无线传感器网络中信道识别的监督机器学习技术研究

George D. O’Mahony, Philip J. Harris, Colin C. Murphy
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引用次数: 3

摘要

无线信道的知识对于无线通信链路是至关重要的,但由于多种原因而有所不同。无线电频谱由于连接设备的数量、需求、分组大小或运行中的业务而变化,而衰落水平、障碍物、路径损失和虚假(非)恶意干扰在物理环境中波动。通常,这些通道适用于数据科学问题的时间序列类,因为主要数据点是在一段时间内测量的。在物联网应用中,无线传感器网络定期为设备提供接入点通信链路,确定运行中的无线通道允许通道访问。通常,通过清晰信道评估来确定是否可以执行无线传输,这是一种有局限性的方法。在本研究中,使用基于软件定义无线电(SDR)的程序从无线信道中收集接收到的同相(I)和正交相(Q)样本,并使用python和Matlab直接进行分析。从接收到的I/Q样本的概率密度函数和统计分析中提取特征,作为所选择的两种机器学习方法的训练数据。数据是通过电线收集和产生的,以避免干扰其他网络,使用sdr和树莓派嵌入式设备,利用可用的开源库。在现场实验室环境中对无信号(噪声)、合法信号(ZigBee)和干扰信号(连续波)进行了数据检查。分别设计并比较了支持向量机和随机森林模型作为这些信号类型的通道标识符。
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Investigating Supervised Machine Learning Techniques for Channel Identification in Wireless Sensor Networks
Knowledge of the wireless channel is pivotal for wireless communication links but varies for multiple reasons. The radio spectrum changes due to the number of connected devices, demand, packet size or services in operation, while fading levels, obstacles, path losses, and spurious (non-)malicious interference fluctuate in the physical environment. Typically, these channels are applicable to the time series class of data science problems, as the primary data points are measured over a period. In the case of wireless sensor networks, which regularly provide the device to access point communication links in Internet of Things applications, determining the wireless channel in operation permits channel access. Generally, a clear channel assessment is performed to determine whether a wireless transmission can be executed, which is an approach containing limitations. In this study, received in-phase (I) and quadrature-phase (Q) samples are collected from the wireless channel using a software-defined radio (SDR) based procedure and directly analyzed using python and Matlab. Features are extracted from the probability density function and statistical analysis of the received I/Q samples and used as the training data for the two chosen machine learning methods. Data is collected and produced over wires, to avoid interfering with other networks, using SDRs and Raspberry Pi embedded devices, which utilize available open-source libraries. Data is examined for the signal-free (noise), legitimate signal (ZigBee) and jamming signal (continuous wave) cases in a live laboratory environment. Support vector machine and Random Forest models are each designed and compared as channel identifiers for these signal types.
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