A high order accurate finite element algorithm for high Reynolds number flow prediction
Abstract
A Galerkin-weighted residuals formulation is employed to establish an implicit finite element solution algorithm for generally nonlinear initial-boundary value problems. Solution accuracy, and convergence rate with discretization refinement, are quantized in several error norms, by a systematic study of numerical solutions to several nonlinear parabolic and a hyperbolic partial differential equation characteristic of the equations governing fluid flows. Solutions are generated using selective linear, quadratic and cubic basis functions. Richardson extrapolation is employed to generate a higher-order accurate solution to facilitate isolation of truncation error in all norms. Extension of the mathematical theory underlying accuracy and convergence concepts for linear elliptic equations is predicted for equations characteristic of laminar and turbulent fluid flows at nonmodest Reynolds number. The nondiagonal initial-value matrix structure introduced by the finite element theory is determined intrinsic to improved solution accuracy and convergence. A factored Jacobian iteration algorithm is derived and evaluated to yield a consequential reduction in both computer storage and execution CPU requirements while retaining solution accuracy.
- Publication:
-
Final Technical Report Tennessee Univ
- Pub Date:
- June 1978
- Bibcode:
- 1978tenn.reptS....B
- Keywords:
-
- Algorithms;
- Finite Element Method;
- Numerical Flow Visualization;
- Prediction Analysis Techniques;
- Reynolds Number;
- Boundary Value Problems;
- Fluid Flow;
- Galerkin Method;
- Jacobi Integral;
- Problem Solving;
- Fluid Mechanics and Heat Transfer