Abstract
Satellites have different revisit frequencies (i.e., temporal resolutions), ranging from daily to monthly. The satellite revisit frequencies suitable for accurately monitoring the phenology of deciduous broad-leaved forests (DBF) are not well-known. To fill this knowledge gap, this study used MODIS Daily Nadir BRDF-Adjusted images to simulate EVI time series with a wide range of temporal resolutions from daily to 52 days, to investigate the impacts of satellite revisit frequency on monitoring spatial and temporal patterns of spring phenology, i.e., the start of season (SOS), of DBF in North America. Then, these EVI time series were used to extract SOS by two common phenology extraction methods (i.e., relative threshold and curvature methods). Our results reveal that 1 ) low temporal resolutions cannot accurately reconstruct real vegetation growth profile, which generally causes a false early SOS detection, 2 ) the impact of temporal resolutions is nonlinear. The accuracy of SOS detection from data with relatively high frequencies (e.g., 7 days) is only slightly lower than that from daily time series but the accuracy decreases largely with low frequencies, and 3 ) validation with ground observations from PhenoCam Network stations and an experiment using three real satellite datasets (i.e., MODIS, Landsat 8, and Sentinel-2) confirm the findings from our simulation study. This study suggests that satellites with medium temporal resolutions, such as Sentinel-2 and Landsat 8, could extract reliable phenology metrics in non-cloudy regions.
Highlights
T HE start of season (SOS), named spring phenology, one of the most critical recurring growth phases of vegetation dynamics, has been documented as an effective indicator of regional environmental condition change
It is reasonable to assume that SOS derived from daily cloud-free enhanced vegetation index (EVI) time series is most accurate because daily cloudfree EVI time series can sufficiently reflect the vegetation growth trajectory
Considering the limited accuracy of SOS estimated by satellite-based EVI time series, we further used green chromatic coordinate (GCC) SOS derived from the PhenoCam Network photographs to validate the results of EVI SOS derived from different temporal resolutions, A
Summary
T HE start of season (SOS), named spring phenology, one of the most critical recurring growth phases of vegetation dynamics, has been documented as an effective indicator of regional environmental condition change Owing to large spatial coverage and multiyear consecutive observations, satellite data has been broadly adopted to measure SOS by using various satellite-derived vegetation index (VI) time series, such as normalized difference vegetation index (NDVI), enhanced vegetation index (EVI), enhanced vegetation index 2 (EVI2), and normalized difference phenology index (NDPI), to record the vegetation growth trajectory [10]–[13]
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