Abstract
Landsat is a fundamental data source for understanding historical change and its effect on environmental processes. In this research we test shallow and deep convolution neural networks (CNNs) for Landsat image super-resolution enhancement, trained using Sentinel-2, in three study sites representing boreal forest, tundra, and cropland/woodland environments. The analysis sought to assess baseline performance and determine the capacity for spatial and temporal extension of the trained CNNs. This is not a data fusion approach and a high-resolution image is only needed to train the CNN. Results show improvement with the deeper network generally achieving better results. For spatial and temporal extension, the deep CNN performed the same or better than the shallow CNN, but at greater computational cost. Results for temporal extension were influenced by change potentiality reducing the performance difference between the shallow and deep CNN. Visual examination revealed sharper images regarding land cover boundaries, linear features, and within-cover textures. The results suggest that spatial enhancement of the Landsat archive is feasible, with optimal performance where CNNs can be trained and applied within the same spatial domain. Future research will assess the enhancement on time series and associated land cover applications.
Highlights
High spatial and temporal resolution earth observation (EO) images are desirable for many remote sensing applications, providing a finer depiction of spatial boundaries or timing of environmental change
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In this research we show that convolution neural networks (CNNs) super-resolution can spatially enhance Landsat imagery and can be applied to historical peak growing season time series that could improve land cover and land cover change applications or possibly biophysical parameter retrievals
Summary
High spatial and temporal resolution earth observation (EO) images are desirable for many remote sensing applications, providing a finer depiction of spatial boundaries or timing of environmental change. Landsat provides the longest record of moderate spatial resolution (30 m) data of the earth from 1984 to present. Temporal enhancement is a key requirement, but spatial enhancement is another aspect of Landsat that could be improved for time series applications. Studies have shown that data fusion can lead to improvements in quantitative remote sensing applications such as land cover [4,8,9]. For a consistent Landsat time series from 1985 to present, a method that will provide the same level of enhancement across sensors is needed. For Landsat-5, a suitable high-resolution source is generally inadequate in space or time to facilitate generation of an extensive spatially enhanced Landsat archive
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