In this study, we examine the notion of atomicity property in fully asynchronous cellular automata where two neighboring cells are not allowed to get updated together. In this direction, after breaking the assumption of atomicity property, we introduce the Formula: see text-skewed asynchronous updating scheme where we allow Formula: see text number of neighboring cells to get updated together for Formula: see text. As a special case, Formula: see text reports the fully asynchronous update, and Formula: see text shows the traditional synchronous update. Here, we classify the dynamics of Elementary Cellular Automata (ECA) under Formula: see text-skewed updating scheme following a qualitative (i.e. space–time diagram) and quantitative (i.e. density, activity, Kolmogorov–Sinai entropy) experimental approach. According to the results, some ECA rules show strong resistance against this Formula: see text-skewed perturbation. However, most ECA rules report abrupt phase transition (i.e. discontinuity), continuous phase transition, and class transition dynamics. Next, based on the two-dimensional density surface, we classify the phase transition dynamics of the ECA system. To understand the abrupt phase change in the microscopic view, we further introduce the notion of a correlated Formula: see text-skewed updating scheme. Moreover, we compare the phase transition dynamics of the Formula: see text-skewed system with Formula: see text-asynchronous cellular automata. Apart from the phase transition dynamics, here, the Formula: see text-skewed system reports a variety of the following class transition dynamics: (a) There are situations where a simple locally chaotic rule can show chaotic dynamics with the effect of Formula: see text-skewed perturbation; (b) Similarly, a chaotic rule is capable of generating simple periodic or fixed point dynamics with the effect of this Formula: see text-skewed perturbation.
Roy et al. (Thu,) studied this question.