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Computational Mechanics

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01-02-2016 | Original Paper

A high order reduction–correction method for Hopf bifurcation in fluids and for viscoelastic vibration

Authors: J. M. Cadou, F. Boumediene, Y. Guevel, G. Girault, L. Duigou, E. M. Daya, M. Potier-Ferry

Published in: Computational Mechanics | Issue 2/2016

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Abstract

There are many recent studies concerning reduced-order computational methods, especially reductions by projection on a small-sized basis. But it is difficult to control the quality of the solutions if the basis is fixed once and for all. This is why we attempt to define efficient and low-cost strategies for correction and updating of the basis. These correction steps re-use previously computed quantities such as: vectors and triangulated matrices. The proposed algorithms use alternately full and reduced-size steps, allowing a strong reduction in the number of full-size tangent matrices. Two classes of applications are discussed. First, we consider an algorithm for determining Hopf bifurcation points in 2D Navier–Stokes equations, but which requires time-consuming preliminary frequency-dependent calculations. New reduction–correction procedures are applied to reduce these preliminary computations. The second application concerns the response curves of viscoelastic structures. A key point is the definition of the reduced basis. Vector Taylor series are computed within the asymptotic numerical method and the relevance of this set of vectors is analysed.

previous article A computational framework for polyconvex large strain elasticity for geometrically exact beam theory

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Lumley JL (1967) The structure of inhomogeneous turbulent flows. In: Yaglom AM, Tatarski VI (eds) Atmospheric turbulence and radio wave propagation. NAUCA, Moscow

Cazemier W, Verstappen RWCP, Veldman AEP (1998) Proper orthogonal decomposition and low-dimensional models for driven cavity flows. Phys Fluids 10–7:1685–1699

Terragni F, Vega JM (2014) Construction of bifurcation diagrams using POD on the fly. SIAM J Appl Dyn Syst 13(1):339–365CrossRefMathSciNetMATH

Herrero H, Maday Y, Plaa F (2013) RB (Reduced basis) for RB (Rayleigh–Bénard). Comput Method Appl Mech Eng 261–262:132–141CrossRef

Patera AT, Rozza G (2006) Reduced basis approximation and a posteriori error estimation for parametrized partial differential equations, Version 1.0, Copyright MIT 2006, (tentative rubric) MIT Pappalardo Graduate Monographs in Mechanical Engineering. Available from: http://augustine.mit.edu/methodology/methodology_bookPartI.htm

Chinesta F, Keunings R, Leygue A (2014) The proper generalized decomposition for advanced numerical simulations, springer Briefs in Applied Sciences and Technology. Springer, BerlinCrossRef

Ladevèze P (1989) The large time increment for the analyse of structures with nonlinear constitutive relation described by internal variables. Compt Rend de l’Académie des Sci 309:1095–1099MATH

Chinesta F, Leygue A, Beringhier M, Tuan Nguyen L, Grandidier JC, Schrefler B, Pesavento F (2013) Towards a framework for non-linear thermal models in shell domains. Int J Numer Method Heat Fluid Flow 23(1):55–73CrossRef

Bilasse M, Azrar L, Daya EM (2011) Complex modes based numerical analysis of viscoelastic sandwich plates vibrations. Comput Struct 89:539–555CrossRef

10.

de Lima AMG, da Silva AR, Rade DA, Bouhaddi N (2010) Component mode synthesis combining robust enriched Ritz approach for viscoelastically damped structures. Eng Struct 32:1479–1488CrossRef

11.

Zghal S, Bouazizi ML, Bouhaddi N, Nasri R (2015) Model reduction methods for viscoelastic sandwich structures in frequency and time domains. Finite Elem Anal Design 93:12–29CrossRef

12.

Bilasse M, Oguamanam DCD (2013) Forced harmonic response of sandwich plates with viscoelastic core using reduced-order model. Compos Struct 105:311–318CrossRef

13.

Heyman J, Girault G, Guevel Y, Allery C, Hamdouni A, Cadou JM (2013) Computation of Hopf bifurcations coupling reduced order models and the asymptotic numerical method. Comput Fluids 76:73–85CrossRefMathSciNet

14.

Cadou JM, Potier-Ferry M, Cochelin B (2006) A numerical method for the computation of bifurcation points in fluid mechanics. Eur J Mech B 25:234–254CrossRefMathSciNetMATH

15.

Brezillon A, Girault G, Cadou JM (2010) A numerical algorithm coupling a bifurcating indicator and a direct method for the computation of Hopf bifurcation points in fluid mechanics. Comput Fluids 39:1226–1240CrossRefMathSciNetMATH

16.

Girault G, Guevel Y, Cadou JM (2012) An algorithm for the computation of multiple Hopf bifurcation points based on Padé approximants. Int J Numer Method Fluids 68:1189–1206CrossRefMathSciNetMATH

17.

Cochelin B (1994) A path-following technique via an asymptotic-numerical method. Comput Struct 53(5):1181–1192CrossRefMATH

18.

Cadou JM, Potier-Ferry M (2010) A solver combining reduced basis and convergence acceleration with applications to non-linear elasticity. Int J Numer Method Biomed Eng 26:1604–1617

19.

Daya EM, Potier-Ferry M (2002) Finite element for viscoelastically damped sandwich structures. Revue Européenne des Eléments Finis 11:39–56CrossRefMATH

20.

Abdoun F, Azrar L, Daya EM, Potier-Ferry M (2009) Forced harmonic response of viscoelastic structures by an asymptotic numerical method. Comput Struct 87:91–100CrossRef

21.

Duigou L, Daya EM, Potier-Ferry M (2003) Iterative algorithms for non-linear eigenvalue problems. Appl Vib Viscoelastic Shells, Comput Method Appl Mech Eng 192:1323–1335CrossRefMATH

22.

Imazatène A, Cadou JM, Zahrouni H, Potier-Ferry M (2001) A new reduced basis method for non-linear problems. Revue Europénne des Eléments Finis 10(1):55–76

23.

Jbilou K, Sadok H (2000) Vector extrapolation methods. Appl Numer Comp J Comput Appl Math 122:149–165CrossRefMathSciNetMATH

24.

Baker GA, Graves-Morris P (1996) Padé approximants, encyclopedia of mathematics and its applications, 2nd edn. Cambridge University Press, Cambridge

25.

Damil N, Cadou JM, Potier-Ferry M (2004) Mathematical and numerical connections between polynomial extrapolations and Padé approximants. Commun Numer Method Eng 20(9):699–707CrossRefMathSciNetMATH

26.

Cadou JM, Duigou L, Damil N, Potier-Ferry M (2009) Convergence acceleration of iterative algorithms. Applications to thin shell analysis and Navier-Stokes equations. Comput Mech 43(2):253–264

27.

Galliet I, Cochelin B (2004) Une version parallèle des méthodes asymptotiques numériques. Revue Europénne des Eléments Finis 13:177–195CrossRefMATH

28.

Jepson AD (1981) Numerical Hopf bifurcation. Thesis, California Institute of Technology

29.

Boumediene F, Duigou L, Boutyour EH, Miloudi A, Cadou JM (2011) Nonlinear forced vibration of damped plates coupling asymptotic numerical method and reduction models. Comput Mech 47(4):359–377CrossRefMATH

30.

Jackson CP (1987) A finite-element study of the onset of vortex shedding in flow past variously shaped body. J Fluid Mech 182:23–45CrossRefMATH

31.

Griewank A, Reddien G (1983) The computation of Hopf points by a direct method. IMA J Numer Anal 3:295–303CrossRefMathSciNetMATH

32.

Bensaadi MEH (1995) Méthode asymptotique-numérique pour le calcul de bifurcations de Hopf et de solutions périodiques. Thesis, Université de Metz

33.

Soni ML (1981) Finite element analysis of viscoelastically damped sandwich structures. Shock Vib Bull 55(1):97–109

34.

Zienkiewicz OC, Taylor RL (1991) The finite element method, 2, 4th edn. Mcgraw-hill book company, New York

35.

Cadou JM, Cochelin B, Damil N, Potier-Ferry M (2001) Asymptotic numerical method for stationary Navier–Stokes equations and with Petrov–Galerkin formulation. Int J Numer Method Eng 50:825–845CrossRefMATH

36.

Wahba EM (2009) Multiplicity of states for two-sided and four-sided lid driven cavity flows. Comput Fluids 38:247–253

37.

Cadou JM, Guevel Y, Girault G (2012) Numerical tools for the stability analysis of 2D flows. Appl Two Four-sided Lid-driven Cavity Fluid Dyn Res 44:031403MathSciNet

38.

Abouhamza A, Pierre R (2003) A neutral stability curve for incompressible flows in a rectangular driven cavity. Math Comput Model 38:141–157CrossRefMathSciNetMATH

39.

Auteri F, Parolini N, Quartapelle L (2002) Numerical investigation on the stability of singular driven cavity flow. J Comput Phys 183:1–25CrossRefMathSciNetMATH

40.

Boppana VBL, Gajjar JSB (2010) Global flow instability in a lid-driven cavity. Int J Numer Method Fluids 62(8):827–853MathSciNetMATH

41.

Fortin A, Jardak M, Gervais JJ, Pierre R (1997) Localization of Hopf bifurcations in fluid flow problems. Int J Numer Method Fluids 24:1185–1210CrossRefMathSciNetMATH

42.

Poliashenko M, Aidun CK (1995) A direct method for computation of simple bifurcations. J Comput Phys 121:246–260CrossRefMathSciNetMATH

43.

Wahba EM (2013) Numerical simulations of flow bifurcations inside a driven cavity. CFD Lett 3(2):100–110

44.

Zhuo C, Zhong C, Guo X, Cao J (2013) MRT-LBM simulation of four-lid-driven cavity flow bifurcation. Procedia engineering, 25th international conference on parallel computational fluid dynamics vol 61, pp 100–107

45.

Guevel Y, Boutyour H, Cadou JM (2011) Automatic detection and branch switching methods for steady bifurcation in fluid mechanics. J Comput Phys 230(9):3614–3629CrossRefMathSciNetMATH

46.

Büchter N, Ramm E, Roehl D (1994) Three dimensional extension of nonlinear shell formulation based on the enhanced assumed strain concept. Int J Numer Method Eng 37:2551–2568CrossRefMATH

47.

Rao DK (1978) Frequency and loss factor of sandwich beams under various boundary conditions. J Mech Eng Sci 20:271–282CrossRef

48.

Ma BA, He JF (1992) Finite element analysis of viscoelastically damped sandwich plates. J Sound Vib 52:107–123CrossRef

49.

Cadou JM, Damil N, Potier-Ferry M, Braikat B (2004) Projection technique to improve high order iterative correctors. Finite Elem Anal Design 41:285–309CrossRef

50.

Boumediene F, Daya EM, Cadou JM, Duigou L (2015) Forced harmonic response of viscoelastic sandwich beams by a reduction method. Mech Adv Mater Struct. doi:10.1080/15376494.2015.1068408

Title: A high order reduction–correction method for Hopf bifurcation in fluids and for viscoelastic vibration
Authors: J. M. Cadou
F. Boumediene
Y. Guevel
G. Girault
L. Duigou
E. M. Daya
M. Potier-Ferry
Publication date: 01-02-2016
Publisher: Springer Berlin Heidelberg
Published in: Computational Mechanics / Issue 2/2016
Print ISSN: 0178-7675
Electronic ISSN: 1432-0924
DOI: https://doi.org/10.1007/s00466-015-1232-4

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