(Page 0025) This pattern is however again fairly simple. And we might assume that at least with the type of cellular automata that we are considering, any rule we might ...

(Page 0200) the network. In the first case, the connections from the new node are exactly the same as the connections from the existing node, while in the second case, the ...

(Page 0360) samples just the first cell in every 14×7 block of cells, making each domain of repetitive behavior stand out as having a uniform color. In the detailed behavior ...

(Page 0464) The pictures above then show how the average density evolves in systems (c) and (d). And what is striking is that even though at the lowest level both of these ...

(Page 0949d) Notes for: Starting from Randomness | Sensitivity to Initial Conditions Properties [of difference patterns] In rule 126, the outer edges of the region of change ...

(Page 1079b) Notes for: Processes of Perception and Analysis | Auditory Perception Auditory system Sound is detected by the motion it causes in hair cells in the cochlea of ...

(Page 0029) [No text on this page] Captions on this page: Five hundred steps in the evolution of the rule 30 cellular automaton from page 27 . The pattern produced continues ...

(Page 0182) [No text on this page] Captions on this page: Examples of three-dimensional cellular automata. In the top set of pictures, the rule specifies that a cell should ...

(Page 0248) [No text on this page] Captions on this page: One-dimensional slices through the evolution of various two-dimensional cellular automata. In each picture black ...

(Page 0283) [No text on this page] Captions on this page: The behavior of the code 20 cellular automaton from the top of the facing page for all initial conditions with black ...