[1 ]阎吉祥,龚顺生,刘智深 .环境监测激光雷达[M].北京:科学出版社,2001.135-204.
[2 ]Collis R T H. Lidar: a new atmosphere probe [J]. Q J R Meteorol Soc, 1966, 92:220-230.
[3 ]Collis R T H, Uthe E E. Mie scatter techniques for air pollution measurement with lasers[J]. Opt Electron, 1972, 4: 87-99.
[4 ]Collis R T H, Russell P B. Lidar Measurements of Particle and Gases by Elastic Backscattering and Differential Absorption[A].Hinkley. Laser Monitoring of the Atmosphere[M]. Berlin: Springer-Verlag, 1976. 71-152.
[5] Klett J D. Stable analytical inversion solution for processing lidar returns[J]. Appl Opt, 1981,20: 211-220.
[6] Klett J D. Lidar inversion with variable backscatter/extinction ratios[J]. Appl Opt, 1985, 24:1638-1643.
[7] Klett J D. Extinction boundary value algorithms for lidar inversion[J]. Appl Opt, 1986, 25:2462-2464.
[8 ]Bissonnette L R. Sensitivity analysis of lidar inversion algorithms[J]. Appl Opt, 1986, 25:2122-2125.
[9 ]Fernald F G. Analysis of atmospheric lidar observations: some comments[J]. Appl Opt, 1984, 23:652-653.
[10] Horst Jager, Hofmann D. Midlatitude lidar backscatter to mass, area, and extinction conversion model based on in situ aerosol measurements from 1980 to 1987[J]. Appl Opt, 1991, 30:127-138.
[11 ]Takamura T, Sasano Y. Aerosol optical properties inferred from simultaneous lidar, aerosol-counter, and sunphotometer measurements[J]. J Meteorol Soc Jpn, 1990, 68:729-739.
[12] Sasano Y. Tropospheric aerosol extinction coefficient profiles derived from scanning lidar measurements over Tsukuba, Japan, from 1990 to 1993[J]. Appl Opt, 1996, 35:4941-4952.
[13 ]Shimizu H, Sasano Y, Nakane H, et al. Large scale laser radar for measuring aerosol distribution over a wide area[J]. Appl Opt, 1985, 24:617-626.
[14 ]Qing P, Nakane H, Sasano Y, et al. Numerical simulation of the retrieval of aerosol size distribution from multiwavelength laser radar measurements[J]. Appl Opt, 1989, 28:5259-5265.
[15 ]Sasano Y, Nakane H. Significance of the extinction/backscatter ratio and the boundary value term in the solution for the two-component lidar equation[J]. Appl Opt, 1984, 23:11-13.
[16 ]Sasano Y, Browell E, Ismail S. Error caused by using a constant extinction/backscattering ratio in the lidar solution[J]. Appl Opt, 1985, 24:3929-3932.
[17] Sasano Y, Nakane H. Quantitative analysis of RHI lidar data by an iterative adjustment of the boundary condition term in the lidar solution[J]. Appl Opt, 1987, 26:615-616.
[18] Takamura T, Sasano Y. Ratio of aerosol backscatter to extinction coefficients as determined from angular scattering measurements for use in atmospheric lidar applications[J]. Opt Quantum Electron, 1987, 19:293-302.
[19 ]Takamura T, Sasano Y, Hayasaka T. Tropospheric aerosol optical properties derived from lidar, sun photometer, and optical particle counter measurements[J]. Appl Opt, 1994, 33:7132-7140.
[20]张改霞,张寅超,胡顺星,等.AML-1车载测污激光雷达探测大气边界层气溶胶[J]. 强激光与粒子束,2004,16(3):286-290.
[21 ]张改霞,张寅超,胡顺星,等.车载测污激光雷达对大气边界层气溶胶的斜程测量[J]. 光学学报,2004,24(8):1015-1019.
[22 ]杨陆军,张寅超,刘小勤,等.车载测污激光雷达测量大气气溶胶光学特性[J]. 量子电子学报,2004,21(1):88-91.
[23 ]吴永华,胡欢陵,周军,等.L625激光雷达探测平流层气溶胶[J]. 光学学报,2001,21(8):1012-1015.
[24 ]周军,岳古明,戚福第,等.大气气溶胶光学特性激光雷达探测[J].量子电子学报,1998,15(2):140-148.
[25] 周军,岳古明,金传佳,等.探测对流层气溶胶的双波长米氏散射激光雷达[J].光学学报,2000,20(10):1412-1417.
[26] 钟志庆,周军,戚福第,等.探测大气气溶胶消光系数的便携式米散射激光雷达[J].强激光与粒子束,2003,15(12):1145-1147.
[27 ]白宇波,石广玉,田村耕一,等.拉萨上空大气气溶胶光学特性的激光雷达探测[J].大气科学,2000,24(4):559-567.
[28 ]邱金桓,郑斯平,黄其荣,等.北京地区对流层中上部云和气溶胶的激光雷达探测[J].大气科学,2003,27(1):1-7.
[29 ]胡欢陵,吴永华,谢晨波,等.北京地区夏冬季颗粒物污染边界层的激光雷达观测[J].环境科学研究,2004,17(1):59-66,73.
30余长明,易帆.武汉上空平流层气溶胶的激光雷达探测结果的初步分析[J].空间科学学报,2004,24(4):261-268.
31 Iwasaka Y, Shi G Y, Kim Y S, et al. Pool of dust particles over the Asian Continent: balloon-borne optical particle counter and ground-based lidar measurements at Dunhuang, China[J].Environmental Monitoring and Assessment, 2004, 92: 5-24.
32 Spinhirne J D, Hart W D. Cirrus structure and radiative parameters from airborne lidar and spectral radiometer observations: The 28 October 1986 FIRE study[J]. Monthly Weather Review, 1990, 118:2329-2343
33 Sassen K, Cho BS. Subvisual-thin cirrus lidar dataset for satellite verification and climatological research[J]. J Appli Meteorol, 1992, 31:1275-1285.
34 Piironen A K, Eloranta E W. Convective boundary layer mean depths and cloud geometrical properties obtained from volume imaging lidar data[J]. J Geophys Res, 1995, 100:25569-25576.
35 Young S A. Analysis of lidar backscatter profiles in optically thin clouds[J]. Appl Opt, 1995, 34:7019-7031.
36 Gobbi G P, Donfrancesco G D, Adriani A. Physical properties of stratospheric clouds during the Antarctic winter of 1995[J] J Geophys Res,1998, 103:10859-10873.
37 Ackerman A S, Toon O B, Stevens D E, et al. Reduction of tropical cloudiness by soot[J]. Science, 2000, 288:1042-1046.
38 Pelon J, Flamant C, Trouillet V, et al. Optical and microphysical parameters of dense stratocumulus clouds during mission 206 of EUCREX’94 as retrieved from measurements made with the airborne lidar LEANDRE 1[J]. J Atmos Res, 2000, 55:47-64.
39 Avissar R, Eloranta E W, Gurer K. An evaluation of the large-eddy simulation option of the regional atmospheric modeling system in simulation a convective boundary layer: A FIRE case study[J]. J Atmos Sci, 1998, 55:1109-1130.
40 Sullivan P P, Moeng C H, Stevens B, et al. Structure of entrainment zone capping the convective atmospheric boundary layer[J]. J Atmos Sci, 1998, 55:3042-3064.
41 Stevens B, Lenschow D H. Observations, experiments, and large eddy simulations[J]. Bull Am Meteorol Soc, 2001, 82:283-294.
42 Asimakopoulos D N. Application of sodar and lidar techniques in air pollution monitoring-A report on the Eurasp-90 International meeting[J]. Atmos Environ, 1991, 25:2057-2060.
43 Hoff R M, Guise-Bagley L, Staebler R M, et al. Lidar, Nephelometer, and in Situ Aerosol Experiments in Southern Ontario[J]. J Geophys Res, 1996, 101:19199-19209.
44 Pinandito M, Rosananto I, Hidayat I, et al. Lidar network system for monitoring the atmospheric environment in Jakarta city[J]. Opt Rev, 1998, 5:252-256.
45 Carnuth W, Trickl T. Transport studies with the IFU three-wavelength aerosol lidar during the VOTALP Mesocina experiment[J]. Atmos Environ, 2000, 34:1425-1434.
46 Papayannis A, Balis D, Bais A, et al. Role of urban and suburban aerosols on solar UV radiation over Athens, Greece[J]. Atmos Environ, 1998, 32:2193-2201.
47 Satheesh S K, Ramanathan V, Xu L J, et al. A model for the natural and anthropogenic aerosols over the tropical Indian Ocean derived from Indian Ocean Experiment data[J]. J Atmos Res,1999, 104:27421-27440.
48 Minomura M, Ru J, Kuze H, et al. Atmospheric correction of satellite data using multi-wavelength lidar data with MODTRAN3 code[J]. Adv Space Res, 2000, 25:1033-1036.
49 Charlson R J, Schwartz S E, Hales J M, et al. Climate forcing by anthropogenic aerosols[J]. Science, 1992, 255:423-430.
50 Pahlow M. Atmospheric boundary layer dynamics and inversion technologies to obtain extinction coefficient profiles in the atmosphere from elastic lidar[D]. Johns Hopkins University, a dissertation with the requirements for the degree of Doctor of Philosophy, 2002.
51 Pahlow M, Kleissl J, Parlange M, et al. Atmospheric boundary-layer structure observed during a haze event due to forest-fire smoke[J]. Boundary-Layer Meteorology, 2005, 114:53-70.
52 邱金桓,孙金辉.沙尘暴的光学遥感与分析[J]. 大气科学,1994,18:1-10.
53 Iwasaka Y. The transport and special scale of Asian dust-storm clouds: a case study of the dust-storm event of April 1979[J]. Tellus, 1983, 36:189-196.
54 夏俊荣.利用激光雷达探测兰州大气气溶胶辐射特性[D].兰州大学, 2006.
55 李成才,刘启汉,毛节泰,等.利用MODIS卫星和激光雷达遥感资料研究香港地区的一次大气气溶胶污染[J].应用气象学报,2004,15:641-650. |