Phase transition in one-dimensional excitable media with variable interaction range

Abstract

We investigate two discrete models of excitable media on a one-dimensional integer lattice Z: the -color Cyclic Cellular Automaton (CCA) and the -color Firefly Cellular Automaton (FCA). In both models, sites are assigned uniformly random colors from Z/. Neighboring sites with colors within a specified interaction range r tend to synchronize their colors upon a particular local event of 'excitation'. We establish that there are three phases of CCA/FCA on Z as we vary the interaction range r. First, if r is too small (undercoupled), there are too many non-interacting pairs of colors, and the whole graph Z will be partitioned into non-interacting intervals of sites with no excitation within each interval. If r is within a sweet spot (critical), then we show the system clusters into ever-growing monochromatic intervals. For the critical interaction range r= /2 , we show the density of edges of differing colors at time t is (t-1/2) and each site excites (t1/2) times up to time t. Lastly, if r is too large (overcoupled), then neighboring sites can excite each other and such 'defects' will generate waves of excitation at a constant rate so that each site will get excited at least at a linear rate. For the special case of FCA with r= 2/ +1, we show that every site will become (+1)-periodic eventually.