On the complexity of two-dimensional signed majority cellular automata

Eric Goles; Pedro Montealegre; Kévin Perrot; Guillaume Theyssier

doi:10.1016/j.jcss.2017.07.010

On the complexity of two-dimensional signed majority cellular automata

Eric Goles
, Pedro Montealegre
, Kévin Perrot
, Guillaume Theyssier

Facultad de Ingeniería y Ciencias

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

17 Citas (Scopus)

Resumen

We study the complexity of signed majority cellular automata on the planar grid. We show that, depending on their symmetry and uniformity, they can simulate different types of logical circuitry under different modes. We use this to establish new bounds on their overall complexity, concretely: the uniform asymmetric and the non-uniform symmetric rules are Turing universal and have a P-complete prediction problem; the non-uniform asymmetric rule is intrinsically universal; no symmetric rule can be intrinsically universal. We also show that the uniform asymmetric rules exhibit cycles of super-polynomial length, whereas symmetric ones are known to have bounded cycle length.

Idioma original	Inglés
Páginas (desde-hasta)	1-32
Número de páginas	32
Publicación	Journal of Computer and System Sciences
Volumen	91
DOI	https://doi.org/10.1016/j.jcss.2017.07.010
Estado	Publicada - feb. 2018

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title = "On the complexity of two-dimensional signed majority cellular automata",

abstract = "We study the complexity of signed majority cellular automata on the planar grid. We show that, depending on their symmetry and uniformity, they can simulate different types of logical circuitry under different modes. We use this to establish new bounds on their overall complexity, concretely: the uniform asymmetric and the non-uniform symmetric rules are Turing universal and have a P-complete prediction problem; the non-uniform asymmetric rule is intrinsically universal; no symmetric rule can be intrinsically universal. We also show that the uniform asymmetric rules exhibit cycles of super-polynomial length, whereas symmetric ones are known to have bounded cycle length.",

keywords = "Cellular automata dynamics, Computational complexity, Intrinsic universal, Majority cellular automata, Signed two-dimensional lattice, Turing universal",

author = "Eric Goles and Pedro Montealegre and K{\'e}vin Perrot and Guillaume Theyssier",

note = "Publisher Copyright: {\textcopyright} 2017 Elsevier Inc.",

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doi = "10.1016/j.jcss.2017.07.010",

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AU - Goles, Eric

AU - Montealegre, Pedro

AU - Perrot, Kévin

AU - Theyssier, Guillaume

PY - 2018/2

Y1 - 2018/2

N2 - We study the complexity of signed majority cellular automata on the planar grid. We show that, depending on their symmetry and uniformity, they can simulate different types of logical circuitry under different modes. We use this to establish new bounds on their overall complexity, concretely: the uniform asymmetric and the non-uniform symmetric rules are Turing universal and have a P-complete prediction problem; the non-uniform asymmetric rule is intrinsically universal; no symmetric rule can be intrinsically universal. We also show that the uniform asymmetric rules exhibit cycles of super-polynomial length, whereas symmetric ones are known to have bounded cycle length.

AB - We study the complexity of signed majority cellular automata on the planar grid. We show that, depending on their symmetry and uniformity, they can simulate different types of logical circuitry under different modes. We use this to establish new bounds on their overall complexity, concretely: the uniform asymmetric and the non-uniform symmetric rules are Turing universal and have a P-complete prediction problem; the non-uniform asymmetric rule is intrinsically universal; no symmetric rule can be intrinsically universal. We also show that the uniform asymmetric rules exhibit cycles of super-polynomial length, whereas symmetric ones are known to have bounded cycle length.

KW - Cellular automata dynamics

KW - Computational complexity

KW - Intrinsic universal

KW - Majority cellular automata

KW - Signed two-dimensional lattice

KW - Turing universal

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SP - 1

EP - 32

JO - Journal of Computer and System Sciences

JF - Journal of Computer and System Sciences

ER -

On the complexity of two-dimensional signed majority cellular automata

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