When LoRa Meets EMR: Electromagnetic Covert Channels Can Be Super Resilient

Cheng Shen, T. Liu, Jun Huang, Rui Tan
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引用次数: 27

Abstract

Due to the low power of electromagnetic radiation (EMR), EM convert channel has been widely considered as a short-range attack that can be easily mitigated by shielding. This paper overturns this common belief by demonstrating how covert EM signals leaked from typical laptops, desktops and servers are decoded from hundreds of meters away, or penetrate aggressive shield previously considered as sufficient to ensure emission security. We achieve this by designing EMLoRa – a super resilient EM covert channel that exploits memory as a LoRa-like radio. EMLoRa represents the first attempt of designing an EM covert channel using state-of-the-art spread spectrum technology. It tackles a set of unique challenges, such as handling complex spectral characteristics of EMR, tolerating signal distortions caused by CPU contention, and preventing adversarial detectors from demodulating covert signals. Experiment results show that EMLoRa boosts communication range by 20x and improves attenuation resilience by up to 53 dB when compared with prior EM covert channels at the same bit rate. By achieving this, EMLoRa allows an attacker to circumvent security perimeter, breach Faraday cage, and localize air-gapped devices in a wide area using just a small number of inexpensive sensors. To countermeasure EMLoRa, we further explore the feasibility of uncovering EMLoRa's signal using energy- and CNN-based detectors. Experiments show that both detectors suffer limited range, allowing EMLoRa to gain a significant range advantage. Our results call for further research on the countermeasure against spread spectrum-based EM covert channels.
当LoRa遇到EMR:电磁隐蔽信道可以具有超级弹性
由于电磁辐射(EMR)的低功率,电磁转换信道被广泛认为是一种可以很容易地通过屏蔽来减轻的近距离攻击。这篇论文推翻了这种普遍的看法,它展示了从典型的笔记本电脑、台式电脑和服务器泄露的隐蔽电磁信号是如何在数百米外被解码的,或者如何穿透以前被认为足以确保发射安全的侵略性屏蔽。我们通过设计EMLoRa来实现这一目标,EMLoRa是一种超级弹性的EM隐蔽信道,利用存储器作为LoRa-like无线电。EMLoRa代表了使用最先进的扩频技术设计EM隐蔽信道的第一次尝试。它解决了一系列独特的挑战,例如处理EMR的复杂频谱特性,容忍由CPU争用引起的信号失真,以及防止对抗性检测器解调隐蔽信号。实验结果表明,在相同比特率下,EMLoRa与现有的EM隐蔽信道相比,通信范围提高了20倍,衰减恢复能力提高了53 dB。通过实现这一点,EMLoRa允许攻击者绕过安全边界,突破法拉第笼,并使用少量廉价的传感器在大范围内定位气隙设备。为了对抗EMLoRa,我们进一步探索了使用基于能量和cnn的检测器来发现EMLoRa信号的可行性。实验表明,这两种探测器的距离都是有限的,这使得EMLoRa获得了显著的距离优势。我们的研究结果要求对基于扩频的EM隐蔽信道的对策进行进一步的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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