What will be the aerospace analysis and design tools of the future?
Brian Vermeire
- Assistant Professor
- Department of Mechanical, Industrial and Aerospace Engineering
- computational aerodynamics2
- future aircraft2
- computational fluid dynamics16
- turbulence8
- scientific computing2
- greener aviation4
- high-order methods
- heterogeneous computing
- implicit-explicit timestepping
- GPU computing2
- high performance computing5
- discontinuous Galerkin methods
- mesh adaption
- flows9
- aerodynamic design7
- aerodynamic optimization3
- aerospace59
- flux reconstruction
- aircraft design3
- atmospheric science
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Carole El Ayoubi
gas turbine engines, computational fluid dynamics, turbine design
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Wahid Ghaly
gas turbine engines, aerodynamic inverse shape design, computational fluid dynamics
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Susan Liscouët-Hanke
aircraft systems architecture, future aircraft, systems integration
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Mojtaba Kheiri
fluid-structure interactions, nonlinear aeroelasticity, kite power systems
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Marius Paraschivoiu
computational fluid dynamics, hydrogen technology, wind energy
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Ted Stathopoulos
building aerodynamics, wind engineering, buildings
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Ali Dolatabadi
surface engineering, thermal spray coatings, droplet transport
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Hany Gomaa
fluid mechanics, microfluidics, complex fluids
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Attila Michael Zsaki
geotechnical engineering, rock mechanics, soil mechanics
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Ali Akgunduz
aviation industry, air traffic control, greener aviation
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Catharine Marsden
aircraft structures, composites, aircraft design
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Hoi Dick Ng
thermofluids, combustion, renewable energy
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Pascale Biron
river dynamics, fish habitats, geomorphology
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Georgios H. Vatistas
human physiology, liquid sloshing, vortex dynamics
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Simone Brugiapaglia
data science, computational mathematics, compressed sensing
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Samuel Li
river dynamics, sediment transport, environmental hydraulics
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André G. Roy
fluvial geomorphology, river dynamics, climate change