Abstract
The sparse canopy cover and large contribution of bright background soil, along with the heterogeneous vegetation types in close proximity, are common challenges for mapping dryland vegetation with remote sensing. Consequently, the results of a single classification algorithm or one type of sensor to characterize dryland vegetation typically show low accuracy and lack robustness. In our study, we improved classification accuracy in a semi-arid ecosystem based on the use of vegetation optical (hyperspectral) and structural (lidar) information combined with the environmental characteristics of the landscape. To accomplish this goal, we used both spectral angle mapper (SAM) and multiple endmember spectral mixture analysis (MESMA) for optical vegetation classification. Lidar-derived maximum vegetation height and delineated riparian zones were then used to modify the optical classification. Incorporating the lidar information into the classification scheme increased the overall accuracy from 60% to 89%. Canopy structure can have a strong influence on spectral variability and the lidar provided complementary information for SAM’s sensitivity to shape but not magnitude of the spectra. Similar approaches to map large regions of drylands with low uncertainty may be readily implemented with unmixing algorithms applied to upcoming space-based imaging spectroscopy and lidar. This study advances our understanding of the nuances associated with mapping xeric and mesic regions, and highlights the importance of incorporating complementary algorithms and sensors to accurately characterize the heterogeneity of dryland ecosystems.
Highlights
Vegetation in semi-arid ecosystems plays an important role in regulating the global carbon balance
Overall accuracy derived from the final SCM for the multiple endmember spectral mixture analysis (MESMA) shrub, grass, and soil cover was 0.67 (Table 2)
This study demonstrated that lidar-derived height distributions used for endmember selection and as additional fractional constraints reduced the confusion between spectrally similar classes in an urban area
Summary
Vegetation in semi-arid ecosystems (i.e., drylands) plays an important role in regulating the global carbon balance. Differentiating vegetation species and their respective roles in regional scale carbon dynamics in semi-arid and other dryland ecosystem types remain challenging. Large environmental gradients (e.g., elevation) and variability in climate over landscapes with complex topography create conditions for disparate biomes to exist within close proximity to each other [3,4]. Higher elevation sites and riparian areas are populated with alpine and deciduous vegetation, respectively, while drier, lower elevation landscapes can be dominated by shrubland vegetation. This heterogeneity makes mapping and quantifying vegetation species and structure inherently difficult at regional scales in drylands
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