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carries out technological research in the areas of optical component technology, optical instrumentation (spectro-radiometric imaging instruments in the visible and infrared, interferometry, optical
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. mechatronics, control theory, computer science, image processing) as well as a solid foundation in mathematics and physics is strongly desirable. Proficiency in the use of computer aided engineering tools is an
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of imaging detectors, optical communication and quantum communication. Depending on the your interests, technical competences and project constrains in 2026/27, you will support one or more of these
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and seismic imaging, theoretical computer science, and theoretical physics. We participate in university focus areas in Complex Systems and Applied Data Science. More information For more information
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, actuation, and control. The research includes the design, fabrication, and experimental validation of micro-scale robotic platforms, integration of optical and imaging-based feedback, and development
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these signals with their transcriptional programs. You will use a variety of techniques and tools, including microscopy and fluorescent imaging techniques, transcriptomics, metabolite profiling and high
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clock interrogation zones that are in one vacuum chamber. Clock interrogation can always be executed in at least one zone, while others are reloaded with atoms, enabling continuous operation. With
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robotic platforms, integration of optical and imaging-based feedback, and development of modeling and control strategies for operation in complex biological environments. Particular attention will be given
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and system analyses, to performance analysis, constellation mission analysis and simulations followed by experimentation with prototype elements in the navigation laboratory. We are looking
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predictions (priors), which are integrated with incoming sensory signals to form posterior beliefs that then update future predictions. In the context of movement, this process supports adaptive behaviour. In