Abstract
Vegetation cover estimation for overstory and understory layers provides valuable information for modeling forest carbon and water cycles and refining forest ecosystem function assessment. Although previous studies demonstrated the capability of light detection and ranging (LiDAR) in the three-dimensional (3D) characterization of forest overstory and understory communities, the high cost inhibits its application in frequent and successive survey tasks. Low-cost commercial red–green–blue (RGB) cameras mounted on unmanned aerial vehicles (UAVs), as LiDAR alternatives, provide operational systems for simultaneously quantifying overstory crown cover (OCC) and understory vegetation cover (UVC). We developed an effective method named back-projection of 3D point cloud onto superpixel-segmented image (BAPS) to extract overstory and forest floor pixels using 3D structure-from-motion (SfM) point clouds and two-dimensional (2D) superpixel segmentation. The OCC was estimated from the extracted overstory crown pixels. A reported method, called half-Gaussian fitting (HAGFVC), was used to segement green vegetation and non-vegetation pixels from the extracted forest floor pixels and derive UVC. The UAV-based RGB imagery and field validation data were collected from eight forest plots in Saihanba National Forest Park (SNFP) plantation in northern China. The consistency of the OCC estimates between BAPS and canopy height model (CHM)-based methods (coefficient of determination: 0.7171) demonstrated the capability of the BAPS method in the estimation of OCC. The segmentation of understory vegetation was verified by the supervised classification (SC) method. The validation results showed that the OCC and UVC estimates were in good agreement with reference values, where the root-mean-square error (RMSE) of OCC (unitless) and UVC (unitless) reached 0.0704 and 0.1144, respectively. The low-cost UAV-based observation system and the newly developed method are expected to improve the understanding of ecosystem functioning and facilitate ecological process modeling.
Highlights
Forest ecosystems generally comprise overstory and understory communities [1,2]
This study aimed to develop a method named back-projection of 3D point cloud onto superpixel-segmented image (BAPS) for automatically estimating overstory crown cover (OCC) and understory vegetation cover (UVC) of forests from unmanned aerial vehicles (UAVs)-based RGB images and validate the accuracy of BAPS using the estimation from reported methods, i.e., canopy height model (CHM)-based method and supervised classification (SC) method, and using in situ reference values
The CHM method yielded an improved map of the crown area, but it highly depended on the completeness of the SfM point cloud of a plot and the grid resolution setting
Summary
Forest ecosystems generally comprise overstory and understory communities [1,2]. The overstory layer (>2 m) refers to the uppermost layer of woody plants [3], whereas the understory layerRemote Sens. 2020, 12, 298 2 of 17 2 of 18(0–2 mov)efrasFltloosrreyusntladyeeecrrost(hy>se2teommv)esrresgfteeornrseyrtoallaltyyheercuo[pm4p]pearrnimsdeoisontvclealurysedtroerosyfhweanrobdoadcyuenopdulaesrnspttsolar[3yn]t,scw,osmhhemrreuuabnssitt,ihseetsuum[n1d,p2es]r.,sstToahrpyelings, seedllianygesr, (g0–ra2smse)sf,asllms aulnldsetrattuhereovtreerestso,reytcla. ye(Fr i[g4u] raend1)i.ncBluodtheschoemrbmacuenouitsiepslapnltasy, sihmrupbosr, tsatnumt rposl,es in waters/acpalribngosn,/sneuedtrliinegnst, cgyracslseesm, somdaelllisntgatuarnedtrfeoerse, esttce. (cFoigsyusrete1m). Seveerraallccoommpponoennetnstosfothf itshfiisgufirgeuorreigoinriagteindaftreodmfarom a free hfirgehe -hqiugha-lqituyaplitiyctpuircetulriberlaibrryarwy ewbesbitseite(h(thttptpss:/:/w/wwwww..ppiikpnngg..ccoomm/)/.)
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