期刊
REMOTE SENSING OF ENVIRONMENT
卷 186, 期 -, 页码 372-392出版社
ELSEVIER SCIENCE INC
DOI: 10.1016/j.rse.2016.08.018
关键词
Multitemporal lidar; Hypertemporal lidar; Multispectral lidar; Hyperspectral lidar; Laser return intensity; Data dimensions
资金
- USDA-NIFA [2011-67003-3034, 2011-68002-30191]
- NASA Terrestrial Ecology [NNX12AK83G, NNX15AT86A]
- Ministry of Science, Research and Arts, Baden-Wuerttemberg [7635.521/Hofle]
- Austrian Research Promotion Agency (FFG) project Alpine Airborne Hydromapping - from research to practice
- NASA
- NASA [796392, NNX12AK83G, 43728, NNX15AT86A] Funding Source: Federal RePORTER
Capturing and quantifying the world in three dimensions (x,y,z) using light detection and ranging (lidar) technology drives fundamental advances in the Earth and Ecological Sciences (EES). However, additional lidar dimensions offer the possibility to transcend basic 3-D mapping capabilities, including i) the physical time (t) dimension from repeat lidar acquisition and ii) laser return intensity (LRIK) data dimension based on the brightness of single- or multi-wavelength (lambda) laser returns. The additional dimensions thus add to the x,y, and z dimensions to constitute the five dimensions of lidar (x.y,z, t, lambda n). This broader spectrum of lidar dimensionality has already revealed new insights across multiple EES topics, and will enable a wide range of new research and applications. Here, we review recent advances based on repeat lidar collections and analysis of LRI data to highlight novel applications of lidar remote sensing beyond 3-D. Our review outlines the potential and current challenges of time and LRI information from lidar sensors to expand the scope of research applications and insights across the full range of EES applications. (C) 2016 Elsevier Inc. All rights reserved.
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