An evaluation of time dependent numerical methods applied to a rapidly converging nozzle

Giles, Garland Eldridge

05 1900

No description available.

Difference equations Numerical solutions

Nozzles

Design, construction and analysis of a chaotic vibratory system

Brown, Andrew M.

12 1900

No description available.

Nonlinear equations

Materials Dynamic testing

The interlacing construction for stochastic flows of diffeomorphisms

Tang, Fuchang

January 1999

No description available.

510

Stochastic differential equations; SDE's

Temporal and spatial host-pathogen models with diverse types of transmission

Turner, Joanne

January 2000

No description available.

519.5

Differential equations; Data analysis

Modulational instability of optical solitary waves

Skryabin, Dmitry Vladimirovich

January 2000

No description available.

530.1

Wave mechanics; Equations; Solitons

Numerical simulation of 2D flow past a dimpled cylinder using a pseudospectral method

Kotovshchikova, Marina

08 January 2007

A numerical simulation of steady and unsteady two-dimensional flows past cylinder with dimples based on highly accurate pseudospectral method is the subject of the present thesis. The vorticity-streamfunction formulation of two-dimensional incompressible Navier-Stokes equations with no-slip boundary conditions is used. The system is formulated on a unit disk using curvilinear body fitted coordinate system. Key issues of the curvilinear coordinate transformation are discussed, to show its importance in properly defined node distribution. For the space discretization of the governing system the Fourier-Chebyshev pseudospectral approximation on a unit disk is implemented. To handle the singularity at the pole of the unit disk the approach of defining the computational grid proposed by Fornberg was implemented. Two algorithms for solving steady and unsteady problems are presented. For steady flow simulations the non-linear time-independent Navier-Stokes problem is solved using the Newton's method. For the time-dependent problem the semi-implicit third order Adams-Bashforth/Backward Differentiation scheme is used. In both algorithms the fully coupled system with two no-slip boundary conditions is solved. Finally numerical result for both steady and unsteady solvers are presented. A comparison of results for the smooth cylinder with those from other authors shows good agreement. Spectral accuracy is demonstrated using the steady solver.

pseudospectral method

Navier-Stokes equations

A class of Petrov-Galerkin finite element methods for the numerical solution of the stationary convection-diffusion equation

Perella, Andrew James

January 1996

A class of Petrov-Galerkin finite element methods is proposed for the numerical solution of the n dimensional stationary convection-diffusion equation. After an initial review of the literature we describe this class of methods and present both asymptotic and nonasymptotic error analyses. Links are made with the classical Galerkin finite element method and the cell vertex finite volume method. We then present numerical results obtained for a selection of these methods applied to some standard test problems. We also describe extensions of these methods which enable us to solve accurately for derivative values of the solution.

519

Pattern formation in nonlinear optics

McIntyre, Ross

January 1996

No description available.

530.1

Modelling random wave boundary layers

Harris, John M.

January 1997

No description available.

629.1323

Numerical simulation of 2D flow past a dimpled cylinder using a pseudospectral method

Kotovshchikova, Marina

08 January 2007

A numerical simulation of steady and unsteady two-dimensional flows past cylinder with dimples based on highly accurate pseudospectral method is the subject of the present thesis. The vorticity-streamfunction formulation of two-dimensional incompressible Navier-Stokes equations with no-slip boundary conditions is used. The system is formulated on a unit disk using curvilinear body fitted coordinate system. Key issues of the curvilinear coordinate transformation are discussed, to show its importance in properly defined node distribution. For the space discretization of the governing system the Fourier-Chebyshev pseudospectral approximation on a unit disk is implemented. To handle the singularity at the pole of the unit disk the approach of defining the computational grid proposed by Fornberg was implemented. Two algorithms for solving steady and unsteady problems are presented. For steady flow simulations the non-linear time-independent Navier-Stokes problem is solved using the Newton's method. For the time-dependent problem the semi-implicit third order Adams-Bashforth/Backward Differentiation scheme is used. In both algorithms the fully coupled system with two no-slip boundary conditions is solved. Finally numerical result for both steady and unsteady solvers are presented. A comparison of results for the smooth cylinder with those from other authors shows good agreement. Spectral accuracy is demonstrated using the steady solver.

pseudospectral method

Navier-Stokes equations