A Lidar Biomass Index of Tidal Marshes from Drone Lidar Point Cloud

Accompanying climate change and sea level rise, tidal marsh mortality in coastal wetlands has been globally observed that urges the documentation of high-resolution, 3D marsh inventory to assist resilience planning. Drone Lidar has proven useful in extracting the fine-scale bare earth terrain and ca...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2024-06, Vol.16 (11), p.1823
Main Authors: Wang, Cuizhen, Morris, James T., Smith, Erik M.
Format: Article
Language:English
Subjects:
3D mapping
Biomass
biomass index
Canopies
Climate change
Clouds
Coasts
Deep learning
Drone aircraft
drone Lidar point cloud
Drones
Environmental aspects
Estuaries
Feasibility studies
Height
Lidar
Mapping
Marshes
Measurement
Morphology
Optical radar
Plant communities
Planting density
Plants (botany)
point density
Sea level
Sea level rise
Spartina alterniflora
Tidal marshes
Topography
Vegetation
Vegetation mapping
Wetlands
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Summary:Accompanying climate change and sea level rise, tidal marsh mortality in coastal wetlands has been globally observed that urges the documentation of high-resolution, 3D marsh inventory to assist resilience planning. Drone Lidar has proven useful in extracting the fine-scale bare earth terrain and canopy height. Beyond that, this study performed marsh biomass mapping from drone Lidar point cloud in a S. alterniflora-dominated estuary on the Southeast U.S. coast. Three point classes (ground, low-veg, and high-veg) were classified via point cloud deep learning. Considering only vegetation points in the vertical profile, a profile area-weighted height (HPA) was extracted at a grid size of 50 cm Ă— 50 cm. Vegetation point densities were also extracted at each grid. Adopting the plant-level allometric equations of stem biomass from long-term S. alterniflora surveys, a Lidar biomass index (Lidar_BI) was built to represent the relative quantity of marsh biomass in a range of [0, 1] across the estuary. Compared with the clipped dry biomass samples, it achieved a comparable and slightly better performance (R2 = 0.5) than the commonly applied spectral index approaches (R2 = 0.4) in the same marsh field. This study indicates the feasibility of the drone Lidar point cloud for marsh biomass mapping. More advantageously, the drone Lidar approach yields information on plant community architecture, such as canopy height and plant density distributions, which are key factors in evaluating marsh habitat and its ecological services.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs16111823