Abstract
In recent years, many spatial and temporal satellite image fusion (STIF) methods have been developed to solve the problems of trade-off between spatial and temporal resolution of satellite sensors. This study, for the first time, conducted both scene-level and local-level comparison of five state-of-art STIF methods from four categories over landscapes with various spatial heterogeneity and temporal variation. The five STIF methods include the spatial and temporal adaptive reflectance fusion model (STARFM) and Fit-FC model from the weight function-based category, an unmixing-based data fusion (UBDF) method from the unmixing-based category, the one-pair learning method from the learning-based category, and the Flexible Spatiotemporal DAta Fusion (FSDAF) method from hybrid category. The relationship between the performances of the STIF methods and scene-level and local-level landscape heterogeneity index (LHI) and temporal variation index (TVI) were analyzed. Our results showed that (1) the FSDAF model was most robust regardless of variations in LHI and TVI at both scene level and local level, while it was less computationally efficient than the other models except for one-pair learning; (2) Fit-FC had the highest computing efficiency. It was accurate in predicting reflectance but less accurate than FSDAF and one-pair learning in capturing image structures; (3) One-pair learning had advantages in prediction of large-area land cover change with the capability of preserving image structures. However, it was the least computational efficient model; (4) STARFM was good at predicting phenological change, while it was not suitable for applications of land cover type change; (5) UBDF is not recommended for cases with strong temporal changes or abrupt changes. These findings could provide guidelines for users to select appropriate STIF method for their own applications.
Highlights
High spatial resolution images with a short revisit cycle are of great significance for various remote sensing applications such as vegetation phenology monitoring [1], forest disturbance mapping [2], and land surface temperature monitoring [3]
We found that one-pair learning and spatial and temporal adaptive reflectance fusion model (STARFM) performed similar, and better than the unmixing-based data fusion (UBDF) model
We further found that Fit-FC is not suitable for landscapes/regions with low temporal variation index (TVI) and high landscape heterogeneity index (LHI), and its performance in terms of retaining the image structure was not as good as Flexible Spatiotemporal DAta Fusion (FSDAF), one-pair learning, or even STARFM
Summary
High spatial resolution (hereafter referred to as “high-resolution”) images with a short revisit cycle are of great significance for various remote sensing applications such as vegetation phenology monitoring [1], forest disturbance mapping [2], and land surface temperature monitoring [3]. Typical examples include Landsat Thematic Mapper (TM), Enhanced TM plus (ETM+), Operational Land Imager (OLI) imagery with a 30 m spatial resolution but a 16-day revisit cycle, and MODerate-resolution Imaging Spectroradiometer (MODIS) imagery with a sub-day revisit cycle but 250/500/1000 m spatial resolutions. To overcome this constraint, many spatial and temporal satellite image fusion (STIF) approaches have been developed [4]. The synthetic imagery allows construction of high-quality high-frequency time series data, which promotes the applications of remote sensing in identifying high-frequency change in heterogeneous landscapes
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