A Game Theoretical Approach to The Algebraic Counterpart of The Wagner Hierarchy : Part II

Jérémie Cabessa; Jacques Duparc

RAIRO - Theoretical Informatics and Applications (2009)

  • Volume: 43, Issue: 3, page 463-515
  • ISSN: 0988-3754

Abstract

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The algebraic counterpart of the Wagner hierarchy consists of a well-founded and decidable classification of finite pointed ω-semigroups of width 2 and height ωω. This paper completes the description of this algebraic hierarchy. We first give a purely algebraic decidability procedure of this partial ordering by introducing a graph representation of finite pointed ω-semigroups allowing to compute their precise Wagner degrees. The Wagner degree of any ω-rational language can therefore be computed directly on its syntactic image. We then show how to build a finite pointed ω-semigroup of any given Wagner degree. We finally describe the algebraic invariants characterizing every degree of this hierarchy.

How to cite

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Cabessa, Jérémie, and Duparc, Jacques. "A Game Theoretical Approach to The Algebraic Counterpart of The Wagner Hierarchy : Part II." RAIRO - Theoretical Informatics and Applications 43.3 (2009): 463-515. <http://eudml.org/doc/250608>.

@article{Cabessa2009,
abstract = { The algebraic counterpart of the Wagner hierarchy consists of a well-founded and decidable classification of finite pointed ω-semigroups of width 2 and height ωω. This paper completes the description of this algebraic hierarchy. We first give a purely algebraic decidability procedure of this partial ordering by introducing a graph representation of finite pointed ω-semigroups allowing to compute their precise Wagner degrees. The Wagner degree of any ω-rational language can therefore be computed directly on its syntactic image. We then show how to build a finite pointed ω-semigroup of any given Wagner degree. We finally describe the algebraic invariants characterizing every degree of this hierarchy. },
author = {Cabessa, Jérémie, Duparc, Jacques},
journal = {RAIRO - Theoretical Informatics and Applications},
keywords = {ω-automata; ω-rational languages; ω-semigroups; infinite games; hierarchical games; Wadge game; Wadge hierarchy; Wagner hierarchy.; -automata; -rational languages; -semigroups; Wagner hierarchy},
language = {eng},
month = {3},
number = {3},
pages = {463-515},
publisher = {EDP Sciences},
title = {A Game Theoretical Approach to The Algebraic Counterpart of The Wagner Hierarchy : Part II},
url = {http://eudml.org/doc/250608},
volume = {43},
year = {2009},
}

TY - JOUR
AU - Cabessa, Jérémie
AU - Duparc, Jacques
TI - A Game Theoretical Approach to The Algebraic Counterpart of The Wagner Hierarchy : Part II
JO - RAIRO - Theoretical Informatics and Applications
DA - 2009/3//
PB - EDP Sciences
VL - 43
IS - 3
SP - 463
EP - 515
AB - The algebraic counterpart of the Wagner hierarchy consists of a well-founded and decidable classification of finite pointed ω-semigroups of width 2 and height ωω. This paper completes the description of this algebraic hierarchy. We first give a purely algebraic decidability procedure of this partial ordering by introducing a graph representation of finite pointed ω-semigroups allowing to compute their precise Wagner degrees. The Wagner degree of any ω-rational language can therefore be computed directly on its syntactic image. We then show how to build a finite pointed ω-semigroup of any given Wagner degree. We finally describe the algebraic invariants characterizing every degree of this hierarchy.
LA - eng
KW - ω-automata; ω-rational languages; ω-semigroups; infinite games; hierarchical games; Wadge game; Wadge hierarchy; Wagner hierarchy.; -automata; -rational languages; -semigroups; Wagner hierarchy
UR - http://eudml.org/doc/250608
ER -

References

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