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Meccanica
Erschienen in: Meccanica 6/2016

21.11.2015

Implicit one-step dynamic algorithms with configuration-dependent parameters: application to central force fields

verfasst von: Gordan Jelenić

Erschienen in: Meccanica | Ausgabe 6/2016

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Abstract

This work presents a family of implicit one-step algorithms for non-linear dynamics possessing the ability to conserve some of the integrals of the underlying Hamiltonian motion. Algorithmic parameters, normally taken as constants, are here made dependent on the actual configuration and thus become particularly suitable for capturing some of the additional properties of a non-linear motion, while at the same time not increasing the computational burden in the Newton–Raphson solution process. The family of algorithms presented includes several well-known implicit algorithms as special cases. The idea is presented on a two-degree-of-freedom problem of a point mass moving in a central force field. The concept is illustrated on two model examples taken to represent some of the issues in non-linear elastodynamics and celestial mechanics: a stiff mechanical problem and a problem possessing an additional integral of motion. It is shown that in this way overall motion of a stiff problem may be described much better even using very large time steps while, for the Keplerian motion, the anomalous perihelion drift may be successfully removed.
Vorheriger Artikel Statements on nonlinear dynamics behavior of a pendulum, excited by a crank-shaft-slider mechanism
Nächster Artikel Preliminary design of a small-sized flapping UAV: I. Aerodynamic performance and static longitudinal stability

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Literatur
1.
Armero F, Romero I (2001) On the formulation of high-frequency dissipative time-stepping algorithms for nonlinear dynamics. Part I: low order methods for two model problems and nonlinear elastodynamics. Comput Methods Appl Mech Eng 190:2603–2649ADSMathSciNetCrossRefMATH
2.
Armero F, Zambrana-Rojas C (2007) Volume-preserving energy–momentum schemes for isochoric multiplicative plasticity. Comput Methods Appl Mech Eng 196:4130–4159ADSMathSciNetCrossRefMATH
3.
Arnold VI (1989) Mathematical methods of classical mechanics, 2nd edn. Springer, New YorkCrossRef
4.
Ascher U, Reich S (1998) On some difficulties in integrating highly oscillatory Hamiltonian systems. Lect Notes Comput Sci Eng 4:281–296MathSciNetCrossRefMATH
5.
Betsch P, Steinmann P (2000) Conservation properties of a time FE method. Part I: time-stepping schemes for N-body problems. Int J Numer Meththods Eng 49:599–638MathSciNetCrossRefMATH
6.
7.
8.
Betsch P, Hesch C, Saenger N, Uhlar S (2010) Variational integrators and energy–momentum schemes for flexible multibody dynamics. J Comput Nonlinear Dyn 5, Article Number: 031001
9.
10.
Bou-Rabee N, Marsden JE (2009) Hamilton–Pontryagin integrators on Lie groups part I: introduction and structure-preserving properties. Found Comput Math 9:197–219MathSciNetCrossRefMATH
11.
Chang DE, Chichka DF, Marsden JE (2002) Lyapunov-based transfer between elliptic Keplerian orbits. Discrete Contin Dyn Syst Ser B 2:57–67MathSciNetMATH
12.
Chorin AJ, Hughes TJR, McCracken MF, Marsden JE (1978) Product formulas and numerical algorithms. Commun Pure Appl Math 31:205–256MathSciNetCrossRefMATH
13.
Crisfield MA, Shi J (1994) A co-rotational element/time-integration strategy for non-linear dynamics. Int J Numer Methods Eng 37:1897–1913MathSciNetCrossRefMATH
14.
15.
Fradkin DM (1967) Existence of the dynamic symmetries \(O_4\) and \(SU_3\) for all classical central potential problems. Progress Theor Phys 37:798–812ADSCrossRef
16.
Goldstein H (1980) Classical mechanics, 2nd edn. Addison-Wesley, Reading
17.
18.
Gonzalez O, Simo JC (1996) On the stability of symplectic and energy–momentum algorithms for non-linear Hamiltonian systems with symmetry. Comput Methods Appl Mech Eng 134:197–222ADSMathSciNetCrossRefMATH
19.
Graham E, Jelenić G, Crisfield MA (2002) A note on the equivalence of some recent time-integration schemes for N-body problems. Commun Numer Methods Eng 18:615–620CrossRefMATH
20.
Graham E, Jelenić G (2003) A general framework for conservative single-step time-integration schemes with higher-order accuracy for a central-force system. Comput Methods Appl Mech Eng 192:3585–3618ADSMathSciNetCrossRefMATH
21.
Graham E, Jelenić G (2006) Conservative single-step time-integration schemes with higher-order accuracy for multi-particle dynamics with local two-point potentials. Comput Methods Appl Mech Eng 195:4917–4952ADSMathSciNetCrossRefMATH
22.
23.
24.
Hairer E, Wanner G (1996) Solving ordinary differential equations II. Stiff and differential-algebraic problems. Springer series in computational mathematics, vol 14. Springer, Berlin
25.
Hairer E, Lubich C, Wanner G (2006) Geometrical numerical integration. Springer series in computational mathematics, vol 31. Springer, Berlin
26.
Hughes TJR (2000) The finite element method. Linear static and dynamic finite element analysis. Dover Civil and Mechanical Engineering, New YorkMATH
27.
28.
29.
Kane C, Marsden JE, Ortiz M, West M (2000) Variational integrators and the Newmark algorithm for conservative and dissipative mechanical systems. Int J Numer Methods Eng 49:1295–1325MathSciNetCrossRefMATH
30.
Krueger M, Gross M, Betsch P (2011) A comparison of structure-preserving integrators for discrete thermoelastic systems. Comput Mech 47:701–722MathSciNetCrossRefMATH
31.
Kustaanheimo P, Stiefel E (1965) Perturbation theory of Kepler motion based on spinor regularization. J Reine Angew Math 218:204–219MathSciNetMATH
32.
LaBudde RA, Greenspan D (1976) Energy and angular momentum conserving methods of arbitrary order for the numerical integration of equations of motion. Part I: motion of a single particle. Numer Math 25:323–346MathSciNetCrossRefMATH
33.
Lamb H (1914) Dynamics. Cambridge University Press, LondonMATH
34.
Leimkuhler B (1999) Reversible adaptive regularization: perturbed Kepler motion and classical atomic trajectories. Philos Trans R Soc Lond A 357:1101–1133ADSMathSciNetCrossRefMATH
35.
36.
Leyendecker S, Marsden JE, Ortiz M (2008) Variational integrators for constrained dynamical systems. Z Ang Math Mech 88:677–708MathSciNetCrossRefMATH
37.
Marsden JE (1992) Lectures on mechanics. London mathematical society lecture note series, vol 174. Cambridge University Press, Cambridge
38.
Ollongren A (1962) Three-dimensional galactic stellar orbits. Bull Astron Inst Neth 16:241–296ADS
39.
Sanz-Serna JM, Calvo MP (1994) Numerical Hamiltonian problems. Applied mathematics and mathematical computation, vol 7. Chapman and Hall, London
40.
Simo JC, Lewis D, Marsden JE (1991) Stability of relative equilibria. Part I: the reduced energy–momentum method. Arch Ration Mech Anal 115:15–59MathSciNetCrossRefMATH
41.
Simo JC, Wong KK (1991) Unconditionally stable algorithms for rigid body dynamics that exactly preserve energy and momentum. Int J Numer Methods Eng 31:19–52MathSciNetCrossRefMATH
42.
Simo JC, Tarnow N (1992) The discrete energy–momentum method. Conserving algorithms for nonlinear elastodynamics. J Appl Math Phys (ZAMP) 43:757–792MathSciNetCrossRefMATH
43.
Simo JC, Tarnow N, Wong KK (1992) Exact energy–momentum conserving algorithms and symplectic schemes for nonlinear dynamics. Comput Methods Appl Mech Eng 100:63–116ADSMathSciNetCrossRefMATH
44.
Simo JC, Gonzalez O (1993) Assessment of energy–momentum and symplectic schemes for stiff dynamical systems. In Papers—American Society of Mechanical Engineers—All Series (ASME Winter Annual Meeting), vol 93(4). New Orleans
45.
Simo JC, Tarnow N, Doblare M (1995) Nonlinear dynamics of three-dimensional rods: exact energy and momentum conserving algorithms. Int J Numer Methods Eng 38:1431–1473MathSciNetCrossRefMATH
46.
Tao ML, Owhadi H, Marsden JE (2010) Nonintrusive and structure preserving multiscale integration of stiff ODEs, SDEs, and Hamiltonian systems with hidden slow dynamics via flow averaging. Multiscale Model Simul 8:1269–1324MathSciNetCrossRefMATH
47.
48.
Whittaker ET (1988) A treatise on the analytical dynamics of particles and rigid bodies, 4th edn. Cambridge University Press, CambridgeCrossRefMATH
49.
Zhong G, Marsden JE (1988) Lie–Poisson Hamilton–Jacobi theory and Lie–Poisson integrators. Phys Lett A 133:134–139ADSMathSciNetCrossRef
Metadaten
Titel
Implicit one-step dynamic algorithms with configuration-dependent parameters: application to central force fields
verfasst von
Gordan Jelenić
Publikationsdatum
21.11.2015
Verlag
Springer Netherlands
Erschienen in
Meccanica / Ausgabe 6/2016
Print ISSN: 0025-6455
Elektronische ISSN: 1572-9648
DOI
https://doi.org/10.1007/s11012-015-0319-5

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