Comparison between continuous wave and pulsed laser EQKD systems

TL;DR

This paper compares continuous-wave and pulsed laser entangled quantum key distribution systems, analyzing how photon statistics influence secret bit rates and identifying optimal performance regimes for each approach.

Contribution

It provides a complete quantum state description and comparative analysis of secret bit rates for both system types using practical parameters.

Findings

Photon statistics significantly impact secret bit rates.

Optimal performance regimes differ between continuous-wave and pulsed systems.

Complete quantum state modeling improves understanding of EQKD system capabilities.

Abstract

Advances in quantum physics and computational complexity threaten the security of present day cryptographic systems and have driven the development of quantum key distribution (QKD). Entangled quantum key distribution (EQKD) is a secure protocol that is based on fundamental quantum mechanics and is not vulnerable to these threats. The primary figure of merit for QKD systems is ability to generate secret bits. However, to date, methods that have been developed to simulate the secret bit rate generation for EQKD systems have been limited by techniques that do not provide a complete description of the quantum state produced by the source. In this paper, we provide a complete description and comparison of the secret bit rate for continuous-wave and pulsed laser EQKD systems. In particular, we highlight the relevant Poissonian and thermal photon statistics that affect the EQKD secret bit rate and use practical system parameters and configurations to show regimes where one expects optimal performance for each case.