Compact Spectrometer Based on a Frosted Glass

T. Yang; X. L. Huang; H. P. Ho; C. Xu; Y. Y. Zhu; M. D. Yi; X. H. Zhou; X. A. Li; W. Huang

doi:10.1109/LPT.2016.2636340

Compact Spectrometer Based on a Frosted Glass

T. Yang, X. L. Huang, H. P. Ho, C. Xu, Y. Y. Zhu, M. D. Yi, X. H. Zhou, X. A. Li, W. Huang

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

We demonstrate a spectrometer based on multiple interference and scattering in an ordinary frosted glass featuring random structures. The probe signal disperses through the frosted glass generating wavelength-dependent speckle patterns, which are detected by a charge coupled device chip and used to reconstruct the input spectrum after calibration. We consider an underdetermined system of linear equations as a model for signal spectrum estimation. Smoothing regularization algorithm is designed for solving the system of equations. Experimental results show that the reconstruction range of the spectrometer at least includes the entire visible band and some part of the ultraviolet band. In comparison with conventional miniature spectrometers, the frosted glass spectrometer consequently has the merits of static measurement, low cost, small size, high throughput, and wide spectral range, which may find applications in a wide range of applications.

Original language	English
Article number	7776812
Pages (from-to)	217-220
Number of pages	4
Journal	IEEE Photonics Technology Letters
Volume	29
Issue number	2
DOIs	https://doi.org/10.1109/LPT.2016.2636340
State	Published - 15 Jan 2017
Externally published	Yes

Keywords

frosted glass
regularization algorithm
Spectrometer

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10.1109/LPT.2016.2636340

Cite this

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title = "Compact Spectrometer Based on a Frosted Glass",

abstract = "We demonstrate a spectrometer based on multiple interference and scattering in an ordinary frosted glass featuring random structures. The probe signal disperses through the frosted glass generating wavelength-dependent speckle patterns, which are detected by a charge coupled device chip and used to reconstruct the input spectrum after calibration. We consider an underdetermined system of linear equations as a model for signal spectrum estimation. Smoothing regularization algorithm is designed for solving the system of equations. Experimental results show that the reconstruction range of the spectrometer at least includes the entire visible band and some part of the ultraviolet band. In comparison with conventional miniature spectrometers, the frosted glass spectrometer consequently has the merits of static measurement, low cost, small size, high throughput, and wide spectral range, which may find applications in a wide range of applications.",

keywords = "frosted glass, regularization algorithm, Spectrometer",

author = "T. Yang and Huang, {X. L.} and Ho, {H. P.} and C. Xu and Zhu, {Y. Y.} and Yi, {M. D.} and Zhou, {X. H.} and Li, {X. A.} and W. Huang",

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doi = "10.1109/LPT.2016.2636340",

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T1 - Compact Spectrometer Based on a Frosted Glass

AU - Yang, T.

AU - Huang, X. L.

AU - Ho, H. P.

AU - Xu, C.

AU - Zhu, Y. Y.

AU - Yi, M. D.

AU - Zhou, X. H.

AU - Li, X. A.

AU - Huang, W.

PY - 2017/1/15

Y1 - 2017/1/15

N2 - We demonstrate a spectrometer based on multiple interference and scattering in an ordinary frosted glass featuring random structures. The probe signal disperses through the frosted glass generating wavelength-dependent speckle patterns, which are detected by a charge coupled device chip and used to reconstruct the input spectrum after calibration. We consider an underdetermined system of linear equations as a model for signal spectrum estimation. Smoothing regularization algorithm is designed for solving the system of equations. Experimental results show that the reconstruction range of the spectrometer at least includes the entire visible band and some part of the ultraviolet band. In comparison with conventional miniature spectrometers, the frosted glass spectrometer consequently has the merits of static measurement, low cost, small size, high throughput, and wide spectral range, which may find applications in a wide range of applications.

AB - We demonstrate a spectrometer based on multiple interference and scattering in an ordinary frosted glass featuring random structures. The probe signal disperses through the frosted glass generating wavelength-dependent speckle patterns, which are detected by a charge coupled device chip and used to reconstruct the input spectrum after calibration. We consider an underdetermined system of linear equations as a model for signal spectrum estimation. Smoothing regularization algorithm is designed for solving the system of equations. Experimental results show that the reconstruction range of the spectrometer at least includes the entire visible band and some part of the ultraviolet band. In comparison with conventional miniature spectrometers, the frosted glass spectrometer consequently has the merits of static measurement, low cost, small size, high throughput, and wide spectral range, which may find applications in a wide range of applications.

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KW - regularization algorithm

KW - Spectrometer

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DO - 10.1109/LPT.2016.2636340

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JO - IEEE Photonics Technology Letters

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Compact Spectrometer Based on a Frosted Glass

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Keywords

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