Thomas Wagenknecht scite author profile

Abstract. Stable localized roll structures have been observed in many physical problems and model equations, notably in the 1D Swift-Hohenberg equation. Reflection-symmetric localized rolls are often found to lie on two "snaking" solution branches, so that the spatial width of the localized rolls increases when moving along each branch. Recent numerical results by Burke and Knobloch indicate that the two branches are connected by infinitely many "ladder" branches of asymmetric localized rolls. In this paper, these phenomena are investigated analytically. It is shown that both snaking of symmetric pulses and the ladder structure of asymmetric states can be predicted completely from the bifurcation structure of fronts that connect the trivial state to rolls. It is also shown that isolas of asymmetric states may exist, and it is argued that the results presented here apply to 2D stationary states that are localized in one spatial direction.

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Homoclinic snaking near a heteroclinic cycle in reversible systems

Knobloch

Wagenknecht

2005

Physica D: Nonlinear Phenomena

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Snaking curves of homoclinic orbits have been found numerically in a number of ODE models from water wave theory and structural mechanics. Along such a curve infinitely many fold bifurcation of homoclinic orbits occur. Thereby the corresponding solutions spread out and develop more and more bumps (oscillations) about their own centre. A common feature of the examples is that the systems under consideration are reversible.In this paper it is shown that such a homoclinic snaking can be caused by a heteroclinic cycle between two equilibria, one of which is a bi-focus. Using Lin's method a snaking of 1-homoclinic orbits is proved to occur in an unfolding of such a cycle. Further dynamical consequences are discussed.As an application a system of Boussinesq equations is considered, where numerically a homoclinic snaking curve is detected and it is shown that the homoclinic orbits accumulate along a heteroclinic cycle between a real saddle and a bi-focus equilibrium.

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Pseudospectra and stability radii for analytic matrix functions with application to time-delay systems

Michiels

Green

Wagenknecht

et al. 2006

Linear Algebra and its Applications

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Definitions for pseudospectra and stability radii of an analytic matrix function are given, where the structure of the function is exploited. Various perturbation measures are considered and computationally tractable formulae are derived. The results are applied to a class of retarded delay differential equations. Special properties of the pseudospectra of such equations are determined and illustrated.

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Isolas of 2-Pulse Solutions in Homoclinic Snaking Scenarios

et al. 2010

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Homoclinic snaking refers to the bifurcation structure of symmetric localised roll patterns that are often found to lie on two sinusoidal “snaking” bifurcation curves, which are connected by an infinite number of “rung” segments along which asymmetric localised rolls of various widths exist. The envelopes of all these structures have a unique maximum and we refer to them as symmetric or asymmetric 1-pulses. In this paper, the existence of stationary 1D patterns of symmetric 2-pulses that consist of two well-separated 1-pulses is established. Corroborating earlier numerical evidence, it is shown that symmetric 2-pulses exist along isolas in parameter space that are formed by parts of the snaking curves and the rungs mentioned above

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Some third-order ordinary differential equations

Swinnerton–Dyer

Wagenknecht²

2008

Bulletin of the London Mathematical Society

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The paper deals with periodic orbits in three systems of ordinary differential equations. Two of the systems, the Falkner-Skan equations and the Nosé equations, do not possess fixed points, and yet interesting dynamics can be found. Here, periodic orbits emerge in bifurcations from heteroclinic cycles, connecting fixed points at infinity. We present existence results for such periodic orbits and discuss their properties using careful asymptotic arguments. In the final part results about the Nosé equations are used to explain the dynamics in a dissipative perturbation, related to a system of dynamo equations.

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