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基于FPGA的可见光波段便携式光谱仪的设计 被引量:7

Design of FPGA-based portable spectrometer working in visible light band
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摘要 为了有效地实现光谱仪的便携式设计,文中采用FPGA便携式光谱仪。FPGA采用Altera公司的CLCLONE IV系列的EP4CE30F23C8N芯片,CCD采用东芝公司的TCD1304。系统机上的数据使用Matlab进行去噪处理,绘制成光谱曲线,系统选用汞灯作为标准光源进行系统校验,利用汞灯的5个标准光谱特征峰确定光谱仪的谱线校验系数。测试结果表明,光谱分辨率可以达到10 nm,系统可以实现可见光波段的光谱测量,具有较好的实用性。 A practical portable spectrometer is established by adopting a modular design scheme combining the FPGA with the linear CCD,so as to effectively realize portable design of the spectrometer.The EP4CE30F23C8N chip of Alterar s CL-CLONE IV series is used for the FPGA.Toshibars TCD1304 is used for the CCD.The CCD drive control,and acquisition and transmission of spectral data where completed in the system.The data transmitted to the PC is denoised with Matlab,and drawn into the spectral curve.The mercury lamp is selected as the standard light source for system calibration.The spectral line calibration coefficients of the spectrometer are determined by using five standard spectral characteristic peaks of the mercury lamp.The test results show that the spectral resolution ratio can reach 10 nm,and the system can realize spectral measurement of the visible light band,which has a good practicability.
作者 袁谦 黄波 张多英 吴霞 罗志 杨恢东 贺冠南 YUAN Qian;HUANG Bo;ZHANG Duoying;WU Xia;LUO Zhi;YANG Huidong;HE Guannan(College of Information Science and Technology,Jinan University,Guangzhou 510000,China;College of Physics and Telecommunication Engineering,South China Normal University,Guangzhou 510006,China;Guangdong Provincial Key Laboratory of Quantum Engineering and Quantum Materials,Guangzhou 510006,China)
出处 《现代电子技术》 北大核心 2019年第6期100-104,共5页 Modern Electronics Technique
基金 国家自然科学基金项目资助(61307080) 国家自然科学基金项目资助(11204105) 广东省自然科学基金资助项目(2017A030310064) 广东省自然科学基金资助项目(2016A030313081) 广东省科技计划项目(2014A010106014)~~
关键词 便携式光谱仪 模块化设计 去噪处理 数据采集 光谱测量 谱线校验 portable spectrometer modular design de-noising processing data acquisition spectral measurement spectral-line validation
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  • 1M.V.R.K.Murty.Use of convergent and divergentillumination with plane gratings[J].J.Opt.Soc.Am.,1962,52(7):768-773.
  • 2Aathur B.Shafer.Optimization of the Czerny-TurnerSpectrometer[J].J.Opt.Soc.Am.,1963,54(7):879-887.
  • 3Murphy L.Dalton,Jr.Astigmatism compensation in the Czerny-Turner spectrometer[J].Appl.Opt.,1966,5(7):1121-1123.
  • 4Masayuki Futamata,Takehiko Takenouchi,Kei-ichi Katakura.Highly efficient and aberration-corrected spectrometer foradvanced Raman spectroscopy[J].Appl.Opt.,2002,41(22):24-31.
  • 5Kye-Sung Lee,Kevin P.Thompson,Jannick P.Rolland.Broadband astigmatism-corrected Czerny-Turner spectrometer[J].Opt.Express,2010,18(22):23378-23384.
  • 6F.A.Jenkins,H.E.White.Fundamentals of Optics[M].NewYork:McGraw-Hill,1950.92-93.
  • 7Dane R.Austin,Tobias Witting,Ian A.Walmsley.Broadbandastigmatism free Czerny-Turner imaging spectrometer usingspherical mirrors[J].Appl.Opt.,2009,48(19):3846-3853.
  • 8王建宇,舒嵘,刘银年,等.成像光谱技术导论[M].北京:科学出版社,2011.
  • 9Dubroca T, Brown G, Hummel R E. Detection of explosives by differential hyperspectral imaging[J]. Opt. Eng. , 2014, 53(2): 239-244.
  • 10I P616nen, H Saari, J Kaivosoja, et al. Hyperspec- tral imaging based biomass and nitrogen content esti- mations from light-weight UAV[C]. SHE, Remote Sensing for Agriculture, Ecosystems, and Hydrology XV, 88870J, 2013.

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