Wireless Qunatum-Key Distribution in RF and Microwave Frequencies

2006 IEEE 7th Workshop on Signal Processing Advances in Wireless Communications Pub Date : 2006-07-02 DOI:10.1109/SPAWC.2006.346361

N. Jam, S. Khorsandi, M. Dehghan

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Abstract

The uncertainty principle says that when elementary quantum systems like photons are used for information transmission, it is impossible in principle to eavesdrop on this media without a high probability of disturbing the transmission in such a way as to be detected. By this way we can make an absolutely secure communication link which can not be threaten by any kind of cheating by an opponent with unlimited computing power. Until now quantum transmission of digital information has been implemented using polarized photon transmission over dark fibers or optical wireless links mainly for random key distribution. In this paper we will use the same idea of uncertainty principle to show the possibility of generating weak photons in the microwave and RF range in such a way that it is impossible to measure the waveform generated by these photons without altering the waveform. The inherent problems of optical quantum systems show the advantages of this technique that includes: less range limitation, lower influence of environment and whether on the link, fast deployment and lower cost of equipments

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射频和微波频率下的无线量子密钥分布

测不准原理说，当像光子这样的基本量子系统被用于信息传输时，如果不以一种被检测到的方式干扰传输，原则上是不可能窃听这种媒介的。通过这种方式，我们可以建立一个绝对安全的通信链路，不受具有无限计算能力的对手的任何欺骗的威胁。到目前为止，数字信息的量子传输主要采用暗光纤或光无线链路上的偏振光子传输，主要用于随机密钥分发。在本文中，我们将使用不确定原理的相同思想来显示在微波和射频范围内产生弱光子的可能性，这样就不可能在不改变波形的情况下测量这些光子产生的波形。光量子系统固有的问题表明了该技术的优势:距离限制小，环境和链路影响小，部署速度快，设备成本低

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2006 IEEE 7th Workshop on Signal Processing Advances in Wireless Communications

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