Active Research Areas
- Quantum Neural Network Methods for Fluid Dynamics
- Artificial Intelligence (AI) in Fluid Dynamics
- Physics-Informed (Convolution) Neural Network Methods for Computational Fluid Dynamics
- Fluid-Structure Interaction (FSI) Modelling, Quasi-Newton based Coupling Techniques
- Fluid-Structure-Thermal Interaction Modelling
- Large scale LES and DNS Modelling
- Design Optimization based on coupled CFD and Structural Modelling
- LES Sub-Grid Scale Turbulence Modeling for Two Phase Flows
- Multi-scale and Multi-physics Modelling in Bio-flows
- Macro- and Microgravity Liquid Sloshing
- Cryogenic Hypersonic Tank Sloshing
- Coupled Sloshing and Vehicle Dynamics
- Blood Flow Modeling in a Viscoelastic Artery and Arterial Network of a Human
- Overset Mesh Dynamics for High and Low Re FSI Simulations
- Supra Left Ventricular Heart Blood Flow Coupled with Coronary Arteries,
- Hemodynamic characterization of Aort and Mitral valves
- Calsification and regurgitaion modelling in heart valves
- Growth and Remodeling of Soft Tissues
- Modelling Human Arterial Network
- Vessel Segmentation and Surface Reconstruction Techniques for Medical Images
- Simulation of Clot Cascading Process in Blood Flow
- Modeling of Deep Vein Thrombosis (DVT)
- Multi-Physics Modeling of Blood Rheology
- Multi-Phase Modeling of Blood Rheology
- Personalized Hemodynamic Heart Valve Modelling
- Animations of our Research Group located in YouTube
- Designing Scalable Algorithms for Large Scale Linear Set of Equations
- Scalable Linear Sparse Solvers for Many-core Distributed Systems
- Scalable Linear Sparse Solvers for Heterogenous Systems
- Nonlinear Algebra: Large Scale Nonlinear Equations
- Large Scale Unconstraint optimization
- Thrust Region (Levenberg-Marquardt) and Line Search Methods
- Quasi-Newton (Inexact Newton Methods)
- Barzilai & Borwein (BB) Like Methods
- BFGS like Quasi-Newton Methods
- Powel Symmetric Broyden (PSB) and Symmeric Rank one (SR1) Methods
- Hybrid Nonlinear Solvers
- Hybrid (Direct and Iterative) Sparse Linear Solvers
Parallel Computing Group
- Parallelization Approaches for Numerical Algorithms
- Communication Avoiding Algorithms
- Performance Measurement and Analysis of Parallel Algorithms
- Application Scaling on Extreme Large Scale Systems
- Resiliance and Fault Tolerancy of Applications on Large Scale Systems
- Scalability of Linear Solvers on GPGPU's
- Parallel Large Scale Scientific Visualization
Computing Grants
- HiSSor (Highly Scalable Linear Solver Project), This work was granted access to the HPC resources of Distributed European Computing Initiative by the PRACE-2IP, receiving funding from the European Community's Seventh Framework Program (FP7/2007-2013) under grant agreement n° RI-283493. 5 Milyon CPU Core Hours, Granting date Oct. 2012.
- Large Scale LES Simulation for Two-phase Flows Project, This work was granted access to the HPC resources of Distributed European Computing Initiative by the PRACE-2IP, receiving funding from the European Community's Seventh Framework Program (FP7/2007-2013) under grant agreement n° RI-283493. 150 Thousand CPU Core Hours, Granting date Oct. 2012.
Inactive Research Areas
Computational Fluid Dynamics
- Nonlinear Unsteady Ship Hydrodynamics
- Computational Free Surface Hydrodynamics
- Nonlinear Wave Body Interactions
- Numerical Wave Tank Simulation
- Floating Body Motions and Fluid-Structure Interactions