Joint precoding and power allocation in a FSO channel with signal-dependent noise

Renhai Feng; Jingtian Kong; Xinchun Guo; Jiang Wang; Sheng Xie

doi:10.1364/AO.484638

Applied Optics
Vol. 62,
Issue 23,
pp. 6060-6071
(2023)
•https://doi.org/10.1364/AO.484638

Joint precoding and power allocation in a FSO channel with signal-dependent noise

Renhai Feng, Jingtian Kong, Xinchun Guo, Jiang Wang, and Sheng Xie

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Renhai Feng, Jingtian Kong, Xinchun Guo, Jiang Wang, and Sheng Xie, "Joint precoding and power allocation in a FSO channel with signal-dependent noise," Appl. Opt. 62, 6060-6071 (2023)

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Table of Contents Category
- Fiber Optics, Fiber Sensors, and Optical Communications
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About this Article
History
- Original Manuscript: January 5, 2023
- Revised Manuscript: March 20, 2023
- Manuscript Accepted: March 20, 2023
- Published: August 2, 2023

Abstract

To enhance the throughput of visible light communication (VLC), this paper investigates precoding and power allocation jointly in a free space optical channel with signal-dependent noise (SDN-FSO). With the presence of SDN from a light source, a more realistic multi-user multiple-input single-output (MU-MISO) VLC channel model is introduced. First, based on the entropy power inequality, a capacity bound for the SDN-FSO channel is derived under a MU-MISO scenario. Second, due to the nonnegativity of SDN-FSO input, a zero forcing constraint is introduced to alleviate multi-user interference. Third, from the perspective of resource allocation, min-max and total power budget constraints are taken into consideration. A non-convex joint optimization problem is formulated and divided into two subproblems, i.e., the precoding subproblem and power allocation subproblem. Moreover, an iterative algorithm based on a concave and convex program and a simplified high signal-to-noise ratio approximation method are iteratively implemented in the precoding subproblem. For the power allocation subproblem, successive convex approximation is employed to ensure its optimality. Simulation results indicate that the proposed joint optimization methods can converge after about two iterations and accomplish a throughput improvement of up to $1 \sim 3\; {\rm nats}/{\rm s}/{\rm Hz}$ as compared with the benchmarks for four different spacing scenarios. When channel state information is interfered with noise, the proposed methods still demonstrate their superior performance with varying degrees of noise.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Parameter	Value
Room and transmitters configurations
Room dimension	$5 \times 5 \times 3 (m^{3})$
Number of LED arrays $N$	9
Number of LEDs per array	36
Minimum optical power of each LED array $P_{m i n}$	4 W
Maximum optical power of each LED array $P_{max}$	12 W
Half power angle, $ϕ_{1 / 2}$	60°
LED height	3 m
Receiver
Number of PDs, $K$	3
Effective area of PD, $A_{r}$	$1 {c m}^{2}$
FOV, $Ψ_{c}$	50°
Gain of optical filter, $T_{s} (ψ)$	1
Refractive index of the concentrator, $κ$	1.5
Receiver orientation axis	(0,0,1)
PD height	0.85 m
Modulation format	2-PAM

Parameter	Value
Room and transmitters configurations
Room dimension	$5 \times 5 \times 3 (m^{3})$
Number of LED arrays $N$	9
Number of LEDs per array	36
Minimum optical power of each LED array $P_{m i n}$	4 W
Maximum optical power of each LED array $P_{max}$	12 W
Half power angle, $ϕ_{1 / 2}$	60°
LED height	3 m
Receiver
Number of PDs, $K$	3
Effective area of PD, $A_{r}$	$1 {c m}^{2}$
FOV, $Ψ_{c}$	50°
Gain of optical filter, $T_{s} (ψ)$	1
Refractive index of the concentrator, $κ$	1.5
Receiver orientation axis	(0,0,1)
PD height	0.85 m
Modulation format	2-PAM

Abstract

Data availability

Cited By

Figures (8)

Tables (4)

Equations (73)

Applied Optics