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Are you interested in developing AI methods that can make physics simulations orders of magnitude faster? If the answer is yes, please continue reading! Join our team! The University of Amsterdam (UvA) is
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Challenge: Understanding how micromobility affects pedestrian stress and comfort Change: Leveraging XR simulations to explore real-world pedestrian interactions. Impact: Guiding urban policy toward
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mathematics, for example mapping out disease processes using single cell data, and using mathematics to simulate gigantic ash plumes after a volcanic eruption. In other words: there is plenty of room
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postdoc, your research will be aimed at further developing ultrafast photoacoustics for overlay metrology. You will perform simulations and experiments to explore the feasibility of the approach on basic
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develops and analyses behavioural experiments (reaction times, eye fixations) and EEG data. The computational strand simulates behavioural and neural data related to processing and memory retrieval. As a
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adaptation to new EO tasks such as disaster response, biodiversity monitoring or land-use change detection; support generative EO applications such as synthetic data creation, gap-filling, and simulation
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technologies—and eager to accelerate their discovery with machine learning and materials theory? Are you passionate about linking atomistic processes to device performance through computer simulations? Are you
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seasonal surveys, develop hydrological models to simulate the system's hydrological and geomorphic behavior, and engage with stakeholders to identify opportunities for system improvement. Floodplain System
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mathematics, for example mapping out disease processes using single cell data, and using mathematics to simulate gigantic ash plumes after a volcanic eruption. In other words: there is plenty of room
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, focused on surrogate modeling. The goal of SmartEM is to develop surrogate models, or systems of surrogates, for complex industrial systems or their high-fidelity simulations. The European project will