Navier-Stokes Equations in Planar Domains
Nonfiction, Science & Nature, Mathematics, Differential Equations, Applied
| Author: | Matania Ben-Artzi, Jean-Pierre Croisille, Dalia Fishelov | ISBN: | 9781783263011 |
| Publisher: | World Scientific Publishing Company | Publication: | March 7, 2013 |
| Imprint: | ICP | Language: | English |
| Author: | Matania Ben-Artzi, Jean-Pierre Croisille, Dalia Fishelov |
| ISBN: | 9781783263011 |
| Publisher: | World Scientific Publishing Company |
| Publication: | March 7, 2013 |
| Imprint: | ICP |
| Language: | English |
This volume deals with the classical Navier-Stokes system of equations governing the planar flow of incompressible, viscid fluid. It is a first-of-its-kind book, devoted to all aspects of the study of such flows, ranging from theoretical to numerical, including detailed accounts of classical test problems such as “driven cavity” and “double-driven cavity”.
A comprehensive treatment of the mathematical theory developed in the last 15 years is elaborated, heretofore never presented in other books. It gives a detailed account of the modern compact schemes based on a “pure streamfunction” approach. In particular, a complete proof of convergence is given for the full nonlinear problem.
This volume aims to present a variety of numerical test problems. It is therefore well positioned as a reference for both theoretical and applied mathematicians, as well as a text that can be used by graduate students pursuing studies in (pure or applied) mathematics, fluid dynamics and mathematical physics.
Contents:
-
Basic Theory:
- Introduction
- Existence and Uniqueness of Smooth Solutions
- Estimates for Smooth Solutions
- Extension of the Solution Operator
- Measures as Initial Data
- Asymptotic Behavior for Large Time
- Some Theorems from Functional Analysis
-
Approximate Solutions:
- Introduction
- Notation
- Finite Difference Approximation to Second-Order Boundary-Value Problems
- From Hermitian Derivative to the Compact Discrete Biharmonic Operator
- Polynomial Approach to the Discrete Biharmonic Operator
- Compact Approximation of the Navier–Stokes Equations in Streamfunction Formulation
- Fully Discrete Approximation of the Navier–Stokes Equations
- Numerical Simulations of the Driven Cavity Problem
Readership: Graduate students and researchers in applied mathematics (particularly computational fluid dynamics), partial differential equations, and mathematical physics (specifically nonlinear evolution equations).
Key Features:
- Provides an up-to-date account of recent developments in vorticity theory
- Presents comprehensive treatment of viscous flow problems in flat domains
- Addresses the classical problem: How rapidly do rotating flows evolve in time?
- Includes theoretical and numerical methods
- Presents state-of-the-art streamfunction formalism (theoretical and numerical)
This volume deals with the classical Navier-Stokes system of equations governing the planar flow of incompressible, viscid fluid. It is a first-of-its-kind book, devoted to all aspects of the study of such flows, ranging from theoretical to numerical, including detailed accounts of classical test problems such as “driven cavity” and “double-driven cavity”.
A comprehensive treatment of the mathematical theory developed in the last 15 years is elaborated, heretofore never presented in other books. It gives a detailed account of the modern compact schemes based on a “pure streamfunction” approach. In particular, a complete proof of convergence is given for the full nonlinear problem.
This volume aims to present a variety of numerical test problems. It is therefore well positioned as a reference for both theoretical and applied mathematicians, as well as a text that can be used by graduate students pursuing studies in (pure or applied) mathematics, fluid dynamics and mathematical physics.
Contents:
-
Basic Theory:
- Introduction
- Existence and Uniqueness of Smooth Solutions
- Estimates for Smooth Solutions
- Extension of the Solution Operator
- Measures as Initial Data
- Asymptotic Behavior for Large Time
- Some Theorems from Functional Analysis
-
Approximate Solutions:
- Introduction
- Notation
- Finite Difference Approximation to Second-Order Boundary-Value Problems
- From Hermitian Derivative to the Compact Discrete Biharmonic Operator
- Polynomial Approach to the Discrete Biharmonic Operator
- Compact Approximation of the Navier–Stokes Equations in Streamfunction Formulation
- Fully Discrete Approximation of the Navier–Stokes Equations
- Numerical Simulations of the Driven Cavity Problem
Readership: Graduate students and researchers in applied mathematics (particularly computational fluid dynamics), partial differential equations, and mathematical physics (specifically nonlinear evolution equations).
Key Features:
- Provides an up-to-date account of recent developments in vorticity theory
- Presents comprehensive treatment of viscous flow problems in flat domains
- Addresses the classical problem: How rapidly do rotating flows evolve in time?
- Includes theoretical and numerical methods
- Presents state-of-the-art streamfunction formalism (theoretical and numerical)
