Infrared Technology, Volume. 42, Issue 7, 688(2020)
Research Progress of Miniature Near Infrared Spectrometer
References(30)
[6] [6] EDITA BOTONJICA S F. Tissue identification using a miniature near-infrared spectrometer [J]. Photonic Therapeutics and Diagnostics,2006, 6(15): 60871Z-608711.
EDITA BOTONJICA S F. Tissue identification using a miniature near-infrared spectrometer [J]. Photonic Therapeutics and Diagnostics,2006, 6(15): 60871Z-608711.
[7] [7] EMADI A, WU H, GRABRANIK S, et al. Fabrication and characterization of IC-Compatible Linear Variable Optical Filters with application in a micro-spectrometer[J]. Sensors and Actuators a: Physical,2010, 162(2): 400-405.
EMADI A, WU H, GRABRANIK S, et al. Fabrication and characterization of IC-Compatible Linear Variable Optical Filters with application in a micro-spectrometer[J]. Sensors and Actuators a: Physical,2010, 162(2): 400-405.
[8] [8] MANEL ALCALà M P, SIESLERD H W. Qualitative and quantitative pharmaceutical analysis with a novel hand-held miniature near infrared spectrometer[J]. Journal of Near Infrared Spectroscopy,2013(21): 445-457.
MANEL ALCALà M P, SIESLERD H W. Qualitative and quantitative pharmaceutical analysis with a novel hand-held miniature near infrared spectrometer[J]. Journal of Near Infrared Spectroscopy,2013(21): 445-457.
[9] [9] FRIEDRICH D M, CHARLES A H, GUNTEN M V, et al. Miniature near-infrared spectrometer for point-of-use chemical analysis [J].Photonic Instrumentation Engineering, 2014(18): 899203-899899.
FRIEDRICH D M, CHARLES A H, GUNTEN M V, et al. Miniature near-infrared spectrometer for point-of-use chemical analysis [J].Photonic Instrumentation Engineering, 2014(18): 899203-899899.
[17] [17] LEI Feng, ZHOU Jingsong, DONG Wang. A Miniature Design of Near Infrared Spectrometer with Wide Field of View[J]. Symposium on Optoelectronic Technology and Application, 2014, 5(18):92980M1-92980M6.
LEI Feng, ZHOU Jingsong, DONG Wang. A Miniature Design of Near Infrared Spectrometer with Wide Field of View[J]. Symposium on Optoelectronic Technology and Application, 2014, 5(18):92980M1-92980M6.
[19] [19] BADIA KOUDSI H R. Miniature Transmissive DLP-Based Infrared Spectrometer[J]. Emerging Digital Micromirror Device Based Systems and Applications, 2016, 16(18): 97610D1-97610D7.
BADIA KOUDSI H R. Miniature Transmissive DLP-Based Infrared Spectrometer[J]. Emerging Digital Micromirror Device Based Systems and Applications, 2016, 16(18): 97610D1-97610D7.
[25] [25] UNGER M, PFEIFER F, SIESLER H W. Comparative Variable Temperature Studies of Polyamide II with a Benchtop Fourier Transform and a Miniature Handheld Near-Infrared Spectrometer Using 2D-COS and PCMW-2DAnalysis[J]. Applied Spectroscopy, 2016(1): 1-7.
UNGER M, PFEIFER F, SIESLER H W. Comparative Variable Temperature Studies of Polyamide II with a Benchtop Fourier Transform and a Miniature Handheld Near-Infrared Spectrometer Using 2D-COS and PCMW-2DAnalysis[J]. Applied Spectroscopy, 2016(1): 1-7.
[26] [26] TüTüNCü E, KOKORIC V, WILK A, et al. Fiber-Coupled Substrate- Integrated Hollow Waveguides: An Innovative Approach to Mid-infrared Remote Gas Sensors[J]. ACS Sensors, 2017, 2(9):1287-1293.
TüTüNCü E, KOKORIC V, WILK A, et al. Fiber-Coupled Substrate- Integrated Hollow Waveguides: An Innovative Approach to Mid-infrared Remote Gas Sensors[J]. ACS Sensors, 2017, 2(9):1287-1293.
[28] [28] KATAGIRI T, SHIBAYAMA K, IIDA T, et al. Infrared Hollow Optical Fiber Probe for Localized Carbon Dioxide Measurement in Respiratory Tracts[J]. Sensors, 2018(18): 1-8.
KATAGIRI T, SHIBAYAMA K, IIDA T, et al. Infrared Hollow Optical Fiber Probe for Localized Carbon Dioxide Measurement in Respiratory Tracts[J]. Sensors, 2018(18): 1-8.
[32] [32] DONG Xiang, Mark A Arnold. Chemical Imaging with a Solid-State near Infrared Spectrometer Based on a Digital Micro-Mirror Array Device Coupled with Hadamard Transform Spectroscopy[J]. Analytical Letters, 2012, 45(9): 1070-1078.
DONG Xiang, Mark A Arnold. Chemical Imaging with a Solid-State near Infrared Spectrometer Based on a Digital Micro-Mirror Array Device Coupled with Hadamard Transform Spectroscopy[J]. Analytical Letters, 2012, 45(9): 1070-1078.
[33] [33] QUAN Xiangqian, HUA Liu, LU Zhenwu, et al. Correction and analysis of noise in Hadamard transform spectrometer with digital micro-mirror device and double sub-gratings[J]. Optics Communication, 2016(359):95-101.
QUAN Xiangqian, HUA Liu, LU Zhenwu, et al. Correction and analysis of noise in Hadamard transform spectrometer with digital micro-mirror device and double sub-gratings[J]. Optics Communication, 2016(359):95-101.
[44] [44] BRYAN K M, ZHANG Jia, PERVEZ N K, et al. Inexpensive photonic crystal spectrometer for colorimetric sensing applications[J]. Optics Express, 2013, 21(4): 4411-4423.
BRYAN K M, ZHANG Jia, PERVEZ N K, et al. Inexpensive photonic crystal spectrometer for colorimetric sensing applications[J]. Optics Express, 2013, 21(4): 4411-4423.
[45] [45] BAO Jie. A colloidal quantum dot spectrometer[J]. Nature, 2015(3):67-72.
BAO Jie. A colloidal quantum dot spectrometer[J]. Nature, 2015(3):67-72.
[46] [46] SAARA A KHAN A B. Colloidal Quantum Dots for Cost Effective,Miniaturized, and Simple Spectrometers[J]. Clinical Chemistry, 2016,62(4): 1-3.
SAARA A KHAN A B. Colloidal Quantum Dots for Cost Effective,Miniaturized, and Simple Spectrometers[J]. Clinical Chemistry, 2016,62(4): 1-3.
[47] [47] YANG Zongyin, ALBROW-OWEN T, CUI Hanxiao, et al. Singlenanowire spectrometers[J]. Science, 2019(6): 1017-1020.
YANG Zongyin, ALBROW-OWEN T, CUI Hanxiao, et al. Singlenanowire spectrometers[J]. Science, 2019(6): 1017-1020.
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WANG Suhui, ZHANG Xu, ZHANG Genwei, GUO Tengxiao, DING Xuequan. Research Progress of Miniature Near Infrared Spectrometer[J]. Infrared Technology, 2020, 42(7): 688
Paper Information
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Received: Nov. 3, 2019
Accepted: --
Published Online: Aug. 18, 2020
The Author Email: Suhui WANG (1262286079@qq.com)
CSTR:32186.14.
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