Available in electronic format
Available in print format		 Transacrions of the American Mathematical Society
Transactions of the American Mathematical Society
ISSN 1088-6850(e) ISSN 0002-9947(p)
Previous issue | Table of contents | Next issue
Articles in press | Recently posted articles | Most recent issue | All issues
Previous Article | Next Article
     

Exponential averaging for Hamiltonian evolution equations

Author(s): Karsten Matthies; Arnd Scheel
Journal: Trans. Amer. Math. Soc. 355 (2003), 747-773.
MSC (2000): Primary 37K55, 37L10, 70K65; Secondary 35Q55, 70K70
Posted: October 2, 2002
Retrieve article in: PDF DVI PostScript

Abstract | References | Similar articles | Additional information

Abstract: We derive estimates on the magnitude of non-adiabatic interaction between a Hamiltonian partial differential equation and a high-frequency nonlinear oscillator. Assuming spatial analyticity of the initial conditions, we show that the dynamics can be transformed to the uncoupled dynamics of an infinite-dimensional Hamiltonian system and an anharmonic oscillator, up to coupling terms which are exponentially small in a certain power of the frequency of the oscillator. The result is derived from an abstract averaging theorem for infinite-dimensional analytic evolution equations in Gevrey spaces. Refining upon a similar result by Neishtadt for analytic ordinary differential equations, the temporal estimate crucially depends on the spatial regularity of the initial condition. The result shows to what extent the strong resonances between rapid forcing and highly oscillatory spatial modes can be suppressed by the choice of sufficiently smooth initial data. An application is provided by a system of nonlinear Schrödinger equations, coupled to a rapidly forcing single mode, representing small-scale oscillations. We provide an example showing that the estimates for partial differential equations we derive here are necessarily different from those in the context of ordinary differential equations.

References:

[Bam99]
D. Bambusi, Nekhoroshev theorem for small amplitude solutions in nonlinear Schrödinger equations. Math. Z. 230 (1999), 345-387. MR 2000h:35146

[FeTi98]
A. Ferrari and E. Titi, Gevrey regularity for nonlinear analytic parabolic equations, Comm. Part. Diff. Eq. 23 (1998), 1-16. MR 99a:35116

[FiVi00]
B. Fiedler and M. I. Vishik, Quantitative homogenization of global attractors for reaction-diffusion systems with rapidly oscillating terms, MSAP preprint (2000).

[FoTe89]
C. Foias and R. Temam, Gevrey class regularity for the solution of the Navier-Stokes equations, J. Funct. Anal. 87 (1989), 359-369. MR 91a:35135

[LoMe88]
P. Lochak and C. Meunier, Multiphase Averaging for Classical Systems, Applied Mathematical Sciences 72, Springer-Verlag, New York (1988).

[MaRa94]
J. Marsden and T. Ratiu, Introduction to Mechanics and Symmetry, Texts in Applied Mathematics 17, Springer-Verlag, New York (1994). MR 2000i:70002

[Mat00]
K. Matthies, Homogenization of exponential order for elliptic systems in infinite cylinders, preprint (2000).

[Mat01]
K. Matthies, Time-averaging under fast periodic forcing of parabolic partial differential equations: Exponential estimates, J. Differential Equations 174 (2001), 133-180.

[Nei84]
A. Neishtadt, The separation of motions in systems with rapidly rotating phase, J. Appl. Math. Mech. 48 (1984), 133-139. MR 86j:34043

[Nek79]
N. N. Nekhorosev, An exponential estimate of the time of stability of nearly integrable Hamiltonian systems, (Russian) Uspehi Mat. Nauk 32 (1977), no. 6 (198), 5-66.

[Paz83]
A. Pazy, Semigroups of Linear Operators and Applications to Partial Differential Equations, Applied Mathematical Sciences 44, Springer-Verlag, New York (1983). MR 85g:47061

[Poe99]
J. Pöschel, On Nekhoroshev estimates for a nonlinear Schrödinger equation and a theorem by Bambusi. Nonlinearity 12 (1999), 1587-1600. MR 2001e:37100

[Pro91]
K. Promislow, Time analyticity and Gevrey regularity for solutions of a class of dissipative partial differential equations, Nonl. Analysis, Th. Meth. Appl. 16 (1991), 959-980. MR 92h:35192

[SaScWu99]
B. Sandstede, A. Scheel, and C. Wulff, Bifurcations and dynamics of spiral waves. J. Nonlinear Science 9 (1999), 439-478. MR 2000h:35020

[TBDHT96]
P. Takác, P. Bollerman, A. Doelman, A. van Harten, and E. Titi, Analyticity of essentially bounded solutions to semilinear parabolic systems and validity of the Ginzburg-Landau equation, SIAM J. Math. Anal. 27 (1996), 424-448. MR 96m:35150

[Vis00]
M. Vishik, Attractors of evolution equations with rapidly oscillating terms, Proc. Internat. Conf. in Honor of R. Temam, Paris, to appear.

Similar Articles:

Retrieve articles in Transactions of the American Mathematical Society with MSC (2000): 37K55, 37L10, 70K65, 35Q55, 70K70

Retrieve articles in all Journals with MSC (2000): 37K55, 37L10, 70K65, 35Q55, 70K70

Additional Information:

Karsten Matthies
Affiliation: Mathematical Institute, University of Warwick, Coventry CV4 7AL, United Kingdom
Address at time of publication: FU Berlin, Institut für Mathematik I, Arnimallee 2-6, 14195 Berlin, Germany
Email: matthies@maths.warwick.ac.uk, matthies@math.fu-berlin.de

Arnd Scheel
Affiliation: School of Mathematics, University of Minnesota, 206 Church St. S.E., Minneapolis, Minnesota 55455
Email: scheel@math.umn.edu

DOI: 10.1090/S0002-9947-02-03143-4
PII: S 0002-9947(02)03143-4
Keywords: Averaging, exponential order, analytic evolution equation, infinite-dimensional Hamiltonian system, Gevrey regularity, nonlinear Schr\"odinger equation
Received by editor(s): October 8, 2001
Received by editor(s) in revised form: May 15, 2002
Posted: October 2, 2002
Additional Notes: The first author was supported by the Deutsche Forschungsgemeinschaft (DFG) under grant Ma 2351/1
The second author gratefully acknowledges support from DAAD/Procope, Nr. D/0031082
Copyright of article: Copyright 2002, American Mathematical Society

  AMS Website Logo Small Comments: webmaster@ams.org
© Copyright 2008, American Mathematical Society
Privacy Statement 		Search the AMSPowered by Google