# Von Neumann Regular Cellular Automata

**Authors:** Alonso Castillo-Ramirez, Maximilien Gadouleau

arXiv: 1701.02692 · 2017-05-29

## TL;DR

This paper explores the algebraic structure of cellular automata, characterizing when they are von Neumann regular and examining properties of regular automata over different groups and vector spaces.

## Contribution

It provides a complete characterization of regular cellular automata in the monoid 	ext{CA}(G;A), including conditions for regularity and invertibility in linear cases.

## Key findings

- 	ext{CA}(G;A) is regular iff |G|=1 or |A|=1.
- All regular linear CA are invertible when G is torsion-free elementary amenable.
- Every linear CA is regular if V is finite-dimensional and G is locally finite.

## Abstract

For any group $G$ and any set $A$, a cellular automaton (CA) is a transformation of the configuration space $A^G$ defined via a finite memory set and a local function. Let $\text{CA}(G;A)$ be the monoid of all CA over $A^G$. In this paper, we investigate a generalisation of the inverse of a CA from the semigroup-theoretic perspective. An element $\tau \in \text{CA}(G;A)$ is von Neumann regular (or simply regular) if there exists $\sigma \in \text{CA}(G;A)$ such that $\tau \circ \sigma \circ \tau = \tau$ and $\sigma \circ \tau \circ \sigma = \sigma$, where $\circ$ is the composition of functions. Such an element $\sigma$ is called a generalised inverse of $\tau$. The monoid $\text{CA}(G;A)$ itself is regular if all its elements are regular. We establish that $\text{CA}(G;A)$ is regular if and only if $\vert G \vert = 1$ or $\vert A \vert = 1$, and we characterise all regular elements in $\text{CA}(G;A)$ when $G$ and $A$ are both finite. Furthermore, we study regular linear CA when $A= V$ is a vector space over a field $\mathbb{F}$; in particular, we show that every regular linear CA is invertible when $G$ is torsion-free elementary amenable (e.g. when $G=\mathbb{Z}^d, \ d \in \mathbb{N}$) and $V=\mathbb{F}$, and that every linear CA is regular when $V$ is finite-dimensional and $G$ is locally finite with $\text{Char}(\mathbb{F}) \nmid o(g)$ for all $g \in G$.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1701.02692/full.md

## Figures

1 figure with captions in the complete paper: https://tomesphere.com/paper/1701.02692/full.md

## References

15 references — full list in the complete paper: https://tomesphere.com/paper/1701.02692/full.md

---
Source: https://tomesphere.com/paper/1701.02692