Guillem Reus Muns, Dheryta Jaisinghani, K. Sankhe, K. Chowdhury
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引用次数: 32
摘要
5G和开放式无线接入网络(open ran)将导致供应商中立的硬件部署,这将需要额外的尽职调查来管理安全风险。这种新模式将允许相同的网络基础设施在不同时间支持传输不同波形的虚拟网络切片,例如5G new Radio、LTE、WiFi。在这种多供应商、多协议/波形设置中,我们提出了一种额外的物理层身份验证方法,该方法通过一种称为射频指纹的技术检测特定的发射器。我们的深度学习方法使用带有三重损失增强的卷积神经网络,其中在训练期间向分类器显示相似/不相似信号样本的示例。我们在美国犹他州盐湖城的大规模空中实验POWDER平台上演示了射频指纹基站的可行性。使用真实世界的数据集,我们展示了我们的方法如何克服改变信道条件和协议选择所带来的挑战,在不同的训练和测试日具有99.86%的检测准确率。
Trust in 5G Open RANs through Machine Learning: RF Fingerprinting on the POWDER PAWR Platform
5G and open radio access networks (Open RANs) will result in vendor-neutral hardware deployment that will require additional diligence towards managing security risks. This new paradigm will allow the same network infrastructure to support virtual network slices for transmit different waveforms, such as 5G New Radio, LTE, WiFi, at different times. In this multivendor, multi-protocol/waveform setting, we propose an additional physical layer authentication method that detects a specific emitter through a technique called as RF fingerprinting. Our deep learning approach uses convolutional neural networks augmented with triplet loss, where examples of similar/dissimilar signal samples are shown to the classifier over the training duration. We demonstrate the feasibility of RF fingerprinting base stations over the large-scale over-the-air experimental POWDER platform in Salt Lake City, Utah, USA. Using real world datasets, we show how our approach overcomes the challenges posed by changing channel conditions and protocol choices with 99.86% detection accuracy for different training and testing days.
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