Proof of concept for adaptive sequential optimization of free-space communication receivers

Carlos E. Carrizo; Ramon Mata Calvo; Aniceto Belmonte

doi:10.1364/AO.58.005397

Applied Optics
Vol. 58,
Issue 20,
pp. 5397-5403
(2019)
•https://doi.org/10.1364/AO.58.005397

Proof of concept for adaptive sequential optimization of free-space communication receivers

Carlos E. Carrizo, Ramon Mata Calvo, and Aniceto Belmonte

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Carlos E. Carrizo, Ramon Mata Calvo, and Aniceto Belmonte, "Proof of concept for adaptive sequential optimization of free-space communication receivers," Appl. Opt. 58, 5397-5403 (2019)

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Related Topics
Table of Contents Category
- Fiber Optics, Fiber Sensors, and Optical Communications
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About this Article
History
- Original Manuscript: March 27, 2019
- Revised Manuscript: June 6, 2019
- Manuscript Accepted: June 8, 2019
- Published: July 5, 2019

Abstract

In a downlink scenario, the performance of laser satellite communications is limited due to atmospheric turbulence, which causes fluctuations in the intensity and the phase of the received signal, leading to an increase in bit error probability. In principle, a single-aperture phase-compensated receiver, based on adaptive optics, can overcome atmospheric limitations by adaptive tracking and correction of atmospherically induced aberrations. However, under strong turbulence situations, the effectiveness of traditional adaptive optics systems is severely compromised. We have developed an alternative intensity-based technique that corrects the wavefront by iteratively updating the phases of individual focal-plane speckles, which maximizes the power coupled into a single-mode fiber. Here, we present the proof of concept for this method. We show how this technique offers around 4 dB power gain with fewer than 60 power measurements under strong turbulence conditions. It delivers a good performance in different turbulent regimes, and it shows robustness against severe deterioration of the signal-to-noise ratio.

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Hardware	Type	Details
LASER	TeraXion PS-LM	$1550 nm \| P_{\max} = 100 mW$
SLM	Hamamatsu X10468-LCOS	$Windows = 15.8 \times 12 mm$
		$800 pixels \times 600 pixels \| 20 μm pixel$ pitch
		$Resolution = 25 lp / mm$
TTM	Newport FSM-300	$Angular Range = \pm 26.2 mrad$
		$Closed-loop = 600 Hz$
		$Resolution = 3 μ rad$
CAM 1	Xenics Cheetah 640-CL	InGaAs sensor $640 \times 512$ pixels
		$ADC \| Pixel Size = 12 bits \| 20 μm$
		$Frame rate = 400 Hz (Full frame)$
CAM 2	Xenics Xeva XS-1.7-320	InGaAs sensor $320 \times 256$ pixels
		$ADC \| Pixel Size = 12 bits \| 30 μm$
		$Frame rate = 100 Hz (Full)$
DM	BMC Multi-X-CL140-DM	$Membrane \| 12 \times 12 actuators$
		$Max. Stroke = 3.7 μm$
		$Mirror BW = 3.5 KHz$
APD	Thorlabs PDA20CS-EC	$InGaAs \| Gain : 0 - 70 dB$
DAQ	NI BNC-2110\|PCI-6221	12 bits
VOA	Thorlabs VOA50	50 dB

AO System	Speckle-Based Iterative	Stochastic Iterative	SH. Sensor
Resolution	low	low	low
Robustness singularities	high (to be verified)	high	low
Robustness scintillation	medium (to be verified)	medium	low
Hardware complexity	low	very low	medium
Reconstruction speed	$\leq 60$	$> 100$	real-time
Robustness noise	high	high	low
Adaptability	high	low	low

Hardware	Type	Details
LASER	TeraXion PS-LM	$1550 nm \| P_{\max} = 100 mW$
SLM	Hamamatsu X10468-LCOS	$Windows = 15.8 \times 12 mm$
		$800 pixels \times 600 pixels \| 20 μm pixel$ pitch
		$Resolution = 25 lp / mm$
TTM	Newport FSM-300	$Angular Range = \pm 26.2 mrad$
		$Closed-loop = 600 Hz$
		$Resolution = 3 μ rad$
CAM 1	Xenics Cheetah 640-CL	InGaAs sensor $640 \times 512$ pixels
		$ADC \| Pixel Size = 12 bits \| 20 μm$
		$Frame rate = 400 Hz (Full frame)$
CAM 2	Xenics Xeva XS-1.7-320	InGaAs sensor $320 \times 256$ pixels
		$ADC \| Pixel Size = 12 bits \| 30 μm$
		$Frame rate = 100 Hz (Full)$
DM	BMC Multi-X-CL140-DM	$Membrane \| 12 \times 12 actuators$
		$Max. Stroke = 3.7 μm$
		$Mirror BW = 3.5 KHz$
APD	Thorlabs PDA20CS-EC	$InGaAs \| Gain : 0 - 70 dB$
DAQ	NI BNC-2110\|PCI-6221	12 bits
VOA	Thorlabs VOA50	50 dB

AO System	Speckle-Based Iterative	Stochastic Iterative	SH. Sensor
Resolution	low	low	low
Robustness singularities	high (to be verified)	high	low
Robustness scintillation	medium (to be verified)	medium	low
Hardware complexity	low	very low	medium
Reconstruction speed	$\leq 60$	$> 100$	real-time
Robustness noise	high	high	low
Adaptability	high	low	low

Abstract

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Tables (2)

Equations (7)

Applied Optics