Adaptive total variation-based spectral deconvolution with the split Bregman method

Hai Liu; Sanya Liu; Zhaoli Zhang; Jianwen Sun; Jiangbo Shu

doi:10.1364/AO.53.008240

Applied Optics
Vol. 53,
Issue 35,
pp. 8240-8248
(2014)
•https://doi.org/10.1364/AO.53.008240

Adaptive total variation-based spectral deconvolution with the split Bregman method

Hai Liu, Sanya Liu, Zhaoli Zhang, Jianwen Sun, and Jiangbo Shu

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Hai Liu, Sanya Liu, Zhaoli Zhang, Jianwen Sun, and Jiangbo Shu, "Adaptive total variation-based spectral deconvolution with the split Bregman method," Appl. Opt. 53, 8240-8248 (2014)

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Abstract

Spectroscopic data often suffer from common problems of band overlap and noise. This paper presents a maximum a posteriori (MAP)-based algorithm for the band overlap problem. In the MAP framework, the likelihood probability density function (PDF) is constructed with Gaussian noise assumed, and the prior PDF is constructed with adaptive total variation (ATV) regularization. The split Bregman iteration algorithm is employed to optimize the ATV spectral deconvolution model and accelerate the speed of the spectral deconvolution. The main advantage of this algorithm is that it can obtain peak structure information as well as suppress noise simultaneity. Simulated and real spectra experiments manifest that this algorithm can satisfactorily recover the overlap peaks as well as suppress noise and are robust to the regularization parameter.

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Band Position^a		1394.1	2273.4	2931.8	2966.3	RMSE^b
Position	SDTR	$- 1.3$	$+ 1.1$	$+ 1.2$	$+ 2.1$	1.455
	HOS	$+ 1.5$	$- 2.4$	$+ 1.4$	$+ 2.9$	2.272
	SDTV	$+ 0.3$	$- 2.2$	$- 1.1$	$+ 1.2$	1.502
	SDATV	$+ 0.1$	$- 0.9$	$- 0.8$	$+ 0.2$	0.580
Height	SDTR	$- 0.249$	$- 0.089$	$- 0.171$	$- 0.172$	0.065
	HOS	—	—	—	—	—
	SDTV	$- 0.199$	$- 0.073$	$- 0.124$	$- 0.119$	0.052
	SDATV	$- 0.103$	$- 0.034$	$- 0.107$	$- 0.095$	0.034

		Methods
Merits	Noise Level (SNR)	SDTR [19]	HOS [6]	SDATV
NMSE	Noise-free	0.0195	0.0216	0.0105
	200	0.0203	0.0224	0.0124
	100	0.0358	0.0407	0.0159
WCC	Noise-free	0.9994	0.9992	0.9996
	200	0.9989	0.9985	0.9991
	100	0.9977	0.9978	0.9984

IR Spectra	SDTR [19] (s)	HOS [6] (s)	SDATV (s)
Malononitrile	23.125	20.156	1.945
Cyclohexanol	20.365	17.524	1.726
Propyl acetate	22.345	19.972	1.885
Mesityl oxide	21.861	18.564	1.804

Band Position^a		1394.1	2273.4	2931.8	2966.3	RMSE^b
Position	SDTR	$- 1.3$	$+ 1.1$	$+ 1.2$	$+ 2.1$	1.455
	HOS	$+ 1.5$	$- 2.4$	$+ 1.4$	$+ 2.9$	2.272
	SDTV	$+ 0.3$	$- 2.2$	$- 1.1$	$+ 1.2$	1.502
	SDATV	$+ 0.1$	$- 0.9$	$- 0.8$	$+ 0.2$	0.580
Height	SDTR	$- 0.249$	$- 0.089$	$- 0.171$	$- 0.172$	0.065
	HOS	—	—	—	—	—
	SDTV	$- 0.199$	$- 0.073$	$- 0.124$	$- 0.119$	0.052
	SDATV	$- 0.103$	$- 0.034$	$- 0.107$	$- 0.095$	0.034

		Methods
Merits	Noise Level (SNR)	SDTR [19]	HOS [6]	SDATV
NMSE	Noise-free	0.0195	0.0216	0.0105
	200	0.0203	0.0224	0.0124
	100	0.0358	0.0407	0.0159
WCC	Noise-free	0.9994	0.9992	0.9996
	200	0.9989	0.9985	0.9991
	100	0.9977	0.9978	0.9984

Abstract

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Tables (4)

Equations (20)

Applied Optics