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The finite element method for fluid dynamics / by Olek C. Zienkiewicz, Robert L. Taylor, P. Nithiarasu.
Saved in:
Bibliographic Details
Main Authors:
Zienkiewicz, O. C.
(Author)
,
Taylor, Robert L. (Robert Leroy), 1934-
(Author)
,
Nithiarasu, Perumal
(Author)
Format:
eBook
Language:
English
Published:
Oxford :
Butterworth-Heinemann,
2014.
Edition:
Seventh edition.
Subjects:
Fluid dynamics
>
Mathematics.
Finite element method.
TECHNOLOGY & ENGINEERING
>
Engineering (General)
TECHNOLOGY & ENGINEERING
>
Reference.
Finite element method
Fluid dynamics
>
Mathematics
Online Access:
Click for online access
Holdings
Description
Table of Contents
Staff View
Table of Contents:
Note continued: 12.6.5. Trefftz-type finite elements for waves
12.7. Refraction
12.7.1. Wave speed refraction
12.7.2. Refraction caused by flows
12.8. Spectral finite elements for waves
12.9. Discontinuous Galerkin finite elements (DGFE)
12.10. Concluding remarks
References
ch. 13 Fluid
Structure Interaction
13.1. Introduction
13.2. One-dimensional fluid
structure interaction
13.2.1. Equations
13.2.2. Characteristic analysis
13.2.3. Boundary conditions
13.2.4. Solution method: Taylor-Galerkin method
13.2.5. Some results
13.3. Multidimensional problems
13.3.1. Equations and discretization
13.3.2. Segregated approach
13.3.3. Mesh moving procedures
13.4. Concluding remarks
References
ch. 14 Biofluid Dynamics
14.1. Introduction
14.2. Flow in human arterial system
14.2.1. Heart
14.2.2. Reflections
14.2.3. Aortic valve
14.2.4. Vessel branching
14.2.5. Terminal vessels
14.2.6. Numerical solution
14.3. Image-based subject-specific flow modeling
14.3.1. Image segmentation
14.3.2. Geometrical potential force (GPF)
14.3.3. Numerical solution, initial and boundary conditions
14.3.4. Domain discretization
14.3.5. Flow solution
14.4. Concluding remarks
References
ch. 15 Computer Implementation of the CBS Algorithm
15.1. Introduction
15.2. The data input module
15.2.1. Mesh data: Nodal coordinates and connectivity
15.2.2. Boundary data
15.2.3. Other necessary data and flags
15.2.4. Preliminary subroutines and checks
15.3. Solution module
15.3.1. Time step
15.3.2. Shock capture
15.3.3. CBS algorithm: Steps
15.3.4. Boundary conditions
15.3.5. Solution of simultaneous equations: Semi-implicit form
15.3.6. Different forms of energy equation
15.3.7. Convergence to steady state
15.4. Output module
References.
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