Abstract
ABSTRACTLorey’s height, representative of mean height in uneven-aged forest stands, is a valuable parameter for forest ecosystem management. While in situ measures provide the most precise information, remote-sensing techniques may provide less expensive but denser and more operational alternative of Lorey’s height estimation over highly mountainous areas. This research aims first to evaluate the performances of two nonparametric data mining methods, random forest (RF) and artificial neural network (ANN), for estimation of Lorey’s height using ice, cloud and land elevation satellite/geoscience laser altimeter system (ICESat/GLAS) in Hyrcanian forests of Iran and then to provide Lorey’s height map using a synergy of ICESat/GLAS and optical images (TM and SPOT). RF and ANN GLAS height models were developed using waveform deterministic metrics, principal components (PCs) from principal component analysis (PCA) and terrain index (TI) extracted from a digital elevation model (DEM). The best result was obtained using an ANN combining first three PCs of PCA and waveform extent ʺWextʺ (RMSE = 3.4 m, RMSE% = 12.4). In order to map Lorey’s height, GLAS-estimated heights were regressed against indices derived from optical images and also topographic information. The best model (RF regression with RMSE = 5.5 m and = 0.59) was applied on the entire study area, and a wall-to-wall height map was generated. This map showed relatively good compatibility with in situ measurements collected in part of the study area.
Highlights
Measuring biophysical parameters of forests is required for forest ecosystem management
Laser-reflected energy by all intercepting objects in each footprint was recorded by a telescope, resulting in a waveform representing the vertical profile of laser-illuminated surfaces
Model 1 with four variables including Ln (H50), TI1.5 (TI raised to the power of 1.5), Wext2.5 and Ln(Wext) produced an root mean square error (RMSE) of 5.4 m
Summary
Measuring biophysical parameters of forests is required for forest ecosystem management. Many forest stands, all over the world, are located in inaccessible or remote areas This highlights the importance of remotely sensed techniques in global estimation of forest biophysical parameters. Applying spaceborne lidar for estimation of forest biophysical parameters over large extent area has been investigated since ice, cloud and land elevation satellite (ICESat) was launched into the space in 2003. The geoscience laser altimeter system (GLAS) onboard ICESat operated for a total of 18 missions during its operational years (2003–2009). It provides a full waveform of illuminated objects in nominally 70-m-diameter footprints on the surface
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