Bandwidth correction of spectral measurement based on Levenberg&#x2013;Marquardt algorithm with improved Tikhonov regularization

Chan Huang; Yuyang Chang; Lin Han; Feinan Chen; Shuang Li; Jing Hong

doi:10.1364/AO.58.002166

Applied Optics
Vol. 58,
Issue 9,
pp. 2166-2173
(2019)
•https://doi.org/10.1364/AO.58.002166

Bandwidth correction of spectral measurement based on Levenberg–Marquardt algorithm with improved Tikhonov regularization

Chan Huang, Yuyang Chang, Lin Han, Feinan Chen, Shuang Li, and Jing Hong

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Chan Huang, Yuyang Chang, Lin Han, Feinan Chen, Shuang Li, and Jing Hong, "Bandwidth correction of spectral measurement based on Levenberg–Marquardt algorithm with improved Tikhonov regularization," Appl. Opt. 58, 2166-2173 (2019)

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Table of Contents Category
- Instrumentation and Measurements
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About this Article
History
- Original Manuscript: January 2, 2019
- Revised Manuscript: February 20, 2019
- Manuscript Accepted: February 22, 2019
- Published: March 13, 2019

Abstract

Spectroscopic data often suffers from spectral distortions due to the broadening effects of the spectrometer. In this paper, the issue of bandwidth correction is transformed into a multiparameter optimization problem, and an improved bandwidth correction method based on the Levenberg–Marquardt algorithm with improved Tikhonov regularization is presented. Example LED, Raman, and compact fluorescent lamp spectra were corrected with the proposed method, the Richardson–Lucy method, and the maximum a posterior method, and the correction errors and runtimes under the same stopping conditions of each method were compared. The experimental results show that the proposed method can be applied to different spectra with excellent correction.

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Method	Author	Commonalities	Differences
S-S	E. I. Stearns	Noniterative algorithm, sensitive to noise	The method requires that the bandwidth shape be triangular and the bandwidth size must be equal to the data interval
Improved S-S	Y. Ohno		The method is an improvement of S-S method, the bandwidth function can be of any shape
DO	E. R. Woolliams		The method enlarges the data interval as a regularization method, which sacrifices part of the effective information to reduce the sensitivity to noise
R-L	S. Eichstädt	Iterative algorithm, insensitive to noise	R-L algorithm combines a new stopping rule, stopping iteration before convergence to avoid over-fitting
L-M	S. Q. Jin		The L-M algorithm combines with the He-Zheng LED model. Using the LED model to reduce the noise of the LED spectra as a means of regularization.
MAP	H. Liu		A gradient descent method with slow convergence rate

Method	Spectrum
Method	White LED	Raman	CFL
LMTR	89.352	210.361	178.009
LMITR	71.811	156.917	155.394
R-L	113.541	142.915	160.308
MAP	87.014	190.845	171.228

Method	Spectrum
Method	White LED	Raman	CFL
LMTR	0.182 s	0.342 s	0.395 s
LMITR	0.176 s	0.321 s	0.241 s
R-L	0.236 s	0.428 s	0.493 s
MAP	18.064 s	28.796 s	30.211 s

Method	Author	Commonalities	Differences
S-S	E. I. Stearns	Noniterative algorithm, sensitive to noise	The method requires that the bandwidth shape be triangular and the bandwidth size must be equal to the data interval
Improved S-S	Y. Ohno		The method is an improvement of S-S method, the bandwidth function can be of any shape
DO	E. R. Woolliams		The method enlarges the data interval as a regularization method, which sacrifices part of the effective information to reduce the sensitivity to noise
R-L	S. Eichstädt	Iterative algorithm, insensitive to noise	R-L algorithm combines a new stopping rule, stopping iteration before convergence to avoid over-fitting
L-M	S. Q. Jin		The L-M algorithm combines with the He-Zheng LED model. Using the LED model to reduce the noise of the LED spectra as a means of regularization.
MAP	H. Liu		A gradient descent method with slow convergence rate

Method	Spectrum
Method	White LED	Raman	CFL
LMTR	89.352	210.361	178.009
LMITR	71.811	156.917	155.394
R-L	113.541	142.915	160.308
MAP	87.014	190.845	171.228

Abstract

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Equations (15)

Applied Optics