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A graphical preprocessing interface for non-conforming spectral element solversKim, Bo Hung 02 June 2009 (has links)
A graphical preprocessor for Spectral Element Method (SEM) is developed with an
emphasis on user friendly graphical interface and instructive element construction. The
interface of the preprocessor helps users with every step during mesh generation, aiding
their understanding of SEM. This preprocessor's Graphical User Interface (GUI) and
help system are comparable to other commercial tools. Moreover, this preprocessor is
designed for educational purposes, and prior knowledge of Spectral Element formulation
is not required to use this tool. The information window in the preprocessor shows stepby-
step instructions for the user. The preprocessor provides a graphical interface which
enables visualization while the mesh is being constructed, so that the entire domain can
be discretized easily. In addition, by following informative steps during the mesh
construction, the user can gain knowledge about the intricate details of computational
fluid dynamics.
This preprocessor provides a convenient way to implement h/p type nonconforming
interfaces between elements. This aids the user in learning advanced numerical
discretization techniques, such as the h/p nonconforming SEM. Using the preprocessor facilitates enhanced understanding of SEM, isoparametric mapping, h and p type
nonconforming interfaces, and spectral convergence. For advanced users, this
preprocessor provides a proficient and convenient graphical interface independent of the
solvers. Any spectral element solver can utilize this preprocessor, by reading the format
of the output file from the preprocessor. Given these features, this preprocessor is useful
both for novice and advanced users.
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Spectral Element Method Simulation of Linear and Nonlinear Electromagnetic Field in Semiconductor NanostructuresLuo, Ma January 2013 (has links)
<p>In this dissertation, the spectral element method is developed to simulate electromagnetic field in nano-structure consisting of dielectric, metal or semiconductor. The spectral element method is a special kind of high order finite element method, which has spectral accuracy. When the order of the basis function increases, the accuracy increases exponentially. The goal of this dissertation is to implement the spectral element method to calculate the electromagnetic properties of various semiconductor nano-structures, including photonic crystal, photonic crystal slab, finite size photonic crystal block, nano dielectric sphere. The linear electromagnetic characteristics, such as band structure and scattering properties, can be calculated by this method with high accuracy. In addition, I have explored the application of the spectral element method in nonlinear and quantum optics. The effort will focus on second harmonic generation and quantum dot nonlinear dynamics. </p><p>The electromagnetic field can be simulated in both frequency domain and time domain. Each method has different application for research and engineering. In this dissertation, the first half of the dissertation discusses the frequency domain solver, and the second half of the dissertation discusses the time domain solver.</p><p>For frequency domain simulation, the basic equation is the second order vector Helmholtz equation of the electric field. This method is implemented to calculate the band structure of photonic crystals consisting of dielectric material as well as metallic materials. Because the photonic crystal is periodic, only one unit cell need to be simulated in the computational domain, and a periodic boundary condition is applied. The spectral accuracy is inspected. Adding the radiation boundary condition at top and bottom of the computational region, the scattering properties of photonic crystal slab can be calculated. For multiple layers photonic crystal slab, the block-Thomas algorithm is used to increase the efficiency of the calculation. When the simulated photonic crystals are finite size, unlike an infinitely periodic system, the periodic boundary condition does not apply. In order to increase the efficiency of the simulation, the domain decomposition method is implemented. </p><p>The second harmonic generation, which is a kind of nonlinear optical effect, is simulated by the spectral element method. The vector Helmholtz equations of multiple frequencies are solved in parallel and the consistence solution with nonlinear effect is obtained by iterative solver. The sensitivity of the second harmonic generation to the thickness of each layer can be calculated by taking the analytical differential of the equation to the thickness of each element. </p><p>The quantum dot dynamics in semiconductor are described by the Maxwell-Bloch equations. The frequency domain Maxwell-Bloch equations are deduced. The spectral element method is used to solve these equations to inspect the steady state quantum dot dynamic behaviors under the continuous wave electromagnetic excitation.</p><p>For time domain simulation, the first order curl equations in Maxwell equations are the basic equations. A spectral element method based on brick element is implemented to simulate a nano-structure consisting of woodpile photonic crystal. The resonance of a micro-cavity consisting of a point defect in the woodpile photonic crystal block is simulated. In addition, the time domain Maxwell-Bloch equations are implemented in the solver. The spontaneous emission process of quantum dot in the micro-cavity is inspected. </p><p>Another effort is to implement the Maxwell-Bloch equations in a previously implemented domain decomposition spectral element/finite element time domain solver. The solver can handle unstructured mesh, which can simulate complicated structure. The time dependent dynamics of a quantum dot in the middle of a nano-sphere are investigated by this implementation. The population inversion under continuous and pulse excitation is investigated. </p><p>In conclusion, the spectral element method is implemented for frequency domain and time domain solvers. High efficient and accurate solutions for multiple layers nano-structures are obtained. The solvers can be applied to design nano-structures, such as photonic crystal slab resonators, and nano-scale semiconductor lasers.</p> / Dissertation
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Theoretical and numerical studies of chaotic mixingKim, Ho Jun 10 October 2008 (has links)
Theoretical and numerical studies of chaotic mixing are performed to circumvent the difficulties
of efficient mixing, which come from the lack of turbulence in microfluidic devices. In order to
carry out efficient and accurate parametric studies and to identify a fully chaotic state, a spectral
element algorithm for solution of the incompressible Navier-Stokes and species transport
equations is developed. Using Taylor series expansions in time marching, the new algorithm
employs an algebraic factorization scheme on multi-dimensional staggered spectral element
grids, and extends classical conforming Galerkin formulations to nonconforming spectral
elements. Lagrangian particle tracking methods are utilized to study particle dispersion in the
mixing device using spectral element and fourth order Runge-Kutta discretizations in space and
time, respectively. Comparative studies of five different techniques commonly employed to
identify the chaotic strength and mixing efficiency in microfluidic systems are presented to
demonstrate the competitive advantages and shortcomings of each method. These are the stirring
index based on the box counting method, Poincare sections, finite time Lyapunov exponents, the
probability density function of the stretching field, and mixing index inverse, based on the
standard deviation of scalar species distribution. Series of numerical simulations are performed
by varying the Peclet number (Pe) at fixed kinematic conditions. The mixing length (lm) is characterized as function of the Pe number, and lm ∝ ln(Pe) scaling is demonstrated for fully
chaotic cases. Employing the aforementioned techniques, optimum kinematic conditions and the
actuation frequency of the stirrer that result in the highest mixing/stirring efficiency are
identified in a zeta potential patterned straight micro channel, where a continuous flow is
generated by superposition of a steady pressure driven flow and time periodic electroosmotic
flow induced by a stream-wise AC electric field. Finally, it is shown that the invariant manifold
of hyperbolic periodic point determines the geometry of fast mixing zones in oscillatory flows in
two-dimensional cavity.
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Spectral element method for numerical simulation of unsteady laminar diffusion flamesWessel, Richard Allen, Jr January 1993 (has links)
No description available.
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Finite and Spectral Element Methods for Modeling Far-Field Underwater Explosion Effects on ShipsKlenow, Bradley A. 22 May 2009 (has links)
The far-field underwater explosion (UNDEX) problem is a complicated problem dominated by two phenomena: the shock wave traveling through the fluid and the cavitation in the fluid. Both of these phenomena have a significant effect on the loading of ship structures subjected to UNDEX.
An approach to numerically modeling these effects in the fluid and coupling to a structural model is using cavitating acoustic finite elements (CAFE) and more recently cavitating acoustic spectral elements (CASE). The use of spectral elements in CASE has shown to offer the greater accuracy and reduced computational expense when compared to traditional finite elements. However, spectral elements also increase spurious oscillations in both the fluid and structural response.
This dissertation investigates the application of CAFE, CASE, and a possible improvement to CAFE in the form of a finite element flux-corrected transport algorithm, to the far-field UNDEX problem by solving a set of simplified UNDEX problems. Specifically we examine the effect of increased oscillations on structural response and the effect of errors in cavitation capture on the structural response which have not been thoroughly explored in previous work.
The main contributions of this work are a demonstration of the problem dependency of increased oscillations in the structural response when applying the CASE methodology, the demonstration of how the sensitivity of errors in the structural response changes with changes in the structural model, a detailed explanation of how error in cavitation capture influences the structural response, and a demonstration of the need to accurately capture the shape and magnitude of cavitation regions in the fluid in order to obtain accurate structural response results. / Ph. D.
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High-order finite element methods for seismic wave propagationDe Basabe Delgado, Jonás de Dios, 1975- 03 February 2010 (has links)
Purely numerical methods based on the Finite Element Method (FEM) are becoming
increasingly popular in seismic modeling for the propagation of acoustic and
elastic waves in geophysical models. These methods o er a better control on the accuracy
and more geometrical
exibility than the Finite Di erence methods that have
been traditionally used for the generation of synthetic seismograms. However, the
success of these methods has outpaced their analytic validation. The accuracy of the
FEMs used for seismic wave propagation is unknown in most cases and therefore
the simulation parameters in numerical experiments are determined by empirical
rules. I focus on two methods that are particularly suited for seismic modeling: the
Spectral Element Method (SEM) and the Interior-Penalty Discontinuous Galerkin
Method (IP-DGM).
The goals of this research are to investigate the grid dispersion and stability
of SEM and IP-DGM, to implement these methods and to apply them to subsurface
models to obtain synthetic seismograms. In order to analyze the grid dispersion
and stability, I use the von Neumann method (plane wave analysis) to obtain a
generalized eigenvalue problem. I show that the eigenvalues are related to the grid
dispersion and that, with certain assumptions, the size of the eigenvalue problem can be reduced from the total number of degrees of freedom to one proportional to
the number of degrees of freedom inside one element.
The grid dispersion results indicate that SEM of degree greater than 4 is
isotropic and has a very low dispersion. Similar dispersion properties are observed
for the symmetric formulation of IP-DGM of degree greater than 4 using nodal basis
functions. The low dispersion of these methods allows for a sampling ratio of 4 nodes
per wavelength to be used. On the other hand, the stability analysis shows that,
in the elastic case, the size of the time step required in IP-DGM is approximately
6 times smaller than that of SEM. The results from the analysis are con rmed by
numerical experiments performed using an implementation of these methods. The
methods are tested using two benchmarks: Lamb's problems and the SEG/EAGE
salt dome model. / text
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Spectral-element simulations of separated turbulent internal flowsOhlsson, Johan January 2009 (has links)
No description available.
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Nonconforming formulations with spectral element methodsSert, Cuneyt 15 November 2004 (has links)
A spectral element algorithm for solution of the incompressible Navier-Stokes and heat transfer equations is developed, with an emphasis on extending the classical conforming Galerkin formulations to nonconforming spectral elements. The new algorithm employs both the Constrained Approximation Method (CAM), and the Mortar Element Method (MEM) for p-and h-type nonconforming elements. Detailed descriptions, and formulation steps for both methods, as well as the performance comparisons between CAM and MEM, are presented. This study fills an important gap in the literature by providing a detailed explanation for treatment of p-and h-type nonconforming interfaces. A comparative eigenvalue spectrum analysis of diffusion and convection operators is provided for CAM and MEM. Effects of consistency errors due to the nonconforming formulations on the convergence of steady and time dependent problems are studied in detail. Incompressible flow solvers that can utilize these nonconforming formulations on both p- and h-type nonconforming grids are developed and validated. Engineering use of the developed solvers are demonstrated by detailed parametric analyses of oscillatory flow forced convection heat transfer in two-dimensional channels.
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Spectral Integral Method and Spectral Element Method Domain Decomposition Method for Electromagnetic Field AnalysisLin, Yun January 2011 (has links)
<p>In this work, we proposed a spectral integral method (SIM)-spectral element method (SEM)- finite element method (FEM) domain decomposition method (DDM) for solving inhomogeneous multi-scale problems. The proposed SIM-SEM-FEM domain decomposition algorithm can efficiently handle problems with multi-scale structures, </p><p>by using FEM to model electrically small sub-domains and using SEM to model electrically large and smooth sub-domains. The SIM is utilized as an efficient boundary condition. This combination can reduce the total number of elements used in solving multi-scale problems, thus it is more efficient than conventional FEM or conventional FEM domain decomposition method. Another merit of the proposed method is that it is capable of handling arbitrary non-conforming elements. Both geometry modeling and mesh generation are totally independent for different sub-domains, thus the geometry modeling and mesh generation are highly flexible for the proposed SEM-FEM domain decomposition method. As a result, the proposed SIM-SEM-FEM DDM algorithm is very suitable for solving inhomogeneous multi-scale problems.</p> / Dissertation
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Spectral (h-p) Element Methods Approach To The Solution Of Poisson And Helmholtz Equations Using MatlabMaral, Tugrul 01 December 2006 (has links) (PDF)
A spectral element solver program using MATLAB is written for the solution of Poisson and Helmholtz equations. The accuracy of spectral methods (p-type high order) and the geometric flexibility of the low-order h-type finite elements
are combined in spectral element methods.
Rectangular elements are used to solve Poisson and Helmholtz equations with Dirichlet and Neumann boundary conditions which are homogeneous or non homogeneous. Robin (mixed) boundary conditions are also implemented.
Poisson equation is also solved by discretising the domain with curvilinear quadrilateral elements so that the accuracy of both isoparametric quadrilateral and rectangular element stiffness matrices and element mass matrices are tested.
Quadrilateral elements are used to obtain the stream functions of the inviscid flow around a cylinder problem. Nonhomogeneous Neumann boundary conditions are imposed to the quadrilateral element stiffness matrix to solve the
velocity potentials.
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