Abstract
The analysis of the Earth system and interactions among its spheres is increasingly important to improve the understanding of global environmental change. In this regard, Earth observation (EO) is a valuable tool for monitoring of long term changes over the land surface and its features. Although investigations commonly study environmental change by means of a single EO-based land surface variable, a joint exploitation of multivariate land surface variables covering several spheres is still rarely performed. In this regard, we present a novel methodological framework for both, the automated processing of multisource time series to generate a unified multivariate feature space, as well as the application of statistical time series analysis techniques to quantify land surface change and driving variables. In particular, we unify multivariate time series over the last two decades including vegetation greenness, surface water area, snow cover area, and climatic, as well as hydrological variables. Furthermore, the statistical time series analyses include quantification of trends, changes in seasonality, and evaluation of drivers using the recently proposed causal discovery algorithm Peter and Clark Momentary Conditional Independence (PCMCI). We demonstrate the functionality of our methodological framework using Indo-Gangetic river basins in South Asia as a case study. The time series analyses reveal increasing trends in vegetation greenness being largely dependent on water availability, decreasing trends in snow cover area being mostly negatively coupled to temperature, and trends of surface water area to be spatially heterogeneous and linked to various driving variables. Overall, the obtained results highlight the value and suitability of this methodological framework with respect to global climate change research, enabling multivariate time series preparation, derivation of detailed information on significant trends and seasonality, as well as detection of causal links with minimal user intervention. This study is the first to use multivariate time series including several EO-based variables to analyze land surface dynamics over the last two decades using the causal discovery algorithm PCMCI.
Highlights
The results indicate that for 100.0%, 99.8%, and 99.8% of all grids, lag-1 autocorrelation is significant for normalized difference vegetation index (NDVI), Global Waterpack (GWP), and Global Snowpack (GSP), respectively
We developed a novel methodological framework including both the preparation of multisource data to generate a unified feature space as well as the consecutive application of statistical time series analysis techniques
These include the calculation of trends and changes in seasonality, as well as the application of the causal discovery algorithm Peter and Clark Momentary Conditional Independence (PCMCI)
Summary
A continuous monitoring of these transformation processes is required to quantify and understand their characteristics, drivers, and impacts [2]. In this context, time series analysis tools are crucial to identify spatio-temporal patterns and examine changes over time [3]. In addition to raw EO data, many subsequently generated geospatial data products, so-called analysis ready data (ARD) that characterize the global land surface are available.
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