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Computer Vision, Deep learning, point cloud |
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5G enabling technologies, intelligent reflecting surfaces, microelectronics, Optical communications, Signal processing, Terahertz communications, Ultra-massive MIMO systems, wireless communication |
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3D printing, 4D printing, Biosensors, flexible electronics |
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coding techniques for Terahertz, communication engineering, Data detection and decoding, Massive MIMO Systems, MATLAB, Python, Signal processing, wireless communication |
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ROV, Towed Vehicles, Underwater Vehicles |
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flexible electronics, Laser-scribed graphene, wearable sensors |
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data analysis, finite element method, HPC, Python, uncertainty quantification |
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Cognitive radio network, Cooperative relay network |
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electronics, inkjet printing technologies, nanomaterials, photodetector devices, photovoltaics, semiconductors interfaces, solar cells |
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machine learning, Terahertz communications |
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compliant electronics, Implantable devices |
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Next generation cellular networks, Wireless Communications |
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artificial intelligence, big data, cloud services |
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control systems, intelligent systems, machine learning, robotics |
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control systems, intelligent systems, RISC, robotics |
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analog/mixed signals design-to-tapeout, human body communication, intenet of bodies, low power transceivers |
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Green communications, Visible light communications |
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Coding theory, Free-space optical communications, Information theory, Relay networks |
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bioelectronics, energy efficiency, IoT, power electronics, Sensing |
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Andrea Fratalocchi, Professor, Electrical and Computer Engineering
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energy harvesting, imaging apparatus, intelligent lasers, photonics |
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computational statistics, machine learning, Statistical Modeling, stochastic processes |
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microwave biosensor, microwave resonator |
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Action understanding, AI4Science, Continual Learning, Multimodal learning, Visual Language Models |
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intelligent systems, robotics |
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Wireless power transfer |
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Control Theory, Estimation |
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Reinforcement Learning, Stochastic Geometry, wireless network |
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Electron Transport, microelectronics |
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control, Mobile robotics, robotics, Robotics manipulators |
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intelligent systems, robotics |
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nanowires, OLEDs |
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Unit commitment, Renewable integration, Quantum computing for power systems, Stochastic AC Optimal Power Flow, Grid-forming & grid-following inverters, HVDC design, Machine learning for power systems |
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biosensing, microwaves, receiver architecture, RF, RF devices, Sensing |
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integrated photonics, Nonlinear Optics, Quantum nanomaterials, ultrafast fiber lasers |
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machine learning, Mechanical Engineering, robotics |
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Ultra-wide band Fractal Antennas |
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Control Theory, Controller design, Fractional calculus, inverse problems |
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Controller design, Free Space Optics, modeling, Signal processing |
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5G and beyond, artificial intelligence, cellular and sensor networks, Deep learning, Digital signal processing, Machine learning applications for wireless communication systems, Resource allocation, UAV-Assisted |
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fabrication of a serpentine, silicon-based reconfigurable electronic platform |
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Atif Shamim, Program Chair, Electrical and Computer Engineering
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additive manufacturing, Antennas, Microwave circuits, sensors |
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machine learning, reconfigurable computing |
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Compressive Sensing, high dimensional statistics, mathematical optimization, statistical learning, statistical signal processing, Wireless Communications |
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AI, Computer Vision, Deep learning, Reinforcement Learning |
