Soil moisture is a fundamental environmental variable essential for applications in agriculture, drought assessment, hydrological modeling, and climate research. In recent decades, numerous Soil Moisture Content (SMC) datasets have been produced from in-situ measurements, airborne and spaceborne observations, and model simulations. However, information about these datasets is fragmented across disparate repositories, publications, and portals, making data discovery, comparison, and integration a significant challenge for researchers. This study introduces the University of Bonn Soil Moisture Data Catalog (UB-SMDC), a unified, standards-compliant metadata portal designed to overcome this fragmentation. Two primary objectives drove the project: first, centralizing information on publicly available SMC datasets into a single, user-friendly, web-based interface; and second, conducting a comprehensive statistical analysis of SMC datasets to characterize the global SMC data landscape. The UB-SMDC was developed using a structured, three-phase methodology: (1) comprehensive data discovery, (2) catalog design and implementation, and (3) metadata creation and analysis. Built on the open-source GeoNetwork platform, the catalog aligns with the Geographic information, ISO19139 metadata standard, to ensure consistency and interoperability. To harmonize key attributes, a controlled keyword taxonomy was developed to standardize terms for spatial and temporal resolution, measurement depth, data format, processing level, and data version. Each metadata record is enriched with links to initial data sources and access, and includes map-based previews to visualize dataset coverage. By assessing 373 metadata records, the UB-SMDC streamlines the data discovery and selection process, supports transparent and reproducible research, and facilitates cross-dataset comparison and integration.

doi:10.1080/20964471.2026.2652079

@article{Mohseni13042026,
    abstract = {Soil moisture is a fundamental environmental variable essential for applications in agriculture, drought assessment, hydrological modeling, and climate research. In recent decades, numerous Soil Moisture Content (SMC) datasets have been produced from in-situ measurements, airborne and spaceborne observations, and model simulations. However, information about these datasets is fragmented across disparate repositories, publications, and portals, making data discovery, comparison, and integration a significant challenge for researchers. This study introduces the University of Bonn Soil Moisture Data Catalog (UB-SMDC), a unified, standards-compliant metadata portal designed to overcome this fragmentation. Two primary objectives drove the project: first, centralizing information on publicly available SMC datasets into a single, user-friendly, web-based interface; and second, conducting a comprehensive statistical analysis of SMC datasets to characterize the global SMC data landscape. The UB-SMDC was developed using a structured, three-phase methodology: (1) comprehensive data discovery, (2) catalog design and implementation, and (3) metadata creation and analysis. Built on the open-source GeoNetwork platform, the catalog aligns with the Geographic information, ISO19139 metadata standard, to ensure consistency and interoperability. To harmonize key attributes, a controlled keyword taxonomy was developed to standardize terms for spatial and temporal resolution, measurement depth, data format, processing level, and data version. Each metadata record is enriched with links to initial data sources and access, and includes map-based previews to visualize dataset coverage. By assessing 373 metadata records, the UB-SMDC streamlines the data discovery and selection process, supports transparent and reproducible research, and facilitates cross-dataset comparison and integration.},
    author = {Farzane Mohseni and Jan-Henrik Haunert},
    doi = {10.1080/20964471.2026.2652079},
    journal = {Big Earth Data},
    number = {0},
    pages = {1--33},
    publisher = {Taylor \& Francis},
    title = {Publicly available soil moisture datasets: an overview and the {UB-SMDC} portal},
    volume = {0},
    year = {2026}
}

Land Use/Land Cover (LULC) mapping plays a pivotal role in understanding the complex interplay between human activities and the natural environment. Here, we present a novel approach for fusing LULC information from two different data sources. Specifically, we aim to combine the advantages of LULC information extracted from remote-sensing imagery and of LULC information mapped by volunteers, especially LULC information from OpenStreetMap. Since OpenStreetMap is based on vector representations of objects and since we aim to generate a harmonized vector layer as output, our approach is to conduct the information fusion in a vector environment, using methods from computational geometry. Our method starts by vectorizing the remote sensing data, yielding a set of polygons. We then overlay the boundaries of these polygons with the boundaries of the LULC polygons from OpenStreetMap and refine the resulting planar subdivision using a Constrained Delaunay Triangulation (CDT). This triangulation is the starting point for the main step of our approach. In this step, for a land use type of interest, we generate the output polygons by computing an optimal selection of triangles from the CDT and resolving the boundaries between adjacent triangles in the selection. The novelty of our approach is that we optimize an objective function that combines five explicitly modeled criteria: (1, 2) adherence to the boundaries of the first/second input layer, (3, 4) adherence to the areas of the first/second input layer, and (5) generalizing the output polygons to a desired level of detail. We show how to efficiently solve our model using an approach based on graph cuts. Application of the methodology to forest land cover portions in North Rhine-Westphalia, Germany, reveals promising results, with outputs closely resembling reference data. With an average Intersection over Union (IoU) of 0.831 and a discrete Hausdorff distance (dH) of 1251.37m, across seven regions of interest, we demonstrate the effectiveness of our approach in accurately mapping LULC through dataset fusion in a vector framework, achieving optimal geometric harmonization.

doi:10.1080/17538947.2025.2562058

@article{Mohseni31122025,
    abstract = { Land Use/Land Cover (LULC) mapping plays a pivotal role in understanding the complex interplay between human activities and the natural environment. Here, we present a novel approach for fusing LULC information from two different data sources. Specifically, we aim to combine the advantages of LULC information extracted from remote-sensing imagery and of LULC information mapped by volunteers, especially LULC information from OpenStreetMap. Since OpenStreetMap is based on vector representations of objects and since we aim to generate a harmonized vector layer as output, our approach is to conduct the information fusion in a vector environment, using methods from computational geometry. Our method starts by vectorizing the remote sensing data, yielding a set of polygons. We then overlay the boundaries of these polygons with the boundaries of the LULC polygons from OpenStreetMap and refine the resulting planar subdivision using a Constrained Delaunay Triangulation (CDT). This triangulation is the starting point for the main step of our approach. In this step, for a land use type of interest, we generate the output polygons by computing an optimal selection of triangles from the CDT and resolving the boundaries between adjacent triangles in the selection. The novelty of our approach is that we optimize an objective function that combines five explicitly modeled criteria: (1, 2) adherence to the boundaries of the first/second input layer, (3, 4) adherence to the areas of the first/second input layer, and (5) generalizing the output polygons to a desired level of detail. We show how to efficiently solve our model using an approach based on graph cuts. Application of the methodology to forest land cover portions in North Rhine-Westphalia, Germany, reveals promising results, with outputs closely resembling reference data. With an average Intersection over Union (IoU) of 0.831 and a discrete Hausdorff distance (dH) of 1251.37m, across seven regions of interest, we demonstrate the effectiveness of our approach in accurately mapping LULC through dataset fusion in a vector framework, achieving optimal geometric harmonization. },
    author = {Mohseni, Farzane and Rottmann, Peter and Haunert, Jan-Henrik},
    doi = {10.1080/17538947.2025.2562058},
    journal = {International Journal of Digital Earth},
    number = {2},
    pages = {2562058},
    publisher = {Taylor \& Francis},
    title = {A multi-criteria optimization approach for the geometric integration of vector-based land cover datasets},
    volume = {18},
    year = {2025}
}

doi:10.1080/20964471.2023.2257905

@article{Mohseni2023,
    author = {Mohseni, Farzane and Ahrari, AmirHossein and Haunert, Jan-Henrik and Montzka, Carsten},
    doi = {10.1080/20964471.2023.2257905},
    journal = {Big Earth Data},
    number = {1},
    pages = {33-57},
    title = {The synergies of SMAP enhanced and MODIS products in a random forest regression for estimating 1 km soil moisture over Africa using Google Earth Engine},
    volume = {8},
    year = {2024}
}

doi:10.3390/rs15143495

@article{Mohseni2023,
    author = {Mohseni, Farzane and Amani, Meisam and Mohammadpour, Pegah and Kakooei, Mohammad and Jin, Shuanggen and Moghimi, Armin},
    doi = {10.3390/rs15143495},
    journal = {Remote Sensing},
    number = {14},
    pages = {3495},
    title = {Wetland Mapping in Great Lakes Using Sentinel-1/2 Time-Series Imagery and DEM Data in Google Earth Engine},
    volume = {15},
    year = {2023}
}