https://orcid.org/0000-0002-0308-0443
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ABSTRACT
Due to its impact on our ecosystem (i.e. vegetation, soil, water, etc.), global change has become more significant over time. Therefore, several biophysical indices (e.g. NDVI, NDWI, NDBI, etc.) have been developed to quantify, assess, and monitor the ecosystem reaction to these changes. Numerous and various satellite imagery can be integrated into multiple analysis approaches to carry out this assessment. One of the efficient methods in this field is Time Series Analysis (TSA), which allows the decomposition of data into three components (i.e. seasonality, irregularity, and trend). In this paper, we considered 100 biophysical indices, which we classified into six categories (i.e. vegetation, water, soil, burn, building, and others). These indices were computed using images of different satellite sensors ranging from coarse to high resolution [i.e. AVHRR, MODIS, Landsat-8, Sentinel-2, etc.] considering two study cases. The first case involved monitoring the Mediterranean basin from 2010 to 2014. The second focused on four specific climate zones -most dominant within the Mediterranean basin- (i.e. San Severo, Tangier, Tobruk, and Murcia), which were conducted from 2015 to 2022. High-performance computing of biophysical indices in both study cases resulted in more than 30,000 images used in generating a significant number of time series. To examine these results and quantify the relationship between satellites across different parameters, two analysis methods (i.e. trend analysis and correlation analysis) were employed. Trend analysis results showed that in the first case, 87% of indices trends are harmonized between AVHRR and SPOT-VGT. Moreover, in the second case, the percentages of biophysical indices that showed harmonized trends among all satellites are 55% for San Severo and Tobruk, 49% for Tangier, and 34% for Murcia. Finally, this study shows that satellite-derived biophysical indices and their trends may be significantly impacted by spatial scale, climate, satellite resolution, time series length, and outliers.
Highlights
Database of more than 100 biophysical indices, derived from seven different satellites.
1096 Time series from 2010 to 2022 of 100 biophysical indices applied in two study cases (i.e. Mediterranean basin, and four Mediterranean climate zones).
Comparative study of 1096 biophysical indices time series trends, and satellites pairwise correlation matrices.
Acknowledgements
This work is supported in part by the University Abdelmalek Essaâdi Thematic project, 2019 – 2022, Monitoring land cover dynamics of the TTA region in the context of global warming: Contribution of Earth’s observation satellites and high-performance computing.
Disclosure statement
No potential conflict of interest was reported by the authors.