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The Austrian Cluster for GMES (Global Monitoring of Environment and Security) combines the forces of industry, applied research, university institutes and user organisations to develop sustainable Earth Observation (EO) based services in the settlement and alpine environment context.
The main purpose of the ACAP project was to compute a global gravity field based on precise orbit information using the so-called acceleration approach. This method is based on Newton's second law of gravitation, which states that the acceleration of a mass is related to the forces acting on it.
ACCU-Clouds - Preparing a Key Dimension of ACCURATE Climate Utility: Cloud sensing and Greenhouse Gas Profiling in Cloudy Air
Overall ACCU-Clouds represents a crucial milestone on the way towards realizing an ACCURATE mission for the benefit of monitoring the changing atmospheric composition and climate in the 21st century.
ACCURAID - Aid to ACCURATE Climate Satellite Mission Preparations for Backing the Austrian Leading Role
ACCURATE (Atmospheric Climate and Chemistry in the UTLS Region And climate Trends Explorer) is a next generation climate mission concept.
The AIM4X project exploits the innovative capabilities of recent high-resolution SAR and radar altimeter missions.
ALS-X - Combination and Evaluation of Airborne Laser Scanning Data and TerraSAR-X Data for Glacier and Snow Monitoring
The project aims at analysing and evaluating time synchronous airborne laser scanning data and Terra SAR-X satellite data under glaciological and snow hydrological aspects.
AQA-PM - Extension of the Air-Quality Model for Austria With Satellite Based Particulate Matter Estimates
AQA issues daily forecasts of gaseous and particulate (PM10) air pollutants over Austria. The goal of this project was to improve the PM10 forecasts for Austria by integrating satellite based measurements and to provide a comprehensive product platform.
The ASaG project is aimed at the implementation of a satellite-based service for spatially detailed monitoring of snow cover and glaciers over extended areas.
The project AT-X was concerned with the development of methods for the operational and scientific utilization of data from TerraSAR-X and other very high resolution spaceborne X- band SAR sensors. It addresses the applications snow and glacier monitoring for water management and climate monitoring and the retrieval of forest parameters.
CASIMO2 is a seamless enhancement of the carrier monitoring system based on and driven by customer requirements concerning the implementation of DSP based polarization discrimination measurements combined with enhanced demodulation functionality and satellite performance measurements.
The aim of this project was to raise the Technology Readiness Level (TRL) of a new type of scalar magnetometer called Coupled Dark State Magnetometer (CDSM). Advantages of the CDSM are the uncomplicated sensor design, the high dynamic range of more than 6 decades and the omni-directional measurement capability without additional design complexity.
In the frame of this project a feasibility study of a new type of scalar magnetometer called Coupled Dark State Magnetometer (CDSM) was carried out. It included the investigation of its technical readiness and scientific merit for space applications, the concept for a TRL 5 (component and/or breadboard validation in relevant environment) compliant design, a detailed investigation of key components as well as the identification of possible challenges for a reliable operation in space.
The overall aim of CHAMPCLIM is to exploit research satellite CHAMPsradio occultation data in the best possible manner for their most challenging application, which is climate monitoring.
The clue idea of COALA.NT is to stronger involve the engine driver in the decisions of the operational traffic management. COALA.NT is a bi-directional, detection-based, innovative information system for operators and enginedrivers on railroad lines with small traffic volume.
CoReH2O will deliver detailed spatial data on key parameters of the global snow and ice masses for applications in climate research and hydrology.
ARC Seibersdorf research GmbH was selected to develop and produce ion emitters for the experiment COSIMA (CometarySecondary Ion Mass Analyser). Scope of this experiment is to analyse cometary matter e. g. to find out what molecules existed shortly after the "big bang". There may be molecules, composed of hydrogen, carbon and oxygen, which might build blocks of amino acids, the basic molecules of life.