Adaptive Finite Element Solution Algorithm for the Euler Equations: 32 - Brossura

Contenuti

1 Introduction.- 1.1 Research Goals.- 1.2 Overview of Thesis.- 1.3 Survey of Finite Element Methods for the Euler Equations.- 2 Governing Equations.- 2.1 Euler Equations.- 2.2 Non-Dimensionalization of the Equations.- 2.3 Auxiliary Quantities.- 2.4 Boundary Conditions.- 2.4.1 Solid Surface Boundary Conditions.- 2.4.2 Open Boundary Conditions.- 3 Finite Element Fundamentals.- 3.1 Basic Definitions.- 3.2 Finite Elements and Natural Coordinates.- 3.2.1 Properties of Interpolation Functions.- 3.2.2 Natural Coordinates and Derivative Calculation.- 3.3 Typical Elements.- 3.3.1 Bilinear Element.- 3.3.2 Biquadratic Element.- 3.3.3 Trilinear Element.- 4 Solution Algorithm.- 4.1 Overview of Algorithm.- 4.2 Spatial Discretization.- 4.3 Choice of Test Functions.- 4.3.1 Test Functions for Galerkin Method.- 4.3.2 Test Functions for Cell-Vertex Method.- 4.3.3 Test Functions for Central Difference Method.- 4.4 Boundary Conditions.- 4.4.1 Solid Surface Boundary Condition.- 4.4.2 Open Boundary Condition.- 4.5 Smoothing.- 4.5.1 Conservative, Low-Accuracy Second Difference.- 4.5.2 Non-Conservative, High-Accuracy Second Difference.- 4.5.3 Combined Smoothing.- 4.5.4 Smoothing on Biquadratic Elements.- 4.6 Time Integration.- 4.7 Consistency and Conservation.- 4.7.1 Making Artificial Viscosity Conservative.- 5 Algorithm Verification and Comparisons.- 5.1 Introduction.- 5.2 Verification and Comparison of Methods.- 5.2.1 5° Converging Channel.- 5.2.2 15° Converging Channel.- 5.2.3 4% Circular Arc Bump.- 5.2.4 10% Circular Arc Bump.- 5.2.5 10% Cosine Bump.- 5.2.6 CPU Comparison and Recommendations.- 5.2.7 Verification of Conservation.- 5.3 Effects of Added Dissipation.- 5.4 Biquadratic vs. Bilinear.- 5.4.1 5° Channel Flow.- 5.4.2 4% Circular Arc Bump.- 5.4.3 10% Cosine Bump.- 5.5 Three Dimensional Verification.- 5.6 Summary.- 6 Adaptation.- 6.1 Introduction.- 6.2 Adaptation Procedure.- 6.2.1 Placement of Boundary Nodes.- 6.2.2 How Much Adaptation?.- 6.3 Adaptation Criteria.- 6.3.1 First-Difference Indicator.- 6.3.2 Second-Difference Indicator.- 6.3.3 Two-Dimensional Directional Adaptation.- 6.4 Embedded Interface Treatment.- 6.4.1 Two-Dimensional Interface.- 6.4.2 Three-Dimensional Interface.- 6.5 Examples of Adaptation.- 6.5.1 Multiple Shock Reflections.- 6.5.2 4% Circular Arc Bump.- 6.5.3 10% Circular Arc Bump.- 6.5.4 3-D Channel.- 6.5.5 Distorted Grid.- 6.6 CPU Time Comparisons.- 7 Dispersion Phenomena and the Euler Equations.- 7.1 Introduction.- 7.2 Difference Stencils.- 7.2.1 Some Properties of the Galerkin Stencil.- 7.2.2 Some Properties of the Cell-Vertex Stencil.- 7.3 Linearization of the Equations.- 7.4 Fourier Analysis of the Linearized Equations.- 7.5 Numerical Verification.- 7.6 Conclusions.- 8 Scramjet Inlets.- 8.1 Introduction.- 8.2 Two-Dimensional Test Cases.- 8.2.1 M? = 5, 0° Yaw.- 8.2.2 M? = 5, 5° Yaw.- 8.2.3 M? = 2, 0° Yaw.- 8.2.4 M? = 3, 0° Yaw.- 8.2.5 M? = 3, 7° Yaw.- 8.2.6 Inlet Performance and Total Pressure Loss.- 8.3 Three-Dimensional Results.- 9 Summary and Conclusions.- 9.1 Summary.- 9.2 Contributions of the Thesis.- 9.3 Conclusions.- 9.4 Areas for Further Exploration.- A Computational Issues.- A.1 Introduction.- A.2 Vectorization and Parallelization Issues.- A.3 Computer Memory Requirements.- A.3.1 Two-Dimensional Memory Requirements.- A.3.2 Three-Dimensional Memory Requirements.- A.4 Data Structures for Adaptation.- A.4.1 Finding the Children of an Element.- A.4.2 Finding The Adjacent Element.- B Scramjet Geometry Definition.- References.- List of Symbols.