Abstract
The 2018–2019 Central European drought had a grave impact on natural and managed ecosystems, affecting their health and productivity. We examined patterns in hyperspectral VNIR imagery using an unsupervised learning approach to improve ecosystem monitoring and the understanding of grassland drought responses. The main objectives of this study were (1) to evaluate the application of simplex volume maximisation (SiVM), an unsupervised learning method, for the detection of grassland drought stress in high-dimensional remote sensing data at the ecosystem scale and (2) to analyse the contributions of different spectral plant and soil traits to the computed stress signal. The drought status of the research site was assessed with a non-parametric standardised precipitation–evapotranspiration index (SPEI) and soil moisture measurements. We used airborne HySpex VNIR-1800 data from spring 2018 and 2019 to compare vegetation condition at the onset of the drought with the state after one year. SiVM, an interpretable matrix factorisation technique, was used to derive typical extreme spectra (archetypes) from the hyperspectral data. The classification of archetypes allowed for the inference of qualitative drought stress levels. The results were evaluated using a set of geophysical measurements and vegetation indices as proxy variables for drought-inhibited vegetation growth. The successful application of SiVM for grassland stress detection at the ecosystem canopy scale was verified in a correlation analysis. The predictor importance was assessed with boosted beta regression. In the resulting interannual stress model, carotenoid-related variables had among the highest coefficient values. The significance of the photochemical reflectance index that uses 512 nm as reference wavelength (PRI512) demonstrates the value of combining imaging spectrometry and unsupervised learning for the monitoring of vegetation stress. It also shows the potential of archetypical reflectance spectra to be used for the remote estimation of photosynthetic efficiency. More conclusive results could be achieved by using vegetation measurements instead of proxy variables for evaluation. It must also be investigated how the method can be generalised across ecosystems.
Highlights
We investigated the drought and soil water status of the research site with threemonths standardised precipitation–evapotranspiration index (SPEI) values and relative soil water content measurements
SPEI time series shows that the 2018 hyperspectral flight took place at the onset of an exceptional meteorological drought period that lasted until early 2019
The main achievement of this study is the successful application of simplex volume maximisation (SiVM) for an unsupervised classification of grassland drought stress at the ecosystem scale
Summary
The changing background climate state is projected to lead to an increase in the frequency and severity of extreme weather and climate events in many parts of the world [1,2,3]. In Europe, prolonged droughts are among the most damaging natural hazards, both socioeconomically and environmentally [4]. Severe droughts impair agri- and silvicultural productivity, and they can have longer-term effects on vegetation health [5]. Pre-symptomatic vegetation stress monitoring is essential for analysing changes in plant functioning linked to extreme events like the 2018–2019 Central European drought on a broader scale. Remote sensing techniques for fast and reliable stress monitoring become increasingly valuable
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