Wavelet-based spatiotemporal analyses of climate and vegetation for the Athabasca river basin in Canada

Monitoring spatiotemporal changes in climate and vegetation coverage are crucial for various purposes, including water, hazard, and agricultural management. Climate has an impact on vegetation, however, studying their relationship is challenging. We implemented the Least-Squares Wavelet (LSWAVE) sof...

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Bibliographic Details
Published in:International Journal of Applied Earth Observation and Geoinformation
Main Authors: Hatef Dastour, Ebrahim Ghaderpour, Mohamed Sherif Zaghloul, Babak Farjad, Anil Gupta, Hyung Eum, Gopal Achari, Quazi K. Hassan
Other Authors: Dastour, Hatef, Ghaderpour, Ebrahim, Sherif Zaghloul, Mohamed, Farjad, Babak, Gupta, Anil, Eum, Hyung, Achari, Gopal, Hassan, Quazi K.
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2022
Subjects:
MODIS
trend analysi
spectral analysi
coherency analysi
phase discrepancy
NDVI
land use/land cover
Athabasca River
Canada
Online Access:https://hdl.handle.net/11573/1686206
https://doi.org/10.1016/j.jag.2022.103044
Description
Summary:Monitoring spatiotemporal changes in climate and vegetation coverage are crucial for various purposes, including water, hazard, and agricultural management. Climate has an impact on vegetation, however, studying their relationship is challenging. We implemented the Least-Squares Wavelet (LSWAVE) software for investigating trend, coherency, and time lag estimation between climate and vegetation time series. We utilized Normalized Difference Vegetation Index (NDVI) time series provided by the Terra satellite and hybrid climate time series. We found that the seasonal cycles of climate and NDVI are coherent with time delay. For the entire Athabasca River Basin (ARB), the most coherent component was the annual cycle with 84% annual coherency between vegetation and temperature and 46% between vegetation and precipitation. The annual cycles of temperature and precipitation led the ones in vegetation by about two and three weeks, respectively. Relatively lower coherency was observed in the mountainous region (upper ARB) and higher coherency in the middle ARB. From the cross-spectrograms, a clear time delay pattern was observed between the annual cycles of climate and vegetation since 2000 but not for other high-frequency seasonal cycles. The results also highlighted the advantages of LSWAVE algorithms over traditional algorithms, such as linear regression and correlation. Furthermore, we analyzed the annual land use and land cover data provided by the Terra and Aqua satellites and discussed their linkage with the climate and NDVI results.

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