Phase Dynamics of Nearly Stationary Patterns in Activator-Inhibitor
  Systems

A. Hagberg; A. Hagberg; A. Hagberg; A. Ito; A. Rovinsky; A.C. Newell; A.D. Wit; A.G. Heidemann; Aric Hagberg; B.S. Kerner; C.B. Muratov; C.P. Schenk; E. Ammelt; E. Meron; E.M. Kuznetsova; Ehud Meron; J. Lega; J.D. Dockery; J.J. Perraud; J.J. Tyson; K. Krischer; K.J. Lee; L. Kramer; M. Or-Guil; M.C. Cross; M.C. Cross; P. De Kepper; Q. Ouyang; Q. Ouyang; R. Woesler; R.E. Goldstein; T. Ohta; Thierry Passot; V. Castets; V.V. Osipov

research

Phase Dynamics of Nearly Stationary Patterns in Activator-Inhibitor Systems

Authors: A. Hagberg
A. Hagberg
A. Hagberg
A. Ito
A. Rovinsky
A.C. Newell
A.D. Wit
A.G. Heidemann
Aric Hagberg
B.S. Kerner
C.B. Muratov
C.P. Schenk
E. Ammelt
E. Meron
E.M. Kuznetsova
Ehud Meron
J. Lega
J.D. Dockery
J.J. Perraud
J.J. Tyson
K. Krischer
K.J. Lee
L. Kramer
M. Or-Guil
M.C. Cross
M.C. Cross
P. De Kepper
Q. Ouyang
Q. Ouyang
R. Woesler
R.E. Goldstein
T. Ohta
Thierry Passot
V. Castets
V.V. Osipov
Publication date: 6 April 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The slow dynamics of nearly stationary patterns in a FitzHugh-Nagumo model are studied using a phase dynamics approach. A Cross-Newell phase equation describing slow and weak modulations of periodic stationary solutions is derived. The derivation applies to the bistable, excitable, and the Turing unstable regimes. In the bistable case stability thresholds are obtained for the Eckhaus and the zigzag instabilities and for the transition to traveling waves. Neutral stability curves demonstrate the destabilization of stationary planar patterns at low wavenumbers to zigzag and traveling modes. Numerical solutions of the model system support the theoretical findings

Similar works

Full text

Available Versions

Crossref

Last time updated on 02/01/2020