Steady-state stabilization due to random delays in maps with self-feedback loops and in globally delayed-coupled maps
Abstract
We study the stability of the fixed-point solution of an array of mutually coupled logistic maps, focusing on the influence of the delay times, τij, of the interaction between the ith and jth maps. Two of us recently reported [Phys. Rev. Lett. 94, 134102 (2005)] that if τij are random enough the array synchronizes in a spatially homogeneous steady state. Here we study this behavior by comparing the dynamics of a map of an array of N delayed-coupled maps with the dynamics of a map with N self-feedback delayed loops. If N is sufficiently large, the dynamics of a map of the array is similar to the dynamics of a map with self-feedback loops with the same delay times. Several delayed loops stabilize the fixed point, when the delays are not the same; however, the distribution of delays plays a key role: if the delays are all odd a periodic orbit (and not the fixed point) is stabilized. We present a linear stability analysis and apply some mathematical theorems that explain the numerical results.
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