Data fusion
Mapping small features (e.g., hedges, streams, urban vegetation) requires higher spatial resolution than the 10m offered natively by Sentinel-2, as well as regular revisits which commercial VHR satellites cannot offer at a global scale. Boosted by deep Convolutional Neural Network (CNN) architectures and Generative Adversarial Networks (GAN), Single Image Super Resolution (SIRS) has recently been proven as very promising in the context of EO. Deep SIRS has the advantage of concentrating processing power and data consumption in the training phase but is resource-friendly when applied during inference. On the other hand, it requires a large training dataset with imagery at the target high resolution and it cannot solve cloudy images.
In the frame of EvoLand we will therefore develop a multi-modal generic architecture for the fusion of time series building further on the existing work by consortium partners and the outcomes of method no 1, Weakly Supervised Learning.
Discover prototypes that use data fusion
C5 – Cropland/grassland GPP monitoring
Rolling out high-resolution GPP data (10-daily, 10m) for grassland and cropland, currently non-existing over Europe.
C6 – Small landscape features mapping
Improving accuracy and efficiency through novel data to support Small Landscape Features (SLF) products.
C7 – Improved water bodies mapping
Finer resolution for water bodies and water networks by means of novel EO-data and super resolution.
C8 – Continuous imperviousness monitoring
Constant monitoring of artificially sealed areas including the level of sealing of the soil per area unit.
C9 – Automated land use mapping of urban dynamics
Combining Machine Learning (ML) with optical Earth Observation (EO) data to automatically detect and characterize urban changes.
C10 – Continuous mapping of land surface categories
Developing continuous mapping of land surface categories at 10m resolution based on Sentinel 1 & 2 data.
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