Difference between revisions of "Publications/baarir.15.lpar"
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| volume = 9450 |
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| series = Lecture Notes in Computer Science |
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| − | | abstract = We describe a tool that inputs a deterministic |
+ | | abstract = We describe a tool that inputs a deterministic <math>\omega</math>-automaton with any acceptance condition, and synthesizes an equivalent <math>\omega</math>-automaton with another arbitrary acceptance condition and a given number of states, if such an automaton exists. This tool, that relies on a SAT-based encoding of the problem, can be used to provide minimal <math>\omega</math>-automata equivalent to given properties, for different acceptance conditions. |
| lrdeprojects = Spot |
| lrdeprojects = Spot |
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| lrdenewsdate = 2015-09-01 |
| lrdenewsdate = 2015-09-01 |
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Revision as of 19:19, 5 January 2018
- Authors
- Souheib Baarir, Alexandre Duret-Lutz
- Where
- Proceedings of the 20th International Conference on Logic for Programming, Artificial Intelligence, and Reasoning (LPAR'15)
- Type
- inproceedings
- Publisher
- Springer
- Projects
- Spot
- Date
- 2015-09-01
Abstract
We describe a tool that inputs a deterministic -automaton with any acceptance condition, and synthesizes an equivalent -automaton with another arbitrary acceptance condition and a given number of states, if such an automaton exists. This tool, that relies on a SAT-based encoding of the problem, can be used to provide minimal -automata equivalent to given properties, for different acceptance conditions.
Documents
Bibtex (lrde.bib)
@InProceedings{ baarir.15.lpar,
author = {Souheib Baarir and Alexandre Duret-Lutz},
booktitle = {Proceedings of the 20th International Conference on Logic
for Programming, Artificial Intelligence, and Reasoning
(LPAR'15)},
title = {{SAT}-based Minimization of Deterministic
$\omega$-Automata},
year = {2015},
month = nov,
pages = {79--87},
publisher = {Springer},
volume = {9450},
series = {Lecture Notes in Computer Science},
abstract = {We describe a tool that inputs a deterministic
$\omega$-automaton with any acceptance condition, and
synthesizes an equivalent $\omega$-automaton with another
arbitrary acceptance condition and a given number of
states, if such an automaton exists. This tool, that relies
on a SAT-based encoding of the problem, can be used to
provide minimal $\omega$-automata equivalent to given
properties, for different acceptance conditions.}
}