Publications
Export 40 results:
. Applications in Hyperspectral and Lidar Remote Sensing to Improve the Characterization of Low-Height Sparse Vegetation Ecosystems. Department of Geosciences. 2011;Doctor of Philosophy:1-88. Available at: http://geology.isu.edu/dml/thesis/Mitchell_Jessica_Dissertation_2010.pdf. Abstract
. A slope-based method for matching elevation surfaces. Photogrammetric Engineering and Remote Sensing. 2011;77(7):743-750. Available at: http://digital.ipcprintservices.com/publication/?i=74137. Abstract
. Sagebrush Steppe Shrub Height and Canopy Cover Estimation Using LiDAR and Landsat 5 TM Data. Department of Geosciences. 2011;Master of Science:1-93. Available at: http://bcal.geology.isu.edu/docs/Bond_Thesis_ISU_2011.pdf. Abstract
Comparison of Two Open Source LiDAR Surface Filtering Algorithms. Remote Sensing. 2011;3:638-649. Available at: http://www.mdpi.com/2072-4292/3/3/638/pdf. Abstract
Errors in LiDAR-derived shrub height and crown area on sloped terrain. Journal of Arid Environments. 2011;75:377-382. Available at: http://bcal.geology.isu.edu/docs/Glennetal2010JAE.pdf. Abstract
. LiDAR: providing structure. Frontiers in Ecology and the Environment. 2011;9:261-262. Available at: http://www.idaholidar.org/f/articles/Vierling_11.WB.pdf. Abstract
. LiDAR-Based Classification of Sagebrush Community Types. Rangeland Ecology & Management. 2011;64:92-98. Available at: http://bcal.geology.isu.edu/docs/Teki/LiDAR-based-classification-of-sagebrush-community-types_2011_Rangeland-Ecology-and-Management.pdf. Abstract
Small-footprint Lidar Estimations of Sagebrush Canopy Characteristics. Photogrammetric Engineering and Remote Sensing. 2011;77:521-530. Available at: http://bcal.geology.isu.edu/docs/ASPRS_inpress_May2011.pdf. Abstract
Spinning a laser web: predicting spider distributions using LiDAR. Ecological Applications. 2011;21:577-588. Abstract
Vegetation and slope effects on accuracy of a LiDAR-derived DEM in the sagebrush steppe. Remote Sensing Letters. 2011;2:317 - 326. Available at: http://bcal.geology.isu.edu/docs/Spaete%20et%20al%202010.pdf. Abstract
. FEMA Standards For Lidar And Other High Quality Digital Topography. Boise; 2010:1-26. Available at: http://www.idaholidar.org/f/reports/FEMA_Standards_for_Lidar_Specs.pdf. Abstract
. Sample LiDAR Data Delivery Requirements. Boise; 2010:1-2. Available at: http://www.idaholidar.org/f/reports/Sample-LiDAR-Data-Delivery-Requirement.pdf. Abstract
Data Flow for LiDAR Acquisition and Processing. In: Idaho NSF EPSCoR Annual Meeting. Idaho NSF EPSCoR Annual Meeting. Boise; 2010. Available at: http://www.idaholidar.org/f/reports/Poster-EPSCoR-ID-2010-LiDARWorkflow.pdf. Abstract
. Design, Development, and Application of LiDAR Data Processing Tools. Department of Geosciences. 2010;Master of Science:1-77. Available at: http://bcal.geology.isu.edu/docs/Ehinger_thesis_0629_Final.pdf. Abstract
. Relationships of aeolian erosion and deposition with LiDAR-derived landscape surface roughness following wildfire. Geomorphology. 2010;119:135-145. Available at: http://bcal.geology.isu.edu/docs/Sankey%20et%20al%202010_Geomorphology.pdf. Abstract
. Simultaneous measurements of plant structure and chlorophyll content in broadleaf saplings with a terrestrial laser scanner. Remote Sensing of Environment. 2010;114:2229-2237. Abstract
. Aeolian sediment transport following wildfire in sagebrush steppe. Journal of Arid Environments. 2009;73:912-919. Available at: http://bcal.geology.isu.edu/docs/Sankeyetal_2009a_JAE.pdf. Abstract
. Characterizing forest succession with lidar data: An evaluation for the Inland Northwest, USA. Remote Sensing of Environment. 2009;113:946-956. Available at: http://www.fs.fed.us/rm/pubs_other/rmrs_2008_falkowski_m002.pdf. Abstract
. Corrigendum to "Nearest neighbor imputation of species-level, plot-scale forest structure attributes from LiDAR data". Remote Sensing of Environment. 2009;113:289-290. Available at: http://www.fs.fed.us/rm/pubs_other/rmrs_2009_hudak_a001.pdf. Abstract
A cross-comparison of field, spectral, and lidar estimates of forest canopy cover. Canadian Journal of Remote Sensing. 2009;35:447-459. Available at: http://www.fs.fed.us/rm/pubs_other/rmrs_2009_smith_a001.pdf. Abstract
. Estimation of fire severity using pre- and post-fire LiDAR data in sagebrush steppe rangelands. International Journal of Wildland Fire. 2009;18:848-856. Available at: http://bcal.geology.isu.edu/docs/Cheng_Glenn_2009_IJWF.pdf. Abstract
. Integrating LiDAR Intensity and Elevation Data for Terrain Characterization in a Forested Area. IEEE Geoscience and Remote Sensing Letters. 2009;6:463-466. Available at: http://bcal.geology.isu.edu/docs/IEEE_DTM_2009.pdf. Abstract
Mapping snags and understory shrubs for a LiDAR-based assessment of wildlife habitat suitability. Remote Sensing of Environment. 2009;113:2533-2546. Available at: http://www.fs.fed.us/global/iitf/pubs/ja_iitf_2009_Martinuzzi003.pdf. Abstract
. LIDAR Detection of Ladder Fuels in a North Idaho Mixed Conifer Forest. College of Graduate Studies. 2008;Master of Science:49. Available at: http://www.idaholidar.org/sites/default/files/Lidar_detection_of_ladder_fuels[revisions7]_ath.pdf. Abstract
. Discrete return lidar-based prediction of leaf area index in two conifer forests. Remote Sensing of Environment. 2008;112:3947-3957. Available at: http://www.fs.fed.us/rm/pubs_other/rmrs_2008_jensen_j001.pdf. Abstract