We consider discrete-alphabet encoding schemes for coherent-state quantum key distribution. The sender encodes the letters of a finite-size alphabet into coherent states whose amplitudes are symmetrically distributed on a circle centered in the origin of the phase space. We study the asymptotic performance of this phase-encoded coherent-state protocol in direct and reverse reconciliation assuming both loss and thermal noise in the communication channel. In particular, we show that using just four phase-shifted coherent states is sufficient for generating secret-key rates of the order of 4×10^(−3) bits per channel use at about 15 dB loss in the presence of realistic excess noise.
Quantum key distribution with phase-encoded coherent states: Asymptotic security analysis in thermal-loss channels / Papanastasiou, P.; Lupo, C.; Weedbrook, C.; Pirandola, S.. - In: PHYSICAL REVIEW A. - ISSN 2469-9926. - 98:1(2018). [10.1103/PhysRevA.98.012340]
Quantum key distribution with phase-encoded coherent states: Asymptotic security analysis in thermal-loss channels
C. Lupo;
2018-01-01
Abstract
We consider discrete-alphabet encoding schemes for coherent-state quantum key distribution. The sender encodes the letters of a finite-size alphabet into coherent states whose amplitudes are symmetrically distributed on a circle centered in the origin of the phase space. We study the asymptotic performance of this phase-encoded coherent-state protocol in direct and reverse reconciliation assuming both loss and thermal noise in the communication channel. In particular, we show that using just four phase-shifted coherent states is sufficient for generating secret-key rates of the order of 4×10^(−3) bits per channel use at about 15 dB loss in the presence of realistic excess noise.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
