Influence of detection noise on the maximum likelihood estimation of
atmospheric turbulence fading parameters

Dan Chen; Yue Gao; Huiqin Wang; Yuan Liu; Yeqin Cao

doi:10.1364/AO.465458

Applied Optics
Vol. 61,
Issue 24,
pp. 7265-7272
(2022)
•https://doi.org/10.1364/AO.465458

Influence of detection noise on the maximum likelihood estimation of atmospheric turbulence fading parameters

Dan Chen, Yue Gao, Huiqin Wang, Yuan Liu, and Yeqin Cao

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Dan Chen, Yue Gao, Huiqin Wang, Yuan Liu, and Yeqin Cao, "Influence of detection noise on the maximum likelihood estimation of atmospheric turbulence fading parameters," Appl. Opt. 61, 7265-7272 (2022)

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Abstract

Free space optical system design and performance analysis are highly related to channel statistics obtained by the channel parameter estimation. The accurate estimation of the channel parameters and scintillation index needs to consider the photoelectric detection noise at the receiving end. We propose a maximum likelihood (ML) method for estimating the parameters of a gamma–gamma fading channel affected by photoelectric detection noise. The Newton–Raphson method and expectation maximization (EM) algorithm are developed to compute the ML estimates of atmospheric turbulence fading parameters and variance of the detection noise. We also derive the Cramer–Rao bound for the unknown parameters. By way of the mean square estimation errors, our estimation technique performance is compared with existing methods of the estimation which ignore detection noise. Based on the measured channel and detection noise data under three weather conditions, it is verified that the proposed EM algorithm, considering the influence of detection noise, can significantly improve the estimation accuracy of atmospheric turbulence fading parameters.

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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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Channel Parameters ( $α$ )	EM Algorithm (times)	N–R Method (times)	EM/N–R (ratio of iterations)
1	69	29	2.379
2	80	34	2.352
3	90	39	2.307
4	96	43	2.232

Date	Time	Temp	Humidity	Wind Scale	Cloud Cover	Rainfall	Weather
22.5.13	10:00–13:00	18°C	33%	2	91%	/	Overcast
22.5.13	14:00–19:00	17°C	57%	3	26%	/	Sunny day after rain
22.5.12	18:00–23:00	13°C	95%	3	81%	2 mm	Light rain

/	Detection Noise Parameters	/	$\hat{α}$	$\hat{β}$	${σ_{I}}^{2}$	$R^{2}$
Overcast	$μ_{o} = 3.4203$	Calculation by Eq. (34)	/	/	0.0393	0.9203
	$σ_{o}^{2} = 0.1478$	EM algorithm (considering noise)	55.09	45.56	0.0396	0.9390
		EM algorithm (Ignoring noise)	46.18	39.85	0.0473	0.8973
Sunny day after rain	$μ_{s} = 3.7559$	Calculation by Eq. (34)	/	/	0.0301	0.9194
	$σ_{s}^{2} = 0.1591$	EM algorithm (considering noise)	67.25	62.16	0.0311	0.9271
		EM algorithm (Ignoring noise)	56.72	50.24	0.0379	0.9027
Light rain	$μ_{l} = 2.0165$	Calculation by Eq. (34)	/	/	0.0564	0.9010
	$σ_{l}^{2} = 0.1404$	EM algorithm (considering noise)	36.54	31.48	0.0600	0.9332
		EM algorithm (Ignoring noise)	30.71	25.24	0.0735	0.9199

Channel Parameters ( $α$ )	EM Algorithm (times)	N–R Method (times)	EM/N–R (ratio of iterations)
1	69	29	2.379
2	80	34	2.352
3	90	39	2.307
4	96	43	2.232

Date	Time	Temp	Humidity	Wind Scale	Cloud Cover	Rainfall	Weather
22.5.13	10:00–13:00	18°C	33%	2	91%	/	Overcast
22.5.13	14:00–19:00	17°C	57%	3	26%	/	Sunny day after rain
22.5.12	18:00–23:00	13°C	95%	3	81%	2 mm	Light rain

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Applied Optics