![]() The first application concerned groundwater inflow into a small stream in Luxembourg. The applications have been numerous, leading to many scientific publications in recent years (see below). For measurements of 30 seconds, an accuracy of 0.1 K can be obtained, improving to 0.02 K for measurements of 30 minutes. Accuracy will increase with the duration of the measurement. The length of the cable may go up to 10 km and temperature will be measured at each meter. DTS allows for precise measurement of temperature along a fiber optic cable. A beta version of the model can be found at . The video below presents the project.ĭistributed Temperature Sensing: An important focus of recent research concerns the application of Distributed Temperature sensing (DTS) to water management problems. Because the main computational bottle neck for this development is the memorry directly accessible by the CPU's, a special data assimilation algorithm has been developed in order to keep model development scalable. The model will be assimilated with measurements collected on the ground and by satellites. The final ambition is to run the model at a grid of 100m x 100m, with as first intermediary step a global grid of 10km x 10km. The model has been parallelised in order for it to be run very fast on a CPU cluster or a super computer. This model was developed in Utrecht and is called PCRGLOB-WB. The project is a cooperative effort by Utrecht University, the Netherlands eScience Center, and TU Delft. This idea won the 2015 Academic and Regional European Satellite Navigation Challenge. See: .ĮWaterCycle: This project will develop a high-resolution global hydrological model. A recent addition is the use of GPS (GNSS) receivers for measuring atmospheric water content. The first prototype disdrometer was developed in The Netherlands and tested in Tanzania for a total project cost of €5000. Within this project, we continue to build and test new sensors, such as an acoustic disdrometer (rain gauge) that can be produced for a fraction of the costs of a commercial equivalent with the same specifications. ![]() The data will be combined with models and satellite observations to obtain a very complete insight in the distribution of water and energy stocks and fluxes. The stations are placed at schools and integrated in the educational program. By applying innovative sensors and ICT, each station should be very cost efficient in installation, operation, and maintenance. The idea behind this project is to build a dense network of hydro-meteorological monitoring stations in sub-Saharan Africa one every 30 km. National governments and regional planners do not have the data to make proper decisions regarding investments in water resources infrastructure. Presently, the African observation network is very limited. Food production and harvest predictions would profit from improved understanding of water availability over space and time. Trans-African Hydro-Meteorological Observatory (TAHMO): Monitoring Africa's environment is an important challenge if the continent's resources are to be used in an optimal and sustainable manner. For a complete CV see CV_Nick_van_de_Giesen.pdf. At Wageningen University, he did his M.Sc. from Cornell University for his work on wetland development in Rwanda. From 1994 to 1998, he did Post-Doctoral research on the hydrology and management of inland valleys at WARDA, Cote d’Ivoire. Since 1 January 2015, he is chairman of the Delft Global Initiative.īefore coming to Delft University, he worked from 1998 to 2004, at the Center for Development Research of Bonn University, with as main activity the scientific coordination of the GLOWA Volta Project. Development of new observation techniques, both in situ and through satellites, as well as High Performance Computing, are the core themes of both research portfolio and teaching curriculum. His main interests are measuring and modeling of complex water resources systems and the development of science-based decision support systems. He teaches Integrated Water Resources Management (CIE4450) and Water Management (CTB2120). Since July 2004, Nick van de Giesen has held the Van Kuffeler Chair of Water Resources Management of the Faculty of Civil Engineering and Geosciences.
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