Abstract
We present the results from a Monte Carlo computer simulation of adaptive optics (AO) pre-compensated laser uplink propagation through the Earth's atmospheric turbulence from the ground to orbiting satellites. The simulation includes the so-called point-ahead angle and tests several potential AO mitigation modes such as tip/tilt or full AO from the downlink beam, and a laser guide star at the point ahead angle. The performance of these modes, as measured by metrics relevant for free-space optical communication, are compared with no correction and perfect correction. The aim of the study is to investigate fundamental limitations of free-space optical communications with AO pre-compensation and a point-ahead angle, therefore the results represent an upper bound of AO corrected performance, demonstrating the potential of pre-compensation technology. Performance is assessed with varying launch aperture size, wavelength, launch geometry, ground layer turbulence strength (i.e. day/night), elevation angle and satellite orbit (Low-Earth and Geostationary). By exploring this large parameter space we are able examine trends on performance with the aim of informing the design of future optical ground stations and demonstrating and quantifying the potential upper bounds of adaptive optics performance in free-space optical communications.
Highlights
Laser propagation between the ground and space is used for free space optical communications (FSOC) [1,2] to securely transfer data at high-data rates
In FSOC the fluctuations in received intensity due to the atmospheric channel lead to fade and surge events increasing the Bit-Error-Rate (BER) and significantly limiting the achievable bandwidth [5]. Both of these phenomena can be mitigated with adaptive optics (AO) systems that can be used to pre-compensate the laser beam to correct for the detrimental effects of the atmospheric channel
We aim to determine if AO can enable larger launch apertures, effectively reducing the geometric beam divergence whist mitigating the effects of the turbulence
Summary
Laser propagation between the ground and space is used for free space optical communications (FSOC) [1,2] to securely transfer data at high-data rates. In FSOC the fluctuations in received intensity due to the atmospheric channel lead to fade and surge events increasing the Bit-Error-Rate (BER) and significantly limiting the achievable bandwidth [5]. Both of these phenomena can be mitigated with adaptive optics (AO) systems that can be used to pre-compensate the laser beam to correct for the detrimental effects of the atmospheric channel (see for example [6,7,8,9])
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
