Final Projects
Spring 2017
Name Project Title
Abhinav Gupta Implementation of the Ghost Cell Immersed Boundary Method in the 2.29 FV Framework
Abiodun Timothy Olaoye Investigation of Fluid Structure Interactions Using the Fourier Spectral Element Method
Yukino Nagai Turbulence Modeling Using the 2.29 Finite Volume Framework
Andrew Joseph Rzeznik Comparison of Turbulence Models for Buoyant Jets in Stratified Environments
Fredrik Samdal Solberg Time-Optimal Path Planning for Sailboats Under the Effect of Strong Winds and Waves
Mohamed Aziz Bhouri Improving Accuracy of Internal Combustion Engines Ring Design Tool Using Richardson Extrapolation and Deferred-Correction Approaches
Orion Thomas Taylor Solitary Wave Solutions to a 2D Lattice
Samuel James Raymond Particle methods for fluid/solid mechanics
Wael Hajj Ali A Finite Volume Model for The Variable-density Parabolic Equation in Ocean Acoustics: Derivation, Implementation and Validation
Yiou Wang Positive Definite and Monotonic Limiters for Unrestricted Time Step Transport Schemes
Zeyu Zhang Replacement of the LU Decomposition by Newton-Raphson Iterations in the 2.29 Finite Volume Framework


Implementation of the Ghost Cell Immersed Boundary Method in the 2.29 FV Framework


by Abhinav Gupta

The goal of this project is to replace the current implementation of boundary condition treatment in the 2.29 FV Framework by staircase approximation with Ghost-Cell Immersed Boundary Method. Currently it is only implemented for the tracer field.




Investigation of Fluid Structure Interactions Using the Fourier Spectral Element Method


by Abiodun Timothy Olaoye




ATurbulence Modeling Using the 2.29 Finite Volume Framework


by Yukino Nagai




Time-Optimal Path Planning for Sailboats Under the Effect of Strong Winds and Waves


by Fredrik Samdal Solberg




Improving Accuracy of Internal Combustion Engines Ring Design Tool Using Richardson Extrapolation and Deferred-Correction Approaches


by Mohamed Aziz Bhouri




Particle methods for fluid/solid mechanics


by Samuel James Raymond




A Finite Volume Model for The Variable-density Parabolic Equation in Ocean Acoustics: Derivation, Implementation and Validation


by Wael Hajj Ali