数据。仿真结果显示了几个因素的性能分析，包括灵敏度、特异性、召回率和检测。

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

International Journal of Computer Network and Information Security Social Sciences-Safety Research

CiteScore

4.10

自引率

0.00%

发文量