Abstract
The United States Forest Service Forest Inventory and Analysis (FIA) Program provides a diverse selection of data used to assess the status of the nation’s forests using sample locations dispersed throughout the country. Airborne laser scanning (ALS) systems are capable of producing accurate measurements of individual tree dimensions and also possess the ability to characterize forest structure in three dimensions. This study investigates the potential of discrete return ALS data for modeling forest aboveground biomass (AGBM) and gross volume (gV) at FIA plot locations in the Malheur National Forest, eastern Oregon utilizing three analysis levels: (1) individual subplot (r = 7.32 m); (2) plot, comprising four clustered subplots; and (3) hectare plot (r = 56.42 m). A methodology for the creation of three point cloud-based airborne LiDAR metric sets is presented. Models for estimating AGBM and gV based on LiDAR-derived height metrics were built and validated utilizing FIA estimates of AGBM and gV derived using regional allometric equations. Simple linear regression models based on the plot-level analysis out performed subplot-level and hectare-level models, producing R2 values of 0.83 and 0.81 for AGBM and gV, utilizing mean height and the 90th height percentile as predictors, respectively. Similar results were found for multiple regression models, where plot-level analysis produced models with R2 values of 0.87 and 0.88 for AGBM and gV, utilizing multiple height percentile metrics as predictor variables. Results suggest that the current FIA plot design can be used with dense airborne LiDAR data to produce area-based estimates of AGBM and gV, and that the increased spatial scale of hectare plots may be inappropriate for modeling AGBM of gV unless exhaustive tree tallies are available. Overall, this study demonstrates that ALS data can be used to create models that describe the AGBM and gV of Pacific Northwest FIA plots and highlights the potential of estimates derived from ALS data to augment current FIA data collection procedures by providing a temporary intermediate estimation of AGBM and gV for plots with outdated field measurements.
Highlights
Light detection and ranging (LiDAR) is a laser-based, active remote sensing system, which collects ranging data utilizing the speed of light and information about the flight time of a laser pulse [1]
Individual Simple linear regression (SLR) models were created for the aboveground biomass (AGBM) and gross volume (gV) estimates using each of the point cloud-based metrics calculated for the individual subplots, plots, and the hectare plots
Results for the multiple regression (MR) analyses show that point cloud metrics derived from the clustered subplots were able to account for the most variability in field estimated AGBM and gV, followed by models based on individual subplot metrics, and models based on hectare plot metrics
Summary
Light detection and ranging (LiDAR) is a laser-based, active remote sensing system, which collects ranging data utilizing the speed of light and information about the flight time of a laser pulse [1]. In this context, flight time refers to the time it takes for a given laser pulse to travel from a system, backscatter from an object, and return back to the system. The increased use of LiDAR systems to acquire data over forested areas can be attributed to their ability to cover extents of local or regional scales and accurately quantify the three-dimensional structure of the forest. Previous studies have demonstrated the usefulness of LiDAR for: (1) Forest measurements [2,3,4,5,6,7,8,9,10,11]; (2) habitat analysis [12,13,14]; (3) estimation of forest biophysical parameters [15,16,17,18,19,20,21,22,23,24,25,26,27];
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