量子电子学报, 2013, 30 (1): 103, 网络出版: 2013-01-24   

基于光纤F-P滤波器全光纤水汽拉曼激光雷达系统的设计与分析

Analysis of all-fiber Raman lidar system for water vapor by fiber Fabry-Perot filters
作者单位
西安理工大学机械与精密仪器工程学院,陕西 西安 710048
摘要
提出并设计了一套基于光纤F-P滤波器的可见波长域全光纤水汽拉曼激光雷达系统, 实现对大气水汽和气溶胶的精细探测。讨论了光纤F-P腔内损耗和腔镜反射率对F-P透射谱的细度、 峰值透过率以及带宽的影响,得到腔内损耗在小于3%的情况下,光纤F-P滤波器具有较高的峰值透过率(大于0.5)和较窄的谱线 带宽(小于0.9 nm)。通过结合光纤带通滤波器和二级级联光纤F-P滤波器的参数设计,在三个独立的光通道中分别实现水 汽拉曼信号(660 nm)、氮气拉曼信号(606 nm)和米瑞利信号(532 nm)的窄带宽、 高透过率严格滤波,并获得对杂散光的高抑制率。通过系统仿真,对各散射信号强度分布、水汽廓线和探测信噪比进行了数 值仿真计算,验证了系统方案的可行性。
Abstract
An all-fiber Raman water vapor lidar system was proposed and designed based on fiber Fabry-Perot (F-P) filters in the visible wavelength domain, to achieve the fine-detection of the atmospheric water vapor and aerosol properties. The influences of cavity loss and the reflectance on the fitness, the transmission peak and bandwidth of fiber F-P filters were analyzed. Results show that the fiber F-P filter features a higher transmission peak and narrower bandwidth under the condition of the F-P cavity loss less than 3%. The combination of fiber band-pass filters and the two-cascade fiber F-P filters was used as fiber spectroscopic system and the corresponding parameters were designed to achieve narrow-band high-peak transmission of the Raman signals of water vapor (660 nm) and nitrogen (606 nm) and Mie-Rayleigh signals (532 nm), respectively, and obtain high rejection-rate of stray lights. By numerical simulations of the intensity distribution of returned signals, the water vapor vertical profile and the detection signal to noise ratio(SNR) were obtained respectively, to verify the feasibility of the system.

王玉峰, 华灯鑫, 王红伟, 狄慧鸽. 基于光纤F-P滤波器全光纤水汽拉曼激光雷达系统的设计与分析[J]. 量子电子学报, 2013, 30(1): 103. WANG Yu-feng, HUA Deng-xin, WANG Hong-wei, Di Hui-ge. Analysis of all-fiber Raman lidar system for water vapor by fiber Fabry-Perot filters[J]. Chinese Journal of Quantum Electronics, 2013, 30(1): 103.

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