Skip to main content
Fachgebiete
Automobil + Motoren Bauwesen + Immobilien Business IT + Informatik Elektrotechnik + Elektronik Energie + Nachhaltigkeit Finance + Banking Management + Führung Marketing + Vertrieb Maschinenbau + Werkstoffe Versicherung + Risiko
DE
EN
Themenseiten
Organisationspsychologie Projektmanagement Marketing Smart Manufacturing
Bücher
Zeitschriften
Weitere Formate
Podcasts Webinare Technik Webinare Wirtschaft Kongresse Veranstaltungskalender Awards
Jetzt Einzelzugang starten
Zugang für Unternehmen
Referenzkunden
MTZ-Fachkongress

Antriebe und Energiesysteme von morgen


Austausch von Automobil- und Energiewirtschaft

Am 14./15. Mai geht es in Chemnitz um die Mobilitätswende durch Elektro- und Wasserstofffahrzeuge.
Erweiterte Suche
Anmelden
nach oben
Calcolo
Erschienen in: Calcolo 1/2018

01.03.2018

Optimal vorticity accuracy in an efficient velocity–vorticity method for the 2D Navier–Stokes equations

verfasst von: M. Akbas, L. G. Rebholz, C. Zerfas

Erschienen in: Calcolo | Ausgabe 1/2018

Einloggen, um Zugang zu erhalten

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config
loading …

Abstract

We study a velocity–vorticity scheme for the 2D incompressible Navier–Stokes equations, which is based on a formulation that couples the rotation form of the momentum equation with the vorticity equation, and a temporal discretization that stably decouples the system at each time step and allows for simultaneous solving of the vorticity equation and velocity–pressure system (thus if special care is taken in its implementation, the method can have no extra cost compared to common velocity–pressure schemes). This scheme was recently shown to be unconditionally long-time \(H^1\) stable for both velocity and vorticity, which is a property not shared by any common velocity–pressure method. Herein, we analyze the scheme’s convergence, and prove that it yields unconditional optimal accuracy for both velocity and vorticity, thus making it advantageous over common velocity–pressure schemes if the vorticity variable is of interest. Numerical experiments are given that illustrate the theory and demonstrate the scheme’s usefulness on some benchmark problems.
Vorheriger Artikel Image reconstruction from scattered Radon data by weighted positive definite kernel functions
Nächster Artikel Cubature formulae for nearly singular and highly oscillating integrals
Literatur
1.
2.
Bochev, P.: Negative norm least-squares methods for the velocity–vorticity–pressure Navier–Stokes equations. Numer. Methods Partial Differ. Equ. 15(2), 237–256 (1999)MathSciNetCrossRefMATH
3.
Brenner, S., Scott, L.R.: The Mathematical Theory of Finite Element Methods, 3rd edn. Springer, Berlin (2008)CrossRefMATH
4.
Brezzi, F.: On the existence, uniqueness and approximation of saddle point problems arising from Lagrange multpliers. R.A.I.R.O 8, 129–151 (1974)MATH
5.
Charnyi, S., Heister, T., Olshanskii, M., Rebholz, L.: On conservation laws of Navier–Stokes Galerkin discretizations. J. Comput. Phys. 337, 289–308 (2017)MathSciNetCrossRef
6.
Ervin, V.J., Heuer, N.: Approximation of time-dependent, viscoelastic fluid flow: Crank–Nicolson, finite element approximation. Numer. Methods Partial Differ. Equ. 20, 248–283 (2003)MathSciNetCrossRefMATH
7.
Girault, V., Raviart, P.A.: Finite Element Methods for Navier–Stokes Equations: Theory and Algorithms. Springer, Berlin (1986)CrossRefMATH
8.
Gresho, P., Sani, R.: Incompressible Flow and the Finite Element Method, vol. 2. Wiley, New York (1998)MATH
9.
Gresho, P.M.: On the theory of semi-implicit projection methods for viscous incompressible flow and its implementation via a finite element method that also introduces a nearly consistent mass matrix. Part 1: theory. Int. J. Numer. Methods Fluids 11(5), 587–620 (1990)MathSciNetCrossRefMATH
10.
Heath, M.: Scientific Computing: An Introductory Survey. McGraw-Hill, New York (2002)MATH
11.
Heister, T., Olshanskii, M. A., Rebholz, L. G.: Unconditional long-time stability of a velocity–vorticity method for 2D Navier–Stokes equations. Numerische Mathematik 135(1), 143–167 (2016)
12.
Heywood, J., Rannacher, R.: Finite element approximation of the nonstationary Navier–Stokes problem. Part IV: error analysis for the second order time discretization. SIAM J. Numer. Anal. 2, 353–384 (1990)CrossRefMATH
13.
John, V.: Large Eddy Simulation of Turbulent Incompressible Flows: Analytical and Numerical Results for a Class of LES Models. Lecture Notes in Computational Science and Engineering. Springer, Berlin (2004)CrossRef
14.
Ladyzhenskaya, O.: The Mathematical Theory of Viscous Incompressible Flow. Gordon and Breach Science Publishers, New York (1969)MATH
15.
Layton, W.: Introduction to Finite Element Methods for Incompressible, Viscous Flow. SIAM, Philadelphia (2008)
16.
Layton, W., Manica, C.C., Neda, M., Olshanskii, M., Rebholz, L.G.: On the accuracy of the rotation form in simulations of the Navier–Stokes equations. J. Comput. Phys. 228, 3433–3447 (2009)MathSciNetCrossRefMATH
17.
Lee, H.K., Olshanskii, M.A., Rebholz, L.G.: On error analysis for the 3D Navier–Stokes equations in velocity–vorticity–helicity form. SIAM J. Numer. Anal. 49(2), 711–732 (2011)MathSciNetCrossRefMATH
18.
Liska, R., Wendroff, B.: Comparison of several difference schemes on 1D and 2D test problems for the Euler equations. SIAM J. Sci. Comput. 25, 995–1017 (2003)MathSciNetCrossRefMATH
19.
Najjar, F., Vanka, S.: Simulations of the unsteady separated flow past a normal flat plate. Int. J. Numer. Methods Fluids 21, 525–547 (1995)CrossRefMATH
20.
Olshanskii, M.A., Rebholz, L.G.: Velocity–vorticity–helicity formulation and a solver for the Navier–Stokes equations. J. Comput. Phys. 229, 4291–4303 (2010)MathSciNetCrossRefMATH
21.
Olshanskii, M.A., Heister, T., Rebholz, L., Galvin, K.: Natural vorticity boundary conditions on solid walls. Comput. Methods Appl. Mech. Eng. 297, 18–37 (2015)MathSciNetCrossRef
22.
Saha, A.: Far-wake characteristics of two-dimensional flow past a normal flat plate. Phys. Fluids 19(128110), 1–4 (2007)MATH
23.
Saha, A.: Direct numerical simulation of two-dimensional flow past a normal flat plate. J. Eng. Mech. 139(12), 1894–1901 (2013)CrossRef
24.
25.
Tezduyar, T., Mittal, S., Ray, S., Shih, R.: Incompressible flow computations with stabilized bilinear and linear equal order interpolation velocity–pressure elements. Comput. Methods Appl. Mech. Eng. 95, 221–242 (1992)CrossRefMATH
26.
Tone, F.: On the long-time stability of the Crank–Nicholson scheme for the 2D Navier–Stokes equations. Numer. Methods D. E. 23(5), 1235–1248 (2007)CrossRefMATH
27.
Tone, F., Wirosoetisno, D.: On the long-time stability of the implicit Euler scheme for the two-dimensional Navier–Stokes equations. SIAM J. Numer. Anal. 44(1), 29–40 (2006)MathSciNetCrossRefMATH
28.
Wong, K.L., Baker, A.J.: A 3D incompressible Navier–Stokes velocity–vorticity weak form finite element algorithm. Int. J. Numer. Methods Fluids 38, 99–123 (2002)CrossRefMATH
Metadaten
Titel
Optimal vorticity accuracy in an efficient velocity–vorticity method for the 2D Navier–Stokes equations
verfasst von
M. Akbas
L. G. Rebholz
C. Zerfas
Publikationsdatum
01.03.2018
Verlag
Springer Milan
Erschienen in
Calcolo / Ausgabe 1/2018
Print ISSN: 0008-0624
Elektronische ISSN: 1126-5434
DOI
https://doi.org/10.1007/s10092-018-0246-7

Weitere Artikel der Ausgabe 1/2018

Calcolo 1/2018 Zur Ausgabe

OriginalPaper

Nonlinear Galerkin methods for a system of PDEs with Turing instabilities

OriginalPaper

An inexact Newton method for solving complementarity problems in hydrodynamic lubrication

OriginalPaper

Image reconstruction from scattered Radon data by weighted positive definite kernel functions

OriginalPaper

Some error analysis on virtual element methods

OriginalPaper

Cubature formulae for nearly singular and highly oscillating integrals

Premium Partner

    Bildnachweise