利用磁化 Hopfield 神经网络和金枪鱼群优化算法识别物联网设备类型

IF 8.2 1区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Muthukrishnan A , Kamalesh S
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引用次数: 0

摘要

物联网(IoT)网络由连接到互联网的物理设备组成,内嵌有执行器、传感器和交换数据的通信组件。为了提高物联网的安全性,准确识别和评估联网设备的安全性至关重要。为提高物联网安全性,本研究提出了利用基于 Memristor 的磁化 Hopfield 神经网络和金枪鱼群优化算法(IOT-DTI-MHNN-TSOA)进行物联网设备类型识别。它包括数据收集、特征提取和物联网设备类型识别。在数据收集阶段,使用的是通过 10 种不同物联网设备类别收集的实际网络流量数据集。在特征提取阶段,使用二维灵活分析小波变换(2D-FAWT)提取最佳特征,如服务器的 TCP 数据包生存时间、客户端的数据包到达间隔时间、服务器的数据包到达间隔时间、客户端的 TCP 数据包生存时间、数据包到达间隔时间、数据包大小、发送和接收的字节数、客户端的数据包大小和数据包总数。这些提取的特征将提供给物联网设备类型识别阶段。在这一阶段,采用基于 Memristor 的磁化 Hopfield 神经网络 (MHNN) 方法来感知物联网设备的已知/可见类别或未知/未见类别。金枪鱼群优化算法(TSOA)增强了 MHNN 的权重参数。IOT-DTI-MHNN-TSOA 分类框架的功效通过精确度、准确度、F1 分数、灵敏度、特异性、错误率、计算时间、ROC、计算复杂度等性能指标进行评估。与现有模型相比,IOT-DTI-MHNN-TSOA 方法的准确率高达 99.97 %,灵敏度高达 99.95 %,精确度高达 99.92 %。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
IOT device type identification using magnetized Hopfield neural network with tuna swarm optimization algorithm

Internet of Things (IoT) networks consist of physical devices connected to the Internet, embedded with actuators, sensors, and communication components that exchange data. To enhance IoT security, accurately identifying and assessing the safety of connected devices is essential. To improve IoT security, this research proposes the IoT Device Type Identification utilizing Memristor-based Magnetized Hopfield Neural Network with Tuna Swarm Optimization Algorithm (IOT-DTI-MHNN-TSOA). It includes data collection, feature extraction, IoT device type identification. In data collection, an actual network traffic dataset amassed through 10 various IoT device categories is used. In the feature extraction phase, optimal features such as TCP packets' time-to-live by server, packets' inter-arrival time by client, packets' inter-arrival time by server, TCP packets' time-to-live by client, packets' inter-arrival time, packet size, number of bytes sent and received, packet size by client, and total number of packets are extracted using a 2-Dimensional Flexible Analytic Wavelet Transform (2D-FAWT). These extracting features are provided to the IoT device type identification phase. In this phase, a Memristor-based Magnetized Hopfield Neural Network (MHNN) method is employed to perceive the categories of IoT device as known/seen or unknown/unseen categories. The Tuna Swarm Optimization Algorithm (TSOA) enhances the weight parameters of MHNN. The efficacy of the IOT-DTI-MHNN-TSOA classification framework is assessed using performance metrics, like precision, accuracy, F1-score, sensitivity, specificity, error rate, computational time, ROC, Computational Complexity. The IOT-DTI-MHNN-TSOA method provides higher accuracy of 99.97 %, higher sensitivity of 99.95 %, and higher precision of 99.92 % compared to the existing models.

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来源期刊
Swarm and Evolutionary Computation
Swarm and Evolutionary Computation COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCEC-COMPUTER SCIENCE, THEORY & METHODS
CiteScore
16.00
自引率
12.00%
发文量
169
期刊介绍: Swarm and Evolutionary Computation is a pioneering peer-reviewed journal focused on the latest research and advancements in nature-inspired intelligent computation using swarm and evolutionary algorithms. It covers theoretical, experimental, and practical aspects of these paradigms and their hybrids, promoting interdisciplinary research. The journal prioritizes the publication of high-quality, original articles that push the boundaries of evolutionary computation and swarm intelligence. Additionally, it welcomes survey papers on current topics and novel applications. Topics of interest include but are not limited to: Genetic Algorithms, and Genetic Programming, Evolution Strategies, and Evolutionary Programming, Differential Evolution, Artificial Immune Systems, Particle Swarms, Ant Colony, Bacterial Foraging, Artificial Bees, Fireflies Algorithm, Harmony Search, Artificial Life, Digital Organisms, Estimation of Distribution Algorithms, Stochastic Diffusion Search, Quantum Computing, Nano Computing, Membrane Computing, Human-centric Computing, Hybridization of Algorithms, Memetic Computing, Autonomic Computing, Self-organizing systems, Combinatorial, Discrete, Binary, Constrained, Multi-objective, Multi-modal, Dynamic, and Large-scale Optimization.
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