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考虑在多个频率信道上进行射频指纹识别。

Considerations for Radio Frequency Fingerprinting across Multiple Frequency Channels.

机构信息

Department of Electrical and Computer Engineering, Air Force Institute of Technology, Wright-Patterson AFB, OH 45433, USA.

出版信息

Sensors (Basel). 2022 Mar 9;22(6):2111. doi: 10.3390/s22062111.

DOI:10.3390/s22062111
PMID:35336280
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8955887/
Abstract

Radio Frequency Fingerprinting (RFF) is often proposed as an authentication mechanism for wireless device security, but application of existing techniques in multi-channel scenarios is limited because prior models were created and evaluated using bursts from a single frequency channel without considering the effects of multi-channel operation. Our research evaluated the multi-channel performance of four single-channel models with increasing complexity, to include a simple discriminant analysis model and three neural networks. Performance characterization using the multi-class Matthews Correlation Coefficient (MCC) revealed that using frequency channels other than those used to train the models can lead to a deterioration in performance from MCC > 0.9 (excellent) down to MCC < 0.05 (random guess), indicating that single-channel models may not maintain performance across all channels used by the transmitter in realistic operation. We proposed a training data selection technique to create multi-channel models which outperform single-channel models, improving the cross-channel average MCC from 0.657 to 0.957 and achieving frequency channel-agnostic performance. When evaluated in the presence of noise, multi-channel discriminant analysis models showed reduced performance, but multi-channel neural networks maintained or surpassed single-channel neural network model performance, indicating additional robustness of multi-channel neural networks in the presence of noise.

摘要

射频指纹识别(RFF)常被提议作为无线设备安全的认证机制,但由于现有技术是在使用单频通道的突发信号的情况下创建和评估的,而没有考虑多通道操作的影响,因此在多通道场景中的应用受到限制。我们的研究评估了四种具有不同复杂度的单通道模型的多通道性能,包括一个简单的判别分析模型和三个神经网络。使用多类 Matthews 相关系数(MCC)进行性能特征描述表明,使用除用于训练模型的频率通道之外的频率通道可能会导致性能下降,MCC 从 > 0.9(优秀)下降到 < 0.05(随机猜测),表明单通道模型在实际操作中可能无法在发射器使用的所有通道上保持性能。我们提出了一种训练数据选择技术来创建多通道模型,这些模型的性能优于单通道模型,将跨通道平均 MCC 从 0.657 提高到 0.957,并实现了与频率通道无关的性能。在存在噪声的情况下评估多通道判别分析模型时,其性能会下降,但多通道神经网络保持或超过了单通道神经网络模型的性能,表明多通道神经网络在存在噪声时具有额外的鲁棒性。

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