Highlighted Paper!

18.02.2019

Our Publication on Continuous‐Variable Quantum Key Distribution with Gaussian Modulation—The Theory of Practical Implementations was highlighted in Advanced Science News.

"Quantum key distribution (QKD) is considered the most advanced direct application of the strange laws of quantum physics, including the Heisenberg uncertainty principle, the superposition principle, quantum entanglement, and the no-cloning theorem. Harnessing these phenomena, QKD enables two distant parties to establish a sequence of bits, i.e., an encryption key, which is identical on both sides, entirely random, and exclusively known by the two trusted communicators. These three conditions are essential for information-theoretic communication security and allow for bug-proof information exchange; no eavesdropper is, by physical law and regardless of their technological capabilities, able to obtain any useful knowledge on the cryptographic key without being noticed. (...)"

Read the full Advanced Science News article here.


Abstract of the publication:

Quantum key distribution (QKD) using weak coherent states and homodyne detection is a promising candidate for practical quantum‐cryptographic implementations due to its compatibility with existing telecom equipment and high detection efficiencies. However, despite the actual simplicity of the protocol, the security analysis of this method is rather involved compared to discrete‐variable QKD. This article reviews the theoretical foundations of continuous‐variable quantum key distribution (CV‐QKD) with Gaussian modulation and rederives the essential relations from scratch in a pedagogical way. The aim of this paper is to be as comprehensive and self‐contained as possible in order to be well intelligible even for readers with little pre‐knowledge on the subject. Although the present article is a theoretical discussion of CV‐QKD, its focus lies on practical implementations, taking into account various kinds of hardware imperfections and suggesting practical methods to perform the security analysis subsequent to the key exchange. Apart from a review of well‐known results, this manuscript presents a set of new original noise models which are helpful to get an estimate of how well a given set of hardware will perform in practice.

Read the full publication here.