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Primary
Contact |
Title |
Authors |
Submitted
to JGR |
|
Andersen |
Estimation of biomass within boreal
forests on the Kenai Peninsula of Alaska using spaceborne L-band polarimetric
SAR |
Andersen, Saatchi, Yu |
|
|
Bergen |
Measurements of Vegetation 3D
Structure for Biodiversity and Habitat: Review and Implications for
Spaceborne Remote Sensing Missions |
Bergen, K., Goetz, S., Dubayah, R.,
Henebry, G., Imhoff, M., Nelson, R., Parker, G., Radeloff, V. |
|
|
Carabajal |
Laser Altimeter Waveform
Simulations of Vegetation Vertical Structure Applied to ICESat: A Valuable
Mission Design Tool |
Claudia C. Carabajal & David J.
Harding |
|
|
Chambers |
Forest biomass change from
hurricane Katrina induced disturbance combining radar and optical remote
sensing |
J.Q. Chambers, S.S. Saatchi, H. Zeng, R. Negron-Juarez, K. Radke, D.
Baker |
|
|
Dolan |
Regional Forest Growth Rates
Measured by Combining ICESAT GLAS and Landsat Data |
Katelyn Dolan, Jeffrey G. Masek,
Chengquan Huang, Guoqing Sun |
|
|
Dubayah |
Lidar measurements of vegetation
structure |
Dubayah et al. |
|
|
Emanual |
Gleaning vegetation characteristics from a statewide
lidar dataset for studies of secondary succession |
Ryan Emanuel and Robert Jackson |
|
|
Goetz |
Stand properties of fire disturbed
areas derived from multi-sensor observations across Alaska |
Goetz, S.J, A. Baccini, M. Sun, M.
Mack |
|
|
Harding |
ICESat Apparent Reflectance for
Land Surfaces: Design Constraint for Future Laser Altimeter Missions |
David Harding, Claudia Carabajal
and Vijay Suchdeo |
|
|
Houghton |
The Importance of Biomass in the
Global Carbon Cycle |
Houghton, Hall, et al. |
|
|
Hurtt |
The role of structure in vegetation
dynamic models |
Hurtt, Moorcroft, et al. |
|
|
Hurtt |
Beyond Potential Vegetation II:
Using Repeat Lidar Data on Changes in Vegetation Height to Test Model
Predictions of Ecosystem Dynamics |
Hurtt, Thomas, Dubayah |
|
|
Knyazikhin |
Retrieving horizontal and vertical
canopy structure from lidar and optical remote sensing data |
Y.Knyazikhin, R. Myneni, M. Schull
and F. Hall |
|
|
Mitchard |
Estimation of biomass changes from
woody encroachment in forest-savanna boundary in Africa from multi-temporal
L-band radar |
Mitchard, Saatchi, Mier |
|
|
Neuenschwander |
Minimum vegetation height, cover,
and change detection capabilities from large-footprint lidar |
Amy Neuenschwander, Timothy Urban,
Roberto Gutierrez, and Bob Schutz |
|
|
Neuenschwander |
Investigations of PALSAR/Lidar
fusion for vegetation monitoring |
Amy Neuenschwander, Timothy Urban,
and Sean Buckley |
|
|
Ni-Meister |
Combining Above-Canopy
Downward-Looking And Below-Canopy
Upward Hemispherical-Scanning Lidar
For Improved Above-Ground Biomass Retrieval |
Wenge Ni-Meister, Shihyan Lee, Alan
Strahler, Curtis Woodcock, Crystal
Schaaf, David L B Jupp, Guoqing Sun, John Ranson, J. Bryan Blair,
Michelle Hofton, Feng Gao, Tian Yao and Xiaoyuan Yang |
|
|
Palace |
Frequency
and return time of small and large disturbances across the Amazon tropical rain forest |
Fernando
D. B. Espirito-Santo, Manoel Gloor, Yadvinder Malhi, Michael Palace, Oliver
L. Phillips |
|
|
Pang |
Modeling spaceborne lidar
performance using simulation of waveforms from forested landscapes |
Yong Pang, Michael Lefsky, Guoqing
Sun and Jon Ranson |
|
|
Popescu |
Space-borne lidar vs. small
footprint airborne lidar: comparing the accuracy of forest structure metrics
at pixel level |
Sorin Popescu, Amy Neuenschwander,
and Tim Urban |
|
|
Radeloff |
Predicting forest songbird
diversity and abundance using Lidar-derived forest structure |
Lesak, Adrian A., T. J. Hawbaker,
A. M. Pidgeon, T. Gobakken, K. Contrucci, and V. C. Radeloff |
|
|
Radeloff |
Improved estimates of forest carbon
stocks and structure with a Lidar-optimized sampling design. |
Hawbaker, Todd J., V. C. Radeloff,
T. Gobakken, A. A. Lesak, E. Tromborg, and K. Contrucci |
|
|
Saatchi |
Thinking Beyond Saturation:
Estimation of Forest Structure and Biomass from Radar Measurements |
Saatchi, Marlier, Clark, Chazdon, Moorcroft, |
|
|
Saatchi |
Radar measurements of vegetation
structure |
Saatchi, Ranson, Siqueira, Simard,
Treuhaft, Sun, Sarabandi, Hensley, Moghaddam |
|
|
Saatchi |
Potential Fusion Techniques between
Imaging Radar and Sampling Lidar |
Saatchi(?), Lefsky, Dubayah, Hurtt,
Moorcroft |
|
|
Shugart |
Changes of vegetation structure in
disturbance and recovery |
Shugart, Clark, et al. |
|
|
Siqueira |
A Trade Study for Estimating
Vegetation Heights from Combined Airborne Lidar and InSAR over the Duke
Forest |
Siqueira, Hensley and Chapman |
|
|
Siqueira |
A SAR, InSAR and Lidar Study for
Measuring Vegetation Structure Over the Harvard Forest |
Siqueira, Ahmed, Chapman, Hensley,
and Bergen |
|
|
Siqueira |
A Survey of Temporal Decorrelation
from Spaceborne L-band Repeat-pass InSAR |
Ahmed, Siqueira, Bergen, Chapman
and Hensley |
|
|
Strahler |
Validation of LVIS Foliage Profiles
using a Ground-Based, Upward-Scanning Lidar (Echidna(R)) |
Alan Strahler, David Jupp, Curtis
Woodcock, Crystal Schaaf |
|
|
Sun |
A case study on canopy height and
biomass mapping with waveform lidar samples and L-band SAR data in Howland,
Maine |
G. Sun, Jon K. Ranson, Z. Guo and
W. Ni |
|
|
Walker |
Object-oriented InSAR/Lidar/Optical
fusion for Estimation of Vegetation Canopy Height and Aboveground Biomass |
Josef Kellndorfer and Wayne Walker |
|
|
Washington-Allen |
Environmental Tomography of a
Mesquite-dominated Dryland using LIDAR and GPR |
R.A. Washington-Allen, T. Boutton,
and S. Popescu |
|
|
Washington-Allen |
IFSAR -based Estimation of Standing
Biomass in an Oak Brush Ecosystem subject to Military Land Use |
R.A. Washington-Allen, R. Douglas
Ramsey, T. G. Van Niel, and R. Klaralus |
|