Robust heteroclinic cycles in the one-dimensional complex Ginzburg-Landau equation
Robust heteroclinic cycles in the one-dimensional complex Ginzburg-Landau equation
Numerical evidence is presented for the existence of stable heteroclinic cycles in large parameter regions of the one-dimensional complex Ginzburg–Landau equation (CGL) on the unit, spatially periodic domain. These cycles connect different spatially and temporally inhomogeneous time-periodic solutions as t?±?. A careful analysis of the connections is made using a projection onto five complex Fourier modes. It is shown first that the time-periodic solutions can be treated as (relative) equilibria after consideration of the symmetries of the CGL. Second, the cycles are shown to be robust since the individual heteroclinic connections exist in invariant subspaces. Thirdly, after constructing appropriate Poincaré maps around the cycle, a criteria for temporal stability is established, which is shown numerically to hold in specific parameter regions where the cycles are found to be of Shil’nikov type. This criterion is also applied to a much higher-mode Fourier truncation where similar results are found. In regions where instability of the cycles occurs, either Shil’nikov–Hopf or blow-out bifurcations are observed, with numerical evidence of competing attractors. Implications for observed spatio-temporal intermittency in situations modelled by the CGL are discussed
complex ginzburg–landau equation, intermittency, heteroclinic cycles
240-268
Lloyd, D.J.B.
50a11792-84b3-48ce-80b4-04b443fd6278
Champneys, A.R.
d9418c20-e8ce-4bc6-9285-bace80e2df3f
Wilson, R.E.
613f4def-6dfa-4a60-8f89-4006f2059f09
May 2005
Lloyd, D.J.B.
50a11792-84b3-48ce-80b4-04b443fd6278
Champneys, A.R.
d9418c20-e8ce-4bc6-9285-bace80e2df3f
Wilson, R.E.
613f4def-6dfa-4a60-8f89-4006f2059f09
Lloyd, D.J.B., Champneys, A.R. and Wilson, R.E.
(2005)
Robust heteroclinic cycles in the one-dimensional complex Ginzburg-Landau equation.
Physica D, 204 (3-4), .
(doi:10.1016/j.physd.2005.04.019).
Abstract
Numerical evidence is presented for the existence of stable heteroclinic cycles in large parameter regions of the one-dimensional complex Ginzburg–Landau equation (CGL) on the unit, spatially periodic domain. These cycles connect different spatially and temporally inhomogeneous time-periodic solutions as t?±?. A careful analysis of the connections is made using a projection onto five complex Fourier modes. It is shown first that the time-periodic solutions can be treated as (relative) equilibria after consideration of the symmetries of the CGL. Second, the cycles are shown to be robust since the individual heteroclinic connections exist in invariant subspaces. Thirdly, after constructing appropriate Poincaré maps around the cycle, a criteria for temporal stability is established, which is shown numerically to hold in specific parameter regions where the cycles are found to be of Shil’nikov type. This criterion is also applied to a much higher-mode Fourier truncation where similar results are found. In regions where instability of the cycles occurs, either Shil’nikov–Hopf or blow-out bifurcations are observed, with numerical evidence of competing attractors. Implications for observed spatio-temporal intermittency in situations modelled by the CGL are discussed
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Published date: May 2005
Keywords:
complex ginzburg–landau equation, intermittency, heteroclinic cycles
Organisations:
Civil Engineering & the Environment
Identifiers
Local EPrints ID: 184263
URI: http://eprints.soton.ac.uk/id/eprint/184263
ISSN: 0167-2789
PURE UUID: d9c10d6c-9fc4-41ec-9287-e69ab0edeeec
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Date deposited: 19 May 2011 08:36
Last modified: 14 Mar 2024 03:07
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Contributors
Author:
D.J.B. Lloyd
Author:
A.R. Champneys
Author:
R.E. Wilson
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