Development of an operational algorithm for removing atmospheric effects from HYDICE and HSI data

Proceedings of SPIE - The International Society for Optical Engineering

Volumn 2819, Issue , 1996, Pages 45-55

  Gao, Bo Cai ^a   Davis, Curtiss O ^a  

^a NAVAL RESEARCH LABORATORY   (United States)

Author keywords

Atmospheric correction; HSI; HYDICE; Imaging spectrometer; Surface reflectance

Indexed keywords

AIRCRAFT; CODES (SYMBOLS); DATA HANDLING; NASA; REFLECTION; SPECTRAL RESOLUTION; SPECTROMETERS; SPECTROMETRY; SPECTROSCOPY; SURFACE SCATTERING;

AIRBORNE VISIBLE/INFRARED IMAGING SPECTROMETERS; ATMOSPHERIC CORRECTIONS; ATMOSPHERIC SCATTERING; HIGH-ALTITUDE AIRCRAFTS; HYDICE; IMAGING SPECTROMETERS; SURFACE REFLECTANCE; TOP OF THE ATMOSPHERES;

HYPERSPECTRAL IMAGING;

EID: 58749091971     PISSN: 0277786X     EISSN: 1996756X     Source Type: Conference Proceeding    
DOI: 10.1117/12.258087     Document Type: Conference Paper

References (12)

1. Aldrich, W. S., M. E. Kappus, and R. G. Resmini, "HYDICE post-flight data processing", in SPIE's Proceedins (this volume), 1996.
2. Gao, B.-C., K. H. Heidebrecht, and A. F. H. Goetz, "Derivation of scaled surface reflectances from AVIRIS data," Remote Sens. Env., 44, 165-178, 1993.
3. Goetz, A. F. H., G. Vane, J. Solomon, and B. N. Rock, "Imaging spectrometry for earth remote sensing," Science, 228, 1147-1153, 1985.
4. Green, R. O., J. E. Conel, and D. A. Roberts, "Estimation of aerosol optical depth and additional atmospheric parameters for the calculation of apparent reflectance from radiance measured by the airborne visible infrared imaging spectrometer," in Summaries of the fourth annual JPL Airborne Geoscience Workshop, JPL Publication 93-26, Vol. 1, Pasadena, California, pp. 73-76, 1993.
5. Kneizys, F. X., E. P. Shettle, L. W. Abreu, J. H. Chetwynd, G. P. Anderson, W. O. Gallery, J. E. A. Selby, and S. A. Clough, "Users guide to LOWTRAN 7," AFGL-TR-8-0177, Air Force Geophys. Lab., Bedford, Mass., 1988.
6. Malkmus, W., "Random Lorentz band model with exponential-tailed S line intensity distribution function," J. Opt. Soc. Am., 57, 323-329, 1967.
7. Resmini, R. G., M. E. Kappus, and W. S. Aldrich, "Use of hyperspectral digital imagery collection experiment (HYDICE) sensor data for quantitative mineral mapping at Cuprite, Nevada," in SPIE's Proceedins (this volume), 1996.
8. Rickard, L. J., R. Besedow, Ed. Zalewski, P. Silverglate, and L. M. Landers, "HYDICE: An airborne system for hyperspectral imaging," in SPIE's Proceedins, Vol. 1937, 173-179, 1993.
9. Sokolowski, J. K., K. Witcher, B. A. Davis, R. O. Green, "The hyperspectral imager aboard the SSTI's Lewis spacecraft: A comparison with AVIRIS," in Summaries of the sixth annual JPL Airborne Geoscience Workshop, March 4-8, Vol. 1, Pasadena, California, 1996.
10. Tanre, D., C. Deroo, P. Duhaut, et al., "Simulation of the satellite signal in the solar spectrum (5S), User's Guide," Laboratory d'Optique Atmospherique, U.S.T. de Lille, 59655 Villeneuve d'ascq, France, 1986.
11. Vane, G., R. O. Green, T. G. Chrien, H. T. Enmark, E. G. Hansen, and W. M. Porter, "The Airborne Visible/Infrared Imaging Spectrometer," Remote Sens. Env., 44, 127-143, 1993.
12. Vermote, E., D. Tanre, J. L. Deuze, M. Herman, and J. J. Morcrette, "Second simulation of the satellite signal in the solar spectrum (6S), 6S User's Guide Version 1," NASA-GSFC, Greenbelt, Maryland, 134 pages, 1994.