Shift-Symmetric Configurations in Two-Dimensional Cellular Automata: Irreversibility, Insolvability, and Enumeration
Peter Banda, John Caughman, Martin Cenek, and Christof Teuscher

TL;DR
This paper investigates shift-symmetric configurations in two-dimensional cellular automata using group theory, revealing universal insolvability of key distributed tasks and providing enumeration formulas and algorithms for detecting symmetry.
Contribution
It introduces a group-theoretic approach to analyze shift-symmetry in cellular automata, offering enumeration formulas, probability calculations, and symmetry detection algorithms.
Findings
Universal insolvability of leader election, pattern recognition, hashing, and encryption.
Efficient formulas for enumerating shift-symmetric configurations.
An algorithm for detecting shift-symmetry in configurations.
Abstract
The search for symmetry as an unusual yet profoundly appealing phenomenon, and the origin of regular, repeating configuration patterns have long been a central focus of complexity science and physics. To better grasp and understand symmetry of configurations in decentralized toroidal architectures, we employ group-theoretic methods, which allow us to identify and enumerate these inputs, and argue about irreversible system behaviors with undesired effects on many computational problems. The concept of so-called configuration shift-symmetry is applied to two-dimensional cellular automata as an ideal model of computation. Regardless of the transition function, the results show the universal insolvability of crucial distributed tasks, such as leader election, pattern recognition, hashing, and encryption. By using compact enumeration formulas and bounding the number of shift-symmetric…
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