Simulation for airborne ocean fluorescence lidar based on ICCD

Jin-jia GUO; Zhi-shen LIU

doi:10.3969/j.issn.1007-5461. 2013.01.016

[1] Wright C W, Hoge F E, Swift R N, et al. Next-generation NASA airborne oceanographic lidar system ［J］. Appl. Opt., 2001, 40(3): 336-342.

[2] Chekalyuk A M, Hoge F E, Swift R N, et al. Laser fluorescence analysis of phytoplankton: Beyond chlorophyll concentration ［OL］. http://oceancolor.gsfc.nasa.gov/DOCS/ScienceTeam/OCRT- Apr2004/chekalyuk- ocrt04.pdf.

[3] Lennon M, Thomas N, Mariette V, et al. Oil slick detection and characterization by satellite and airborne sensors: experimental results with SAR, hyperspectral and lidar data ［C］. IEEE IGARSS’ 2005, Seoul, Korea, 2005.

[4] Babichenko S, Dudelzak A, Lapimaa J, et al. Locating water pollution and shore discharges in coastal zone and inland waters with FLS lidar ［J］. EARSeL eProceedings, 2006, 5(1): 32-41.

[5] Jha M N, Levy J, Gao Y. Advances in remote sensing for oil spill disaster management: State-of-the-art sensors technology for oil spill surveillance ［J］. Sensors, 2008, 8: 236-255.

[6] Brown C E, Fingas M F. Review of the development of laser fluorosensors for oil spill application ［J］. Marine Pollution Bulletin, 2003, 47: 477-484.

[7] Lee K J, Park Y, Bunkin A, et al. Helicopter-based lidar system for monitoring the upper ocean and terrain surface ［J］. Appl. Opt., 2002, 41(3): 401-406.

[10] Hoge F E, Swift R N. Airborne dual laser excitation and mapping of phytop lankton photopigments in a Gulf Stream Warm Core Ring ［J］. Appl. Opt., 1983, 22: 2272-2281.