In early June 2013, widespread flooding in central Europe has inundated swathes of Austria, Germany, Slovakia and the Czech Republic, killing at least 15 people.

Pre-Flood Soil Moisture:

ESA's SMOS satellite captured the extremely high soil moisture levels monitored previous to the floods on 31 May and 2 June 2013.

Several providers have acquired and processed up to date satellite-derived maps of the affected areas:

Austria

On 10 January 2013 the International Charter "Space and Major Disasters" was activated for floods in the Middle East to provide satellite imagery and derived maps. UN-SPIDER/UNOOSA requested the activation on behalf of UNOCHA, Pt Jerusalem Office. The National Space Organization (NSPO) already provided a Formosat2 image taken on 12 January 2013 over Palestine. The Imagery was processed by the FCU (Feng Chia University) GIS team.

After heavy rains, a deadly snow storm had hit parts of Israel, Palestine and Jordan causing power outages, structural and agricultural damage and loss of human lives. Since Thursday, 10 January, at least 4inches (10cm) of snow have fallen in Jordan. Thousands of people are living in refugee camps due to freezing weather conditions.

Reportedly, two fatalities occurred in Lebanon during a flash flood. At least 46 people have been injured in road accidents across Jordan. Several roads and schools have also been closed. Rescue efforts are...

Between September 17th and 19th 2010 heavy rains captured the area of Slovenia. A big part of the area of Slovenia was flooded. In the activation of the International Charter Space and Major Disasters the series of radar images was achieved. The paper presents the study of flood dynamics in the surroundings of the capital Ljubljana. Radar images enabled satisfactory near-real-time comprehension of flood dynamics, however not in urban areas. There were also some problems with high-grown plants (trees, crops). In these areas combinations with other data are going to be studied. Especially optical satellite images and digital elevation model (DEM) with its derivates (heights, slope, shadows) can improve the detection of floods in these parts of these areas. The short paper presents the results of flood detection produced by radar images. It also discusses the deficiencies of radar images for small water area detection. These deficiencies might be eliminated using...

This paper illustrates some applications of COSMOSkyMed (CSK) observations for rapid mapping of flooded areas and damages in small to medium size catchments. The results presented here have been obtained within the framework of the project “OPERA – Civil protection from floods” funded by the Italian Space Agency and run by a team of scientific research centres and private companies. The project aims to the systematic evaluation of the added value of the use of Earth Observation techniques into operational flood prediction chains. Due to the specific geomorphology of Italy, the focus is mainly on flash floods on small sized river catchments. Monitoring and modelling processes at proper space-time scales in this environment raise several issues to be solved, compared to applications in larger river basins. Here we address some related to the suitable use of CSK imagery.

The overall goal of this study is to strengthen the quality, accuracy, and completeness of disaster data in Europe. As part of the MICRODIS project, the study analyses the impact of recent disasters on human populations, using both statistical and spatial data through generated geocoded maps of impact areas. It is intended to serve as a preliminary and descriptive investigation to reveal certain possibilities and serve as the basis for further research.

The importance of sea-level rise in shaping coastal landscapes is well recognized within the earth science community, but as with many natural hazards, communicating the risks associated with sea-level rise remains a challenge. Topography is a key parameter that influences many of the processes involved in coastal change, and thus, up-to-date, high-resolution, high-accuracy elevation data are required to model the coastal environment. Maps of areas subject to potential inundation have great utility to planners and managers concerned with the effects of sea-level rise. However, most of the maps produced to date are simplistic representations derived from older, coarse elevation data. In the last several years, vast amounts of high quality elevation data derived from lidar have become available. Because of their high vertical accuracy and spatial resolution, these lidar data are an excellent source of up-to-date information from which to improve identification and...