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the industry to lead and/or conduct innovative research on, but not limited to evolutionary computing, job scheduling, transfer optimization, transfer learning, reinforcement learning, large-scale
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development, validation, and optimization of 3D-printed propellers. This includes conducting hydrodynamic analysis, finite element modeling, as well as overseeing site-based test bedding, data collection, and
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/or Typhoon HIL and conduct real time simulation studies/experimentation. Design and develop an intelligent and optimal energy management system (EMS) controller for the optimal operation and
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in the development, validation, and optimization of 3D-printed modular floating structures. This includes conducting hydrodynamic analysis, finite element modeling, and stability assessments, as
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optimization; bioprospecting for novel microbial hosts, enzymes, and metabolites to support sustainable biomanufacturing. (Bio)pharmaceuticals: Processing science and technology for bio- and chemical
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to analyze wave interaction with natural coastal ecosystems under varying conditions. • Optimize the model to predict shear coefficients, drag forces, and energy dissipation. 2. Experimental Calibration and
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structural integrity and stress distribution of modular floating units under operational and extreme conditions. • Optimize design configurations to enhance performance and durability. 3. Stability and Mooring
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behavior of floating breakwaters under varied sea conditions. 2. CFD and Finite Element Modeling • Perform Computational Fluid Dynamics (CFD) simulations to optimize the design and performance of floating
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this role, you will characterize mixtures of pharmaceutical excipients and drug materials to develop methodologies for screening hot-melt extrusion formulations and selecting optimal operating conditions
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. Carry out naval architecture calculations, i.e., stability, resistance, structural analysis, etc. iv. Carry out ship and system design optimization for electric ships. Coordinate procurement and liaison