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the same time, we are developing the chips and sensors of the future, whilst also setting the foundations for the software technologies to run on this new generation of equipment – which of course includes
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of the simulation environment and models, and preliminary control methodology. Development of a high-fidelity simulation environment capturing the relevant dynamics, DFAOCS sensors and actuators and including all
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explore new ways to build sensors, such as superradiant clocks and collaborate with industry, startups and users to bring quantum technology to the market . This project is embedded in the Quantum Delta NL
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sustainable and future-proof. At the same time, we are developing the chips and sensors of the future, whilst also setting the foundations for the software technologies to run on this new generation
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– Integrating Behaviour, Health and Biodiversity in Animal Science”. The ‘Digital Biology’ programme focuses on developing and applying digital technologies (AI, sensors, modelling, data fusion) to better
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our daily lives. Technology such as the electricity grid, which our faculty is helping to make completely sustainable and future-proof. At the same time, we are developing the chips and sensors
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Sr gases for quantum sensing, the study of many-body physics and for quantum computing. We explore new ways to build sensors, such as superradiant clocks and collaborate with industry, startups and
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model scenarios, and data which can be used to test the developed models. Measurements will include, for example, water content, and pressure head with local in-situ sensors. In addition we aim to carry
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knowledge—collected from survey data, narrative accounts, and participatory insights to sensor measurements and high-resolution geospatial data—is an essential prerequisite for studying these complex
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invariant theory. Others are working on problems of localization and mapping from sensor data (e.g., GPS) using techniques from distance geometry and billiards. Ideally, the candidate would complement