Logo
ScienceStack
Table of Contents
Fetching ...
Sign In

MIMO FSO Systems in Hybrid Quantum Noise Environments: SKR Analysis with One- and Two-way CV-QKD Protocols

Sushil Kumar, Soumya P. Dash, George C. Alexandropoulos

TL;DR

Numerical results corroborate the proposed analytical secrecy framework, quantifying the SKR gains obtained by employing MIMO and the two-way protocol for FSO CV-QKD systems.

Abstract

This paper studies a multiple-input multiple-output (MIMO) free-space optical (FSO) communication system employing continuous-variable quantum key distribution (CV-QKD), with the goal to support secret key transmission between two legitimate users, Alice and Bob. All involved wireless channels are subjected to atmospheric turbulence leading to beam spreading, pointing error, and turbulence-induced fading, which along with the presence of hybrid quantum noise negatively impact secret key exchange. Furthermore, the legitimate MIMO FSO system faces the threat of compromise from an eavesdropper, Eve, employing a collective Gaussian attack to intercept the secret key exchange. Novel one- and two-way protocols for enhancing the security of the transmitted keys are proposed. To this end, the transmissivity of the FSO channels is mathematically formulated and bounds on the mutual information between the transmitted and received coherent states are obtained, which are then used for deriving novel expressions for the secret key rates (SKRs) for both one- and two-way protocols. The presented numerical results corroborate the proposed analytical secrecy framework, quantifying the SKR gains obtained by employing MIMO and the two-way protocol for FSO CV-QKD systems.

MIMO FSO Systems in Hybrid Quantum Noise Environments: SKR Analysis with One- and Two-way CV-QKD Protocols

TL;DR

Numerical results corroborate the proposed analytical secrecy framework, quantifying the SKR gains obtained by employing MIMO and the two-way protocol for FSO CV-QKD systems.

Abstract

This paper studies a multiple-input multiple-output (MIMO) free-space optical (FSO) communication system employing continuous-variable quantum key distribution (CV-QKD), with the goal to support secret key transmission between two legitimate users, Alice and Bob. All involved wireless channels are subjected to atmospheric turbulence leading to beam spreading, pointing error, and turbulence-induced fading, which along with the presence of hybrid quantum noise negatively impact secret key exchange. Furthermore, the legitimate MIMO FSO system faces the threat of compromise from an eavesdropper, Eve, employing a collective Gaussian attack to intercept the secret key exchange. Novel one- and two-way protocols for enhancing the security of the transmitted keys are proposed. To this end, the transmissivity of the FSO channels is mathematically formulated and bounds on the mutual information between the transmitted and received coherent states are obtained, which are then used for deriving novel expressions for the secret key rates (SKRs) for both one- and two-way protocols. The presented numerical results corroborate the proposed analytical secrecy framework, quantifying the SKR gains obtained by employing MIMO and the two-way protocol for FSO CV-QKD systems.

Paper Structure

This paper contains 16 sections, 66 equations, 10 figures.

Table of Contents

  1. Introduction
  2. System Model
  3. Channel Model
  4. Additive Noise Model
  5. One- and Two-Way MIMO CV-QKD Protocols
  6. One-Way Protocol
  7. Two-Way Protocol
  8. Analysis of the Mutual Information
  9. One-Way Protocol
  10. Two-Way Protocol
  11. SKR Analysis Under Hybrid Quantum Noise
  12. One-Way MIMO FSO CV-QKD
  13. Two-Way MIMO FSO CV-QKD
  14. Asymptotic Analysis
  15. Numerical Results and Discussion
  16. ...and 1 more sections

Figures (10)

  • Figure 1: The considered MIMO FSO CV-QKD system model.
  • Figure 2: The MIMO FSO CV-QKD system model employing the one-way protocol.
  • Figure 3: The MIMO FSO CV-QKD system model with the two-way protocol.
  • Figure 4: $\text{SKR}_{\text{MIMO}}$ vs. distance between Alice and Bob, $z$, for the MIMO configuration $N_T=N_R=\{4, 8, 16, 32\}$, $\lambda_0 = 1$, $\sigma_{\text{g}}^2 = 0.001$, $\eta=1, \beta = 1$, and $C_n^2 = 10^{-15} \text{m}^{-2/3}$.
  • Figure 5: SKR ratio vs. distance between Alice and Bob, $z$, for $N_T=N_R=\{4, 8, 16, 32\}$ MIMO configuration, $\lambda_0 = 1$, $\sigma_{\text{g}}^2 = 0.001$, $\eta=1, \beta = 1$, and $C_n^2 = 10^{-15} \text{m}^{-2/3}$.
  • ...and 5 more figures