AquaKey: Exploiting the Randomness of the Underwater Visible Light Communication Channel for Key Extraction

Lupeng Zhang, Pingchuan Wang, Minhao Cui, Jingwen Wei, Yu Tian, Jingchi Zhang, Jie Xiong, Lei Wang
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Abstract

Underwater Visible Light Communication (UVLC) is promising due to its relatively strong penetration capability in water and large frequency bandwidth. Visible Light Communication (VLC) is also considered a safer wireless communication paradigm as light signals can be constrained within the area of interest with obstacles such as walls, reducing the chance of potential attack. However, this intuitional security assumption is not true anymore in underwater environment. Recent research shows that the eavesdropping risk of UVLC is more severe than we thought, attributed to the divergence and scattering effects of light beams in water. In this paper, we harness the dynamic nature of underwater environments as a true random resource to extract symmetric keys for UVLC. Specifically, the proposed AquaKey system incorporates instantaneous bidirectional channel probing, computation of relative channel characteristics, and an environment-adaptive quantization algorithm. The above design addresses unique challenges caused by the dynamic underwater environment, including self-interference, high-frequency disturbance, and mismatch, ensuring the practicality and applicability of AquaKey. Additionally, AquaKey has negligible impact on communication and has no effect on the illumination function. Through extensive real-world experiments, we show that AquaKey can achieve reliable key extraction with cheap hardware, generating a 512-bit key in just 0.5-1 seconds.
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AquaKey:利用水下可见光通信信道的随机性提取密钥
水下可见光通信(UVLC)因其在水中相对较强的穿透能力和较大的频率带宽而前景广阔。可见光通信(VLC)也被认为是一种更安全的无线通信模式,因为光信号可以通过墙壁等障碍物限制在感兴趣的区域内,从而减少潜在攻击的机会。然而,这种直观的安全假设在水下环境中不再适用。最新研究表明,由于光束在水中的发散和散射效应,UVLC 的窃听风险比我们想象的要严重得多。在本文中,我们利用水下环境的动态特性作为真正的随机资源,为 UVLC 提取对称密钥。具体来说,所提出的 AquaKey 系统包含瞬时双向信道探测、相对信道特性计算和环境适应量化算法。上述设计解决了动态水下环境带来的独特挑战,包括自干扰、高频干扰和不匹配,确保了 AquaKey 的实用性和适用性。此外,AquaKey 对通信的影响可以忽略不计,对照明功能也没有影响。通过大量实际实验,我们证明 AquaKey 可以用廉价的硬件实现可靠的密钥提取,只需 0.5-1 秒即可生成 512 位密钥。
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