Focal Plane Irradiance Statistics for Laser Downlink Beams

Abstract

Laser satellite communications is a growing market for telecommunications services and secure communications. Due to the small footprint of the beam, it provides security, and it can serve as inherently safe communication, using the quantum properties of light, i.e. quantum communications, and quantum key distribution. For quantum communications, the detector sensitivity is of utmost importance. Hence, detector technologies such as Superconducting Nanowire Single Photon Detector (SNSPD), are designated to support optical communications. In this research, we estimate the efficacy of SNSPD arrays for optical downlinks to earth. In this paper, we investigate how spatial resolution of the SNSPD and the spatiotemporal statistics of the incoming turbulence can be matched, in order to effectively use SNSPD arrays. We simulated the downlink using a split-step approach, using a receiver aperture of 1 m and a Fried parameter of 50 and 12.5 cm (D/r₀ is 2 and 8). We obtained the average intensity, the scintillation index, the probability density function (PDF) and the power spectral density (PSD) using 4000 samples. We project instantaneous images on the SNSPD, to estimate how the PSD is distributed. We conclude that stronger turbulence conditions could improve detection performance, because the point spread function (PSD) is wider, and the incident light is distributed over more pixels.