9-11 Nov. 1999
at Austin.
ee, W.A. & Cummins,
tive of riparian zones.
e data sources for urban
^ Week '99, Fritsch D. &
Verlag, Heidelberg, pp.
. L., & Still, D. J., 1999.
ies by Echo Recovery
^roduct Description, In
Space Administration.
LICER (Scanning Lidar
overy) Airborne Laser
cov/research/laser/slicer/
\, Goddard Space Flight
ter, J. B., Ridgway, J.
nd Rabine, D. L., 1999.
ong Valley caldera, CA,
J] Remote Sensing
anning laser mapping of
n. ISPRS J Photogram &
emote Sens 54(2-3).
ey, H. E., Jr. & Krabill,
craft MSS and LIDAR
tland. Geocarto Internat
de, S., 1999a. Airborne
.Wff.nasa.gov/aoltm.html
veronatics and Space
S., Martin, C., Sonntag,
V. & Yungel, J. 1999b.
ern greenland ice sheet.
International Archives of Photogrammetry and Remote Sensing, Vol. 32, Part 3W14, La Jolla, CA, 9-11 Nov. 1999
Kraus, K. & Pfeifer, N., 1998. Determination of terrain
models in wooded areas with airborne laser scanner data.
ISPRS J Photogram & Remote Sens 53:193. 203.
Kreslavsky, M., & Head, J.W. 1999. Kilometer-scale slopes
on Mars and their correlation with geologic units: Initial
results from the Mars Orbiter Laser Altimeter (MOLA). J
Geophys Res 104:911-924.
Lefsky, M. A., Harding, D., Cohen, W. B., Parker, G., &
Shugart, H. H., 1999. Surface lidar remote sensing of basal
area and biomass in deciduous forests of eastern Maryland,
USA. Remote Sens Env 67(1):83-98.
Maas, H. G., & Vosselman, G., 1999. Two algorithms for
extracting building models from raw laser altimetry data.
ISPRS J Photogram & Remote Sens 54(2 3):153-163.
MacLean, G. A., & Krabill, W. B., 1985. Gross merchantable
timber volume estimation using an airborne LIDAR system.
Can J Remote Sens 12(1):7-18.
Matrosov, S., Heymsfield, A., Kropfli, R., Snider, Martner,
Piironen, P., & Eloranta, E.W., 1998. Comparisons of ice and
cloud properties obtained by remote and direct methods. J
Atmos & Ocean Tech 15:184-196.
Means, J. E., Acker, S. A., Harding, D. J., Blair, J. B., Lefsky,
M. A., Cohen, W. B., Harmon, M. E. & McKee, W. A., 1999.
Use of large_footprint scanning airborne lidar to estimate
forest stand characteristics in the western Cascades of
Oregon. Remote Sens Env 67(3):298-308.
Murakami, H., Nakagawa, K., Hasegawa, H., & Shibata, T.,
1999. Change detection of buildings using an airborne laser
scanner. ISPRS J Photogram & Remote Sens 54(2-3):148-
152.
Naesset, E., 1997a. Determination of mean tree height of
forest stands using airborne laser scanner data. ISPRS J
Photogram & Remote Sens 52(2):49-56.
Naesset, E., 1997b. Estimating timber volume of forest stands
using airborne laser scanner data. Remote Sens Env
61(2):246-253.
Nelson, R., Krabill, W., & Maclean, G., 1984. Determining
forest canopy characteristics using airborne laser data. Remote
Sens Env 15:201-212.
Nelson, R., Oderwald, R. & Gregoire, T. G., 1997. Separating
the ground and airborne laser sampling phases to estimate
tropical forest basal area, volume, and biomass. Remote Sens
Env 60(3):311-326.
Rothermel, R.C., 1991. Predicting behavior and size of crown
fires in the northern Rocky Mountains. USDA Forest Service,
Intermountain Research Station, Fort Collins, CO. Research
Paper INT-438, 46 p.
Schreier, H., Lougheed, J., Tucker, C. & Leckie, D., 1985.
Automated measurements of terrain reflection. and height
variations using an airborne laser system. /nt J Remote Sens
6:101-113.
SOAR Staff 1999. Support Office for Aerogeophysical
Research.http://www.ig.utexas.edu/research/projects/soar/soar
html World Wide Web. Institute for Geophysics, University
of Texas at Austin.
Wagner, M. J., 1995. Seeing in 3 D without the glasses.
Earth Observ Mag (July):51-53.
Wehr, A. & Lohr, U., 1999. Airborne laser scanning - an
introduction and overview. ISPRS J Photogram & Remote
Sens 54(2-3):68-82.
