Abstract
Quantum key distribution (QKD) is the best candidate for securing communications against attackers, who may in the future exploit quantum-enhanced computational powers to break classical encryption. As such, new challenges are arising from our need for large-scale deployment of QKD systems. In a realistic scenario, transmitting and receiving devices from different vendors should be able to communicate with each other without the need for matching hardware. Therefore, practical deployment of QKD would require hardware capable of adapting to different protocols and clock rates. Here, we address this challenge by presenting a multi-rate, multi-protocol QKD transmitter linked to a correspondingly adaptable QKD receiver. The flexibility of the transmitter, achieved by optical injection locking, allows us to connect it with two receivers with inherently different clock rates. Furthermore, we demonstrate the multi-protocol operation of our transmitter, communicating with receiving parties employing different decoding circuits.
Highlights
Quantum key distribution (QKD) allows users to communicate with information theoretical security [1]
The system stabilization happens within a few seconds, without loss of integrity or degradation of the quantum bit error rate (QBER) or secure key rates (SKRs) afterwards
The comparison between the SKRs obtained with the BB84 [21], differential phase shift (DPS) [22], and coherent one way (COW) [23] protocols should take this into account
Summary
Quantum key distribution (QKD) allows users to communicate with information theoretical security [1]. There have been many impressive demonstrations of point-to-point QKD over fiber links, including key sharing at 10 Mbit/s [4] and at a distance of 421 km [5] for a point-to-point link of optical fiber Such distances can be further improved due to the novel twin-field QKD protocol [6], which has the capability to reach more than 500 km [7,8]. [9] Much of the current research within QKD aims at improving specific systems, while little consideration is given to interoperability between different systems This has led to the situation where dedicated hardware is required to implement separate protocols and to operate at a fixed clock rate. The system stabilization happens within a few seconds, without loss of integrity or degradation of the quantum bit error rate (QBER) or secure key rates (SKRs) afterwards
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