An Emphasis on Quantum Cryptography and Quantum Key Distribution

Cryptography - Recent Advances and Future Developments Pub Date : 2021-02-05 DOI:10.5772/INTECHOPEN.95383

Bharadwaja V. Srividya, S. Sasi

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引用次数: 1

Abstract

The application of internet has spiked up in the present-day scenario, as the exchange of information made between two parties happens in public environment. Hence privacy of information plays an important role in our day to day life. There have been incredible developments made in the field of cryptography resulting in modern cryptography at its zenith. Quantum computers are one among them creating fear into security agencies across the world. Solving the complex mathematical calculations is uncomplicated using quantum computers which results in breaking the keys of modern cryptography, which cannot be broken using classical computers. The concept of quantum physics, into the cryptographic world has resulted in the advancement of quantum cryptography. This technique utilizes the idea of key generation by photons, and communicates between peer entities by secured channel. Quantum cryptography adapts quantum mechanical principles like Heisenberg Uncertainty principle and photon polarization principle to provide secure communication between two parties. This article focuses on generation of a secret shared key, later converted into Quantum bits (Qbits) and transmitted to the receiver securely.

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量子密码学与量子密钥分发研究

在当今的场景中，互联网的应用激增，因为双方之间的信息交换发生在公共环境中。因此，信息隐私在我们的日常生活中起着重要的作用。密码学领域取得了令人难以置信的发展，使现代密码学达到了顶峰。量子计算机是让世界各地的安全机构感到恐惧的技术之一。使用量子计算机解决复杂的数学计算并不复杂，从而可以破解传统计算机无法破解的现代密码学密钥。量子物理学的概念，进入了密码学的世界，导致了量子密码学的进步。该技术利用光子生成密钥的思想，通过安全信道在对等实体之间进行通信。量子密码学采用海森堡测不准原理、光子偏振原理等量子力学原理，为双方通信提供安全保障。本文重点介绍秘密共享密钥的生成，然后将其转换为量子比特(Qbits)并安全地传输给接收者。

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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Cryptography - Recent Advances and Future Developments

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