Abstract
Spatio-temporal data fusion refers to the technique of combining high temporal resolution from coarse satellite images and high spatial resolution from fine satellite images. However, data availability remains a major limitation in algorithm development. Existing spatio-temporal data fusion algorithms require at least one known image pair between the fine and coarse resolution image. However, data which come from two different satellite platforms do not necessarily have an overlap in their overpass times, hence restricting the application of spatio-temporal data fusion. In this paper, a new algorithm named Hopfield Neural Network SPatio-tempOral daTa fusion model (HNN-SPOT) is developed by utilizing the optimization concept in the Hopfield neural network (HNN) for spatio-temporal image fusion. The algorithm derives a synthesized fine resolution image from a coarse spatial resolution satellite image (similar to downscaling), with the use of one fine resolution image taken on an arbitrary date and one coarse image taken on a predicted date. The HNN-SPOT particularly addresses the problem when the fine resolution and coarse resolution images are acquired from different satellite overpass times over the same geographic extent. Both simulated datasets and real datasets over Hong Kong and Australia have been used in the evaluation of HNN-SPOT. Results showed that HNN-SPOT was comparable with an existing fusion algorithm, the spatial and temporal adaptive reflectance fusion model (STARFM). HNN-SPOT assumes consistent spatial structure for the target area between the date of data acquisition and the prediction date. Therefore, it is more applicable to geographical areas with little or no land cover change. It is shown that HNN-SPOT can produce accurate fusion results with >90% of correlation coefficient over consistent land covers. For areas that have undergone land cover changes, HNN-SPOT can still produce a prediction about the outlines and the tone of the features, if they are large enough to be recorded in the coarse resolution image at the prediction date. HNN-SPOT provides a relatively new approach in spatio-temporal data fusion, and further improvements can be made by modifying or adding new goals and constraints in its HNN architecture. Owing to its lower demand for data prerequisites, HNN-SPOT is expected to increase the applicability of fine-scale applications in remote sensing, such as environmental modeling and monitoring.
Highlights
Satellite remote sensing for monitoring the geophysical environment has developed rapidly in recent decades
Possible reasons for the compatible fusion result by Hopfield neural network (HNN)-SPOT compared to spatial and temporal adaptive reflectance fusion model (STARFM) can be due to (1) the similar assumption of the sampling theory between the fine and coarse pixels, and (2) the same usage of moving window in the algorithm, different mechanisms are applied in the two models
This paper presents a newly developed spatio-temporal data fusion algorithm, HNN-SPOT, which utilizes the optimization property in the HNN algorithm to assist data fusion
Summary
Satellite remote sensing for monitoring the geophysical environment has developed rapidly in recent decades. Earth observation is often constrained by the spatial and temporal resolutions of the satellite images. With the integration of high spatial resolution and high temporal resolution, information provided by different satellites can be better utilized, especially for applications requiring both frequent coverage and high spatial details, such as diurnal reflectance analysis and 24-hour temperature monitoring [13]. These applications can help in environmental modeling and monitoring, and can further assist in making decisions about urban planning [2]
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