Abstract
Observations of vegetation phenology at regional-to-global scales provide important information regarding seasonal variation in the fluxes of energy, carbon, and water between the biosphere and the atmosphere. Numerous algorithms have been developed to estimate phenological transition dates using time series of remotely sensed spectral vegetation indices. A key challenge, however, is that different algorithms provide inconsistent results. This study provides a comprehensive comparison of start of season (SOS) and end of season (EOS) phenological transition dates estimated from 500 m MODIS data based on two widely used sources of such data: the TIMESAT program and the MODIS Global Land Cover Dynamics (MLCD) product. Specifically, we evaluate the impact of land cover class, criteria used to identify SOS and EOS, and fitting algorithm (local versus global) on the transition dates estimated from time series of MODIS enhanced vegetation index (EVI). Satellite-derived transition dates from each source are compared against each other and against SOS and EOS dates estimated from PhenoCams distributed across the Northeastern United States and Canada. Our results show that TIMESAT and MLCD SOS transition dates are generally highly correlated (r = 0.51-0.97), except in Central Canada where correlation coefficients are as low as 0.25. Relative to SOS, EOS comparison shows lower agreement and higher magnitude of deviations. SOS and EOS dates are impacted by noise arising from snow and cloud contamination, and there is low agreement among results from TIMESAT, the MLCD product, and PhenoCams in vegetation types with low seasonal EVI amplitude or with irregular EVI time series. In deciduous forests, SOS dates from the MLCD product and TIMESAT agree closely with SOS dates from PhenoCams, with correlations as high as 0.76. Overall, our results suggest that TIMESAT is well-suited for local-to-regional scale studies because of its ability to tune algorithm parameters, which makes it more flexible than the MLCD product. At large spatial scales, where local tuning is not feasible, the MLCD product provides a readily available data set based on a globally consistent approach that provides SOS and EOS dates that are comparable to results from TIMESAT.
Highlights
Land surface phenology (LSP) observations derived from satellites provide information related to seasonal dynamics in the net ecosystem exchange of carbon [1,2] and surface energy and water balance [3,4] at regional-to-global scales
We present a comparison of start of season (SOS) and end of season (EOS) dates from TIMESAT and the MODIS Global Land Cover Dynamics (MLCD) product across a range of land cover types and ecological conditions
This study provides a comprehensive comparison of start of season and end of season phenology for the two most widely used satellite-based LSP sources: TIMESAT and the MODIS Global
Summary
Land surface phenology (LSP) observations derived from satellites provide information related to seasonal dynamics in the net ecosystem exchange of carbon [1,2] and surface energy and water balance [3,4] at regional-to-global scales. LSP has been shown to reflect year-to-year variation in weather and is, a sensitive indicator of ecosystem response to long-term changes in climate [4,5,6]. Consistent with perturbations expected from climate change, long-term phenology studies have identified widespread trends towards earlier springs and a lengthening of the growing season [1,6,7,8]. Observed trends towards delayed leaf senescence are less pronounced and are spatially heterogeneous [4,7]. These changes have important implications for ecosystem productivity and function [1,4,9]. Accurate information regarding the start and end of the growing season is important for monitoring and modeling the impacts of climate change on vegetation and ecosystem processes
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