Estimating vegetation and litter biomass fractions in rangelands using structure-from-motion and LiDAR datasets from unmanned aerial vehicles

Authors: FERNANDEZ-GUISURAGA, JOSE - University Of Leon; CALVO, LEONOR - University Of Leon; ENTERKINE, JOSH - Boise State University; PRICE, WILLIAM - Oregon State University; DINKINS, JONATHAN - Oregon State University; JENSEN, K. - University Of Idaho; Olsoy, Peter; ARISPE, SERGIO - Oregon State University

Submitted to: Landscape Ecology
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 10/6/2024
Publication Date: 10/14/2024
Citation: Fernandez-Guisuraga, J.M., Calvo, L., Enterkine, J., Price, W.J., Dinkins, J.B., Jensen, K.S., Olsoy, P.J., Arispe, S.A. 2024. Estimating vegetation and litter biomass fractions in rangelands using structure-from-motion and LiDAR datasets from unmanned aerial vehicles. Landscape Ecology. 39. Article 181. https://doi.org/10.1007/s10980-024-01979-w.
DOI: https://doi.org/10.1007/s10980-024-01979-w

Interpretive Summary: Rangelands in the western U.S. are currently under the invasion of annual grasses, such as cheatgrass (Bromus tectorum), medusahead (Taeniatherum caput-medusae), and ventenata (Ventenata dubia), which promote high litter accumulation that cause larger, more frequent wildfires. However, litter is difficult to measure with existing remote sensing methods that are either too coarse of spatial resolution or unable to penetrate the dense mat of medusahead litter. We used unoccupied aerial systems (UAS, i.e., drones) equipped with a light detection and ranging (LiDAR) and optical sensors to test several predictors for litter, vegetation, and total biomass fractions from clipped vegetation. We found that UAS equipped with LiDAR was able to penetrate dense litter and accurately estimate all three biomass fractions better than optical sensors alone. These results demonstrate a promising tool for quantifying litter and vegetation fractions of biomass, which improves our ability to measure wildfire fuels and model fire behavior in rangelands.

Technical Abstract: Context - The invasion of annual grasses in western U.S. rangelands promotes high litter accumulation throughout the landscape that perpetuates a grass-fire cycle threatening biodiversity. Objectives - To provide novel evidence on the potential of fine spatial and structural resolution remote sensing data derived from Unmanned Aerial Vehicles (UAVs) to separately estimate the biomass of vegetation and litter fractions in sagebrush ecosystems. Methods - We calculated several plot-level metrics with ecological relevance and representative of the biomass fraction distribution by strata from UAV Light Detection and Ranging (LiDAR) and Structure-from-Motion (SfM) datasets and regressed those predictors against vegetation, litter, and total biomass fractions harvested in the field. We also tested a hybrid approach in which we used digital terrain models (DTMs) computed from UAV LiDAR data to height-normalize SfM-derived point clouds (UAV SfM-LiDAR). Results - The metrics derived from UAV LiDAR data had the highest predictive ability in terms of total(R2 = 0.74) and litter (R2= 0.59) biomass, while those from the UAV SfM-LiDAR provided the highest predictive performance for vegetation biomass (R2 = 0.77 versus R2 = 0.72 for UAV LiDAR). In turn, SfM and SfM-LiDAR point clouds indicated a pronounced decrease in the estimation performance of litter and total biomass. Conclusions - Our results demonstrate that high-density UAV LiDAR datasets are essential for consistently estimating all biomass fractions through more accurate characterization of (i) the vertical structure of the plant community beneath top-of-canopy surface and (ii) the terrain microtopography through thick and dense litter layers than achieved with SfMderived products.