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Affine Parikh automata∗

Michaël Cadilhac; Alain Finkel; Pierre McKenzie

RAIRO - Theoretical Informatics and Applications (2012)

  • Volume: 46, Issue: 4, page 511-545
  • ISSN: 0988-3754

Abstract

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The Parikh finite word automaton (PA) was introduced and studied in 2003 by Klaedtke and Rueß. Natural variants of the PA arise from viewing a PA equivalently as an automaton that keeps a count of its transitions and semilinearly constrains their numbers. Here we adopt this view and define the affine PA, that extends the PA by having each transition induce an affine transformation on the PA registers, and the PA on letters, that restricts the PA by forcing any two transitions on the same letter to affect the registers equally. Then we report on the expressiveness, closure, and decidability properties of such PA variants. We note that deterministic PA are strictly weaker than deterministic reversal-bounded counter machines.

How to cite

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Cadilhac, Michaël, Finkel, Alain, and McKenzie, Pierre. "Affine Parikh automata∗." RAIRO - Theoretical Informatics and Applications 46.4 (2012): 511-545. <http://eudml.org/doc/277829>.

@article{Cadilhac2012,
abstract = {The Parikh finite word automaton (PA) was introduced and studied in 2003 by Klaedtke and Rueß. Natural variants of the PA arise from viewing a PA equivalently as an automaton that keeps a count of its transitions and semilinearly constrains their numbers. Here we adopt this view and define the affine PA, that extends the PA by having each transition induce an affine transformation on the PA registers, and the PA on letters, that restricts the PA by forcing any two transitions on the same letter to affect the registers equally. Then we report on the expressiveness, closure, and decidability properties of such PA variants. We note that deterministic PA are strictly weaker than deterministic reversal-bounded counter machines.},
author = {Cadilhac, Michaël, Finkel, Alain, McKenzie, Pierre},
journal = {RAIRO - Theoretical Informatics and Applications},
keywords = {Automata; semilinear sets; affine functions; counter machines; automata},
language = {eng},
month = {11},
number = {4},
pages = {511-545},
publisher = {EDP Sciences},
title = {Affine Parikh automata∗},
url = {http://eudml.org/doc/277829},
volume = {46},
year = {2012},
}

TY - JOUR
AU - Cadilhac, Michaël
AU - Finkel, Alain
AU - McKenzie, Pierre
TI - Affine Parikh automata∗
JO - RAIRO - Theoretical Informatics and Applications
DA - 2012/11//
PB - EDP Sciences
VL - 46
IS - 4
SP - 511
EP - 545
AB - The Parikh finite word automaton (PA) was introduced and studied in 2003 by Klaedtke and Rueß. Natural variants of the PA arise from viewing a PA equivalently as an automaton that keeps a count of its transitions and semilinearly constrains their numbers. Here we adopt this view and define the affine PA, that extends the PA by having each transition induce an affine transformation on the PA registers, and the PA on letters, that restricts the PA by forcing any two transitions on the same letter to affect the registers equally. Then we report on the expressiveness, closure, and decidability properties of such PA variants. We note that deterministic PA are strictly weaker than deterministic reversal-bounded counter machines.
LA - eng
KW - Automata; semilinear sets; affine functions; counter machines; automata
UR - http://eudml.org/doc/277829
ER -

References

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