Device Type Classification based on Two-stage Traffic Behavior Analysis

IF 0.7 4区 计算机科学 Q3 Engineering IEICE Transactions on Communications Pub Date : 2023-01-01 DOI:10.1587/transcom.2023wwp0004
Chikako TAKASAKI, Tomohiro KORIKAWA, Kyota HATTORI, Hidenari OHWADA
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Abstract

In the beyond 5G and 6G networks, the number of connected devices and their types will greatly increase including not only user devices such as smartphones but also the Internet of Things (IoT). Moreover, Non-terrestrial networks (NTN) introduce dynamic changes in the types of connected devices as base stations or access points are moving objects. Therefore, continuous network capacity design is required to fulfill the network requirements of each device. However, continuous optimization of network capacity design for each device within a short time span becomes difficult because of the heavy calculation amount. We introduce device types as groups of devices whose traffic characteristics resemble and optimize network capacity per device type for efficient network capacity design. This paper proposes a method to classify device types by analyzing only encrypted traffic behavior without using payload and packets of specific protocols. In the first stage, general device types, such as IoT and non-IoT, are classified by analyzing packet header statistics using machine learning. Then, in the second stage, connected devices classified as IoT in the first stage are classified into IoT device types, by analyzing a time series of traffic behavior using deep learning. We demonstrate that the proposed method classifies device types by analyzing traffic datasets and outperforms the existing IoT-only device classification methods in terms of the number of types and the accuracy. In addition, the proposed model performs comparable as a state-of-the-art model of traffic classification, ResNet 1D model. The proposed method is suitable to grasp device types in terms of traffic characteristics toward efficient network capacity design in networks where massive devices for various services are connected and the connected devices continuously change.
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基于两阶段流行为分析的设备类型分类
在超越5G和6G的网络中,连接设备的数量和类型将大大增加,不仅包括智能手机等用户设备,还包括物联网(IoT)。此外,非地面网络(NTN)引入了连接设备类型的动态变化,因为基站或接入点是移动的对象。因此,需要进行连续的网络容量设计,以满足各设备的网络需求。但是,由于计算量大,很难在短时间内对每个设备进行持续优化的网络容量设计。我们将设备类型作为流量特征相似的设备组来引入,并对每种设备类型的网络容量进行优化,以实现有效的网络容量设计。本文提出了一种不使用特定协议的有效载荷和报文,仅通过分析加密的流量行为对设备类型进行分类的方法。在第一阶段,通过使用机器学习分析包头统计数据,对物联网和非物联网等一般设备类型进行分类。然后,在第二阶段,通过使用深度学习分析流量行为的时间序列,将第一阶段分类为物联网的连接设备分类为物联网设备类型。我们证明了该方法通过分析流量数据集对设备类型进行分类,并且在类型数量和准确率方面优于现有的仅限iot的设备分类方法。此外,该模型的性能可与最先进的流量分类模型ResNet 1D模型相媲美。该方法适用于在各种业务连接大量设备且连接设备不断变化的网络中,从流量特征上把握设备类型,实现高效的网络容量设计。
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来源期刊
IEICE Transactions on Communications
IEICE Transactions on Communications ENGINEERING, ELECTRICAL & ELECTRONIC-TELECOMMUNICATIONS
CiteScore
1.50
自引率
28.60%
发文量
101
期刊介绍: The IEICE Transactions on Communications is an all-electronic journal published occasionally by the Institute of Electronics, Information and Communication Engineers (IEICE) and edited by the Communications Society in IEICE. The IEICE Transactions on Communications publishes original, peer-reviewed papers that embrace the entire field of communications, including: - Fundamental Theories for Communications - Energy in Electronics Communications - Transmission Systems and Transmission Equipment for Communications - Optical Fiber for Communications - Fiber-Optic Transmission for Communications - Network System - Network - Internet - Network Management/Operation - Antennas and Propagation - Electromagnetic Compatibility (EMC) - Wireless Communication Technologies - Terrestrial Wireless Communication/Broadcasting Technologies - Satellite Communications - Sensing - Navigation, Guidance and Control Systems - Space Utilization Systems for Communications - Multimedia Systems for Communication
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