Dynamics of Spiral Waves in Complex Ginzburg-Landau Systems Subjected to Feedback Derived from an Annular Domain

doi:10.19596/j.cnki.1001-246x.8360

Abstract

Abstract:

We studied dynamics of spiral waves subjected to a feedback control, where the feedback signal is obtained with integral in an annular region.As the annular region is circular, the spiral tip usually enters a circular attractor after a transient drift, and radius of the attractor varies periodically with parameters of the annular region.With the change of these parameters, drift direction of the spiral tip at the beginning of feedback also has a periodic change.In the phase of transient drift, modulus function of the complex feedback signal is bell-shaped, and the steepness of the bell is related to the smoothness of the drift trajectory.The sign and value of the feedback gain affect the dynamical behavior of the controlled spiral.As the annular region is square, final attractors of the spiral tip are more abundant, including mainly square attractor, limit circle attractor with small amplitude, diamond attractor and point attractor, where the point attractors are usually on the diagonal lines of the square.Here, trajectory of the spiral tip has a regular change with control parameters of the annual region as well.

Key words: spiral wave, Ginzburg-Landau system, feedback control, attractor

Shaoying CHEN, Xueli WANG, Zhimei GAO, Guoyong YUAN. Dynamics of Spiral Waves in Complex Ginzburg-Landau Systems Subjected to Feedback Derived from an Annular Domain[J]. Chinese Journal of Computational Physics, 2022, 39(1): 118-126.

Figures/Tables 11

Fig.1 Spiral snapshots and spiral tip tractories (a) rfb1=20; (b) rfb1=40; (c) rfb1=60 (The two pink circles are inner and outer boundaries of the annular measuring region. The black dot describes location of the spiral tip before the feedback is switched on. The black line is the tip trajectory after the feedback is applied.)

Fig.2 (a) Tip trajectories at four rfb1; (b) Attractor radius rtip as a function of inner radius rfb1 of a annular measuring region under the control of the feedback signal

Fig.3 (a) Tip trajectories at five h; (b) Variation of rtip with h under the control of a feedback signal

Fig.4 Spiral tip trajectiories under positive and negative gains (a) rfb1=28; (b) rfb1=30; (c) rfb1=40; (d) rfb1=42 (The black trajectories and point attractors are obtained under kfb=0.02, and the case of kfb=-0.02 is illustrated by red color.)

Fig.5 Effect of positive feedback gain on spiral dynamics

Fig.6 Effect of negative feedback gain on spiral dynamics(h=30 and rfb1=42) (a) kfb=-0.015; (b) kfb=-0.02; (c) kfb=-0.025; (d) kfb=-0.035

Fig.7 Transient drift tractories and modular functions of the complex feedback signal

Fig.8 Trajectories of the spiral tip at different dfb1

Fig.9 Trajectories of the spiral tip at different l (a) 2≤l≤20; (b) 21≤l≤46

Fig.10 Effect of kfb on drift trajectiory in the transient phase

Fig.11 Effect of negative feedback gain on spiral dynamics (dfb1=20, l=5) (a) kfb=-0.015; (b) kfb=-0.02; (c) kfb=-0.0225; (d) kfb=-0.025

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