[1] Brennan D, Alderman J, Sattler L, et al. Issues in development of NIR micro spectrometer system for on-line process monitoring of milk product［J］. Measurement, 2003, 33(1): 67-74.

[2] Schuler L P, Milne J S, Dell J M, et al. MEMS-based microspectrometer technologies for NIR and MIR wavelengths［J］. Journal of Physics D, 2009, 42(13): 133001.

[3] Barthès B G, Brunet D, Rabary B, et al. Near infrared reflectance spectroscopy (NIRS) could be used for characterization of soil nematode community［J］. Soil Biology & Biochemistry, 2011, 43(8): 1649-1659.

[4] Tseng V F G, Xie H. Simultaneous piston position and tilt angle sensing for large vertical displacement micromirrors by frequency detection inductive sensing［J］. Applied Physics Letters, 2015, 107(21): 214102.

[5] Bao J, Bawendi M G. A colloidal quantum dot spectrometer［J］. Nature, 2015, 523(7558): 67-70.

[6] Hamamatsu. C11708MA microspectrometer - MS series ［EB/OL］. ［2018-03-01］. http:∥www.hamamatsu.com.cn/product/category/10345/0/11945/index.html.

[7] Xiang X Y, Wen Z Y, Long Z C, et al. Development of analysis system for miniature near-infrared spectrometer［J］. Spectroscopy & Spectral Analysis, 2009, 29(8): 2286-2290.

[8] Liu K, Yu F H. Accurate wavelength calibration method using system parameters for grating spectrometers［J］. Optical Engineering, 2013, 52(1): 013603.

[9] Grueger H, Wolter A, Schenk H, et al. Realization of a spectrometer with micromachined scanning grating［J］. Proceedings of SPIE, 2003, 4945: 46-53.

[10] Pügner T, Knobbe J, Grüger H, et al. Design of a hybrid-integrated MEMS scanning grating spectrometer［J］. Proceedings of SPIE, 2011, 8167: 816718.

[11] Pügner T, Grüger H. Miniaturized NIR scanning grating spectrometer for use in mobile phones［J］. Proceedings of SPIE, 2016, 9855: 985502.

[12] Yan B, Yuan W, Sun R, et al. Design and simulation of microspectrometer based on torsional MEMS grating［J］. Proceedings of SPIE, 2010, 7657: 76570V.

[13] Qiao D, Kang B, Liu Y, et al. A resonance scanning grating based on SOI for microspectrometer application［J］. Laser Physics, 2013, 23(3): 035601.

[14] Nie Q, Wen Z, Huang J. A high-performance scanning grating based on tilted (111) silicon wafer for near infrared micro spectrometer application［J］. Microsystem Technologies, 2015, 21(8): 1749-1755.

[15] Nie Q, Wen Z, Huang J. Design and fabrication of a MEMS high-efficiency NIR-scanning grating based on tilted (111) silicon wafer［J］. European Physical Journal Applied Physics, 2015, 72(1): 10702.

[16] Keating A J, Antoszewski J, Silva K K M B D, et al. Design and characterization of Fabry-Pérot MEMS-based short-wave infrared microspectrometers［J］. Journal of Electronic Materials, 2008, 37(12): 1811-1820.

[17] Dell J M, Milne J S, Antoszewski J, et al. MEMS-based Fabry-Perot microspectrometers for agriculture［J］. Proceedings of SPIE, 2009, 7319: 73190K.

[18] Milne J S, Dell J M, Keating A J, et al. Widely tunable MEMS-based Fabry-Perot filter［J］. Journal of Microelectromechanical Systems, 2009, 18(4): 905-913.

[19] Akujrvi A, Gao B, Mannila R, et al. MOEMS FPI sensors for NIR-MIR microspectrometer applications［J］. Proceedings of SPIE, 2016, 9760: 97600M.

[20] Hamamatsu. Microspectrometer ［EB/OL］. ［2018-03-01］. http:∥www.hamamatsu.com.cn/product/category/10345/10345/index.html page=1.

[21] Emadi A, Wu H, Grabarnik S, et al. Fabrication and characterization of IC-compatible linear variable optical filters with application in a micro-spectrometer［J］. Sensors & Actuators A, 2010, 162(2): 400-405.

[22] Wen Z Y, Chen G, Wang J G. The project and simulation of a compositive miniature spectrum instrument based on the array of Fabry-Perot cavity［J］. Spectroscopy & Spectral Analysis, 2006, 26 (10): 1955-1959.

[23] Emadi A, Wu H, Grabarnik S, et al. IC-compatible fabrication of linear variable optical filters for microspectrometer［J］. Procedia Chemistry, 2009, 1(1): 1143-1146.

[24] Emadi A. Near- and mid-IR microspectrometers based on linear-variable optical filters［C］∥Sensors, IEEE, 2011: 424-427.

[25] Ghaderi M, Silva M F, Emadi A, et al. Design, fabrication and characterization of LVOF-based IR microspectrometers［J］. Proceedings of SPIE, 2014, 9130: 91300T.

[26] Wallrabe U, Solf C, Mohr J, et al. Miniaturized Fourier transform spectrometer for the near infrared wavelength regime incorporating an electromagnetic linear actuator［J］. Sensors & Actuators A, 2005, 123: 459-467.

[27] Yu K, Lee D, Krishnamoorthy U, et al. Micromachined Fourier transform spectrometer on silicon optical bench platform［J］. Sensors & Actuators A, 2006, 130(2): 523-530.

[28] Quenzer H J, Gu-Stoppel S, Stoppel F, et al. Piezoelectrically driven translatory optical MEMS actuator with 7 mm apertures and large displacements［J］. Proceedings of SPIE, 2015, 9375: 93750O.

[29] Wang W, Chen J P, Zivkovic A S, et al. A compact Fourier transform spectrometer on a silicon optical bench with an electrothermal MEMS mirror［J］. Journal of Microelectromechanical Systems, 2016, 25(2): 347-355.

[30] Han F, Wang W, Zhang X, et al. Modeling and control of a large-stroke electrothermal MEMS mirror for Fourier transform microspectrometers［J］. Journal of Microelectromechanical Systems, 2016, 25(4): 750-760.

[31] Han F T. Miniature Fourier transform spectrometer with a dual closed-loop controlled electrothermal micromirror［J］. Optics Express, 2016, 24(20): 22650-22660.

[32] Kumar H, Nisam N, Kulkarni A, et al. Lamellar grating interferometer FTIR spectroscopy and its applications: a review［C］∥15th International Conference on Nanotechnology, IEEE, 2015: 1107-1110.

[33] Ataman C, Urey H, Wolter A. A Fourier transform spectrometer using resonant vertical comb actuators［J］. Journal of Micromechanics & Microengineering, 2006, 16(12): 2517-2523.

[34] Ataman C, Urey H. Compact Fourier transform spectrometers using FR4 platform［J］. Sensors & Actuators A, 2009, 151(1): 9-16.

[35] Lee F, Zhou G, Yu H, et al. A MEMS-based resonant-scanning lamellar grating Fourier transform micro-spectrometer with laser reference system［J］. Sensors & Actuators A, 2009, 149(2): 221-228.

[36] Wang S, Yu H, Siong C F. A miniaturized lamellar grating based Fourier transform spectrometer with electrostatic actuation［J］. IEEE Sensors Journal, 2010, 10(12): 1869-1874.

[37] Zhang Z H, Mo X X, Guo Y J, et al. A novel MOEMS NIR spectrometer［J］. Physics Procedia, 2011, 19: 110-114.

[38] Wei W, Huang S, Zhu Y, et al. Analysis of a Hadamard transform near-infrared spectrometer based on grating light modulator［J］. Proceedings of SPIE, 2009, 7159: 71590N.

[39] Zhang Z H, Gao L X, Guo Y J, et al. The design and experiment of complementary S coding matrix based on digital micromirror spectrometer［J］. Spectroscopy & Spectral Analysis, 2012, 32(12): 3429-3432.

[40] Wang X D, Liu H, Lu Z W, et al. Design of a spectrum-folded Hadamard transform spectrometer in near-infrared band［J］. Optics Communications, 2014, 333: 80-83.

[41] Quan X, Liu H, Lu Z, et al. Correction and analysis of noise in Hadamard transform spectrometer with digital micro-mirror device and double sub-gratings［J］. Optics Communications, 2016, 359: 95-101.

[42] Wang X, Liu H, Juschkin L, et al. Freeform lens collimating spectrum-folded Hadamard transform near-infrared spectrometer［J］. Optics Communications, 2016, 380: 161-167.