A Comparison of Least-Squares Finite Element Models with the Conventional Finite Element Models of Problems in Heat Transfer and Fluid Mechanics

Nellie Rajarova,

2009 May 1900

In this thesis, least-squares based finite element models (LSFEM) for the Poisson equation and Navier-Stokes equation are presented. The least-squares method is simple, general and reliable. Least-squares formulations offer several computational and theoretical advantages. The resulting coefficient matrix is symmetric and positive-definite. Using these formulations, the choice of approximating space is not subject to any compatibility condition. The Poisson equation is cast as a set of first order equations involving gradient of the primary variable as auxiliary variables for the mixed least-square finite element model. Equal order C0 continuous approximation functions is used for primary and auxiliary variables. Least-squares principle was directly applied to develop another model which requires C1continous approximation functions for the primary variable. Each developed model is compared with the conventional model to verify its performance. Penalty based least-squares formulation was implemented to develop a finite element for the Navier Stokes equations. The continuity equation is treated as a constraint on the velocity field and the constraint is enforced using the penalty method. Velocity gradients are introduced as auxiliary variables to get the first order equivalent system. Both the primary and auxiliary variables are interpolated using equal order C0 continuous, p-version approximation functions. Numerical examples are presented to demonstrate the convergence characteristics and accuracy of the method.

LSFEM

Poisson's equation

h-version

p-version,Navier-tokes

Velocity

Velocity Gradient

Penalty

Puasono lygties sprendimas naudojantis šaltinio apibendrintomis hiperbolinės funkcijomis / Poisson's equation using a source of summarized hyperbolic functions

Brenčys, Liutauras

04 August 2011

Sudarytas Puasono lygties sprendimo per „rutuliukų“ potencialus algoritmas. Šiuo metodu Puasono lygties sprendimo uždavinys suvedamas į tiesinių algebrinių lygčių sistemos sprendimą. Sudaryta ir išbandyta matematiniu paketu MATHCAD to sprendimo programa. Palyginti gauti sprendiniai su tais, kurie gaunami analiziškai, įvertintas gautų sprendinių tikslumas. Šį sprendimo būdą galima panaudoti realiems fizikiniams potencialams paskaičiuoti, turint galvoje realų potencialą su kuriuo realūs krūviai. / It consists of Poisson equation solution in the "ball" potential algorithm. In this method the Poisson equation, the decision problem are reduced to linear algebraic equations system solution. Created and tested a mathematical package MATHCAD program for that decision. Compared to solutions with those obtained analytically, estimated to obtain accurate solutions. This solution can be used to calculate the real physical potentials, given the real potential of the real workloads.

Mathematics

Puasono lygtis

Algoritmas

Tiesinė algebrinė lygčių sistema

Poisson's equation

Algorithm

Linear algebraic equations

Colloidal interaction forces on approach, in contact and during separation :

Feiler, Adam.

Unknown Date

Thesis (PhD)--University of South Australia, 2001.

Atomic force microscopy.

Surfaces (Physics)

Colloids

Poisson's equation.

Silica.

Titanium dioxide.

Development of a dynamic calculation tool forsimulation of ditching

Pilorget, Marc

January 2011

The present document is the final master thesis report written by Marc PILORGET,student at SUPAERO (home institution) and KTH (Royal Institute of Technology,Exchange University). This six months internship was done at DASSAULT AVIATION(Airframe engineering department) based in Saint-Cloud, France. It spanned from the 5thof July to the 23rd of December. The thesis work aims at developing an SPH (SmoothParticle Hydrodynamics) calculation method for ditching and implementing it in the finiteelement software ELFINI® developed by DASSAULT. Ditching corresponds to a phasewhen the aeroplane is touching the water. The problematic of ditching has always beenan area of interest for DASSAULT and the whole aeronautical industry. So far, only testsand simple analytical calculations have been performed. Most of the work was carried bythe NACA (National Advisory Committee for Aeronautics) in the late 70's. However in thepast decade, a new method for fluid-structure coupling problems has been developed. Itis called SPH. The basic principle is the following: the domain is represented by means ofparticles and each particle of fluid is treated separately and submitted to the Navier-Stokes equations. The particle is influenced by the neighbouring particles with a weightfunction depending on the distance between the two particles. Particles are also placed atthe interface solid-fluid: they are called limit particles. The final purpose of this SPHmethod is to access to the structural response of an aircraft when ditching. The crucialinterest of such a method compared to methods used so far is the absence of mesh. Theanalysis of large deformation problems by the finite element method may require thecontinuous remeshing of the domain to avoid the breakdown of the calculation due toexcessive mesh distortion. When considering ditching or other large deformationsproblems, the mesh generation is a far more time-consuming task than the constructionand solution of a discrete set of equations. For DASSAULT-AVIATION, the long termobjective is to get a numerical tool able to model ditching. The SPH method is used tosolve the equations for the fluid and is coupled with a finite element method for thestructure. So far, the compressible solver for 2D geometries has been implemented.Tests are going to be performed to ensure the program’s robustness. Then theincompressible solver for 2D geometries will be studied both theoretically andnumerically.

SPH

kernel

incompressible

Poisson's equation

boundary conditions

Engineering and Technology

Teknik och teknologier

Computer Simulation of Biological Ion Channels

Hoyles, Matthew, Matthew.Hoyles@anu.edu.au

January 2000

This thesis describes a project in which algorithms are developed for the rapid and accurate solution of Poisson's equation in the presence of a dielectric boundary and multiple point charges. These algorithms are then used to perform Brownian dynamics simulations on realistic models of biological ion channels. An iterative method of solution, in which the dielectric boundary is tiled with variable sized surface charge sectors, provides the flexibility to deal with arbitrarily shaped boundaries, but is too slow to perform Brownian dynamics. An analytical solution is derived, which is faster and more accurate, but only works for a toroidal boundary. Finally, a method is developed of pre-calculating solutions to Poisson's equation and storing them in tables. The solution for a particular configuration of ions in the channel can then be assembled by interpolation from the tables and application of the principle of superposition. This algorithm combines the flexibility of the iterative method with greater speed even than the analytical method, and is fast enough that channel conductance can be predicted. The results of simulations for a model single-ion channel, based on the acetylcholine receptor channel, show that the narrow pore through the low dielectric strength medium of the protein creates an energy barrier which restricts the permeation of ions. They further show that this barrier can be removed by dipoles in the neck of the channel, but that the barrier is not removed by shielding by counter-ions. The results of simulations for a model multi-ion channel, based on a bacterial potassium channel, show that the model channel has conductance characteristics similar to those of real potassium channels. Ions appear to move through the model multi-ion channel via rapid transitions between a series of semi-stable states. This observation suggests a possible physical basis for the reaction rate theory of channel conductance, and opens up an avenue for future research.

computer simulation

ion channels

conductance theories

electrostatics

Brownian dynamics

single-ion channel

multi-ion channel

Poisson's equation

dielectric boundary

potassium channel

Realization and comparison of various mesh refinement strategies near edges

Apel, T., Milde, F.

30 October 1998

This paper is concerned with mesh refinement techniques for treating elliptic boundary value problems in domains with re- entrant edges and corners, and focuses on numerical experiments. After a section about the model problem and discretization strategies, their realization in the experimental code FEMPS3D is described. For two representative examples the numerically determined error norms are recorded, and various mesh refinement strategies are compared.

singularities near edges

Fichera corner

finite element methods

convergence

a priori mesh grading algorithms

adaptive mesh

refinement

Poisson's equation

MSC 65N50

MSC 65N30

MSC 35J05

ddc:510

Summation By Parts Finite Difference Methods with Simultaneous Approximation Terms for the Heat Equation with Discontinuous Coefficients

Kåhlman, Niklas

January 2019

In this thesis we will investigate how the SBP-SAT finite difference method behave with and without an interface. As model problem, we consider the heat equation with piecewise constant coefficients. The thesis is split in two main parts. In the first part we look at the heat equation in one-dimension, and in the second part we expand the problem to a two-dimensional domain. We show how the SAT-parameters are chosen such that the scheme is dual consistent and stable. Then, we perform numerical experiments, now looking at the static case. In the one-dimensional case we see that the second order SBP-SAT method with an interface converge with an order of two, while the second order SBP-SAT method without an interface converge with an order of one.

Finite Difference Method

FDM

Summation By Parts

Simultaneous Approximation Terms

SBP-SAT

Heat Equation

Poisson's Equation

Discontinuous Coefficients

Piecewise Constant Coefficients

Convergence

Dual Consistency

Stability

Computational Mathematics

Beräkningsmatematik

Discrete Mathematics

Diskret matematik

Mathematical Analysis

Matematisk analys

Other Mathematics

Annan matematik

Realization and comparison of various mesh refinement strategies near edges

Apel, T., Milde, F.

30 October 1998

This paper is concerned with mesh refinement techniques for treating elliptic boundary value problems in domains with re- entrant edges and corners, and focuses on numerical experiments. After a section about the model problem and discretization strategies, their realization in the experimental code FEMPS3D is described. For two representative examples the numerically determined error norms are recorded, and various mesh refinement strategies are compared.

info:eu-repo/classification/ddc/510

ddc:510

MSC 65N50, MSC 65N30, MSC 35J05