Difference between revisions of "Publications/baier.19.atva"
From LRDE
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| title = Generic Emptiness Check for Fun and Profit |
| title = Generic Emptiness Check for Fun and Profit |
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| booktitle = Proceedings of the 17th International Symposium on Automated Technology for Verification and Analysis (ATVA'19) |
| booktitle = Proceedings of the 17th International Symposium on Automated Technology for Verification and Analysis (ATVA'19) |
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− | | volume = |
+ | | volume = 11781 |
| series = Lecture Notes in Computer Science |
| series = Lecture Notes in Computer Science |
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− | | pages = |
+ | | pages = 445 to 461 |
| publisher = Springer |
| publisher = Springer |
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− | | note = To appear |
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| abstract = We present a new algorithm for checking the emptiness of <math>\omega</math>-automata with an Emerson-Lei acceptance condition (i.e., a positive Boolean formula over sets of states or transitions that must be visited infinitely or finitely often). The algorithm can also solve the model checking problem of probabilistic positiveness of MDP under a property given as a deterministic Emerson-Lei automaton. Although both these problems are known to be NP-complete and our algorithm is exponential in general, it runs in polynomial time for simpler acceptance conditions like generalized Rabin, Streett, or parity. In fact, the algorithm provides a unifying view on emptiness checks for these simpler automata classes. We have implemented the algorithm in Spot and PRISM and our experiments show improved performance over previous solutions. |
| abstract = We present a new algorithm for checking the emptiness of <math>\omega</math>-automata with an Emerson-Lei acceptance condition (i.e., a positive Boolean formula over sets of states or transitions that must be visited infinitely or finitely often). The algorithm can also solve the model checking problem of probabilistic positiveness of MDP under a property given as a deterministic Emerson-Lei automaton. Although both these problems are known to be NP-complete and our algorithm is exponential in general, it runs in polynomial time for simpler acceptance conditions like generalized Rabin, Streett, or parity. In fact, the algorithm provides a unifying view on emptiness checks for these simpler automata classes. We have implemented the algorithm in Spot and PRISM and our experiments show improved performance over previous solutions. |
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| lrdekeywords = Spot |
| lrdekeywords = Spot |
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| type = inproceedings |
| type = inproceedings |
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| id = baier.19.atva |
| id = baier.19.atva |
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+ | | identifier = doi:10.1007/978-3-030-31784-3_26 |
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| bibtex = |
| bibtex = |
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@InProceedings<nowiki>{</nowiki> baier.19.atva, |
@InProceedings<nowiki>{</nowiki> baier.19.atva, |
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(ATVA'19)<nowiki>}</nowiki>, |
(ATVA'19)<nowiki>}</nowiki>, |
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year = <nowiki>{</nowiki>2019<nowiki>}</nowiki>, |
year = <nowiki>{</nowiki>2019<nowiki>}</nowiki>, |
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− | volume = <nowiki>{</nowiki> |
+ | volume = <nowiki>{</nowiki>11781<nowiki>}</nowiki>, |
series = <nowiki>{</nowiki>Lecture Notes in Computer Science<nowiki>}</nowiki>, |
series = <nowiki>{</nowiki>Lecture Notes in Computer Science<nowiki>}</nowiki>, |
||
− | pages = <nowiki>{</nowiki> |
+ | pages = <nowiki>{</nowiki>445--461<nowiki>}</nowiki>, |
month = oct, |
month = oct, |
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publisher = <nowiki>{</nowiki>Springer<nowiki>}</nowiki>, |
publisher = <nowiki>{</nowiki>Springer<nowiki>}</nowiki>, |
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⚫ | |||
abstract = <nowiki>{</nowiki>We present a new algorithm for checking the emptiness of |
abstract = <nowiki>{</nowiki>We present a new algorithm for checking the emptiness of |
||
$\omega$-automata with an Emerson-Lei acceptance condition |
$\omega$-automata with an Emerson-Lei acceptance condition |
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these simpler automata classes. We have implemented the |
these simpler automata classes. We have implemented the |
||
algorithm in Spot and PRISM and our experiments show |
algorithm in Spot and PRISM and our experiments show |
||
− | improved performance over previous solutions.<nowiki>}</nowiki> |
+ | improved performance over previous solutions.<nowiki>}</nowiki>, |
⚫ | |||
<nowiki>}</nowiki> |
<nowiki>}</nowiki> |
||
Latest revision as of 13:05, 8 November 2019
- Authors
- Christel Baier, František Blahoudek, Alexandre Duret-Lutz, Joachim Klein, David Müller, Jan Strejček
- Where
- Proceedings of the 17th International Symposium on Automated Technology for Verification and Analysis (ATVA'19)
- Type
- inproceedings
- Publisher
- Springer
- Keywords
- Spot
- Date
- 2019-07-29
Abstract
We present a new algorithm for checking the emptiness of -automata with an Emerson-Lei acceptance condition (i.e., a positive Boolean formula over sets of states or transitions that must be visited infinitely or finitely often). The algorithm can also solve the model checking problem of probabilistic positiveness of MDP under a property given as a deterministic Emerson-Lei automaton. Although both these problems are known to be NP-complete and our algorithm is exponential in general, it runs in polynomial time for simpler acceptance conditions like generalized Rabin, Streett, or parity. In fact, the algorithm provides a unifying view on emptiness checks for these simpler automata classes. We have implemented the algorithm in Spot and PRISM and our experiments show improved performance over previous solutions.
Documents
Bibtex (lrde.bib)
@InProceedings{ baier.19.atva, author = {Christel Baier and Franti\v{s}ek Blahoudek and Alexandre Duret-Lutz and Joachim Klein and David M\"uller and Jan Strej\v{c}ek}, title = {Generic Emptiness Check for Fun and Profit}, booktitle = {Proceedings of the 17th International Symposium on Automated Technology for Verification and Analysis (ATVA'19)}, year = {2019}, volume = {11781}, series = {Lecture Notes in Computer Science}, pages = {445--461}, month = oct, publisher = {Springer}, abstract = {We present a new algorithm for checking the emptiness of $\omega$-automata with an Emerson-Lei acceptance condition (i.e., a positive Boolean formula over sets of states or transitions that must be visited infinitely or finitely often). The algorithm can also solve the model checking problem of probabilistic positiveness of MDP under a property given as a deterministic Emerson-Lei automaton. Although both these problems are known to be NP-complete and our algorithm is exponential in general, it runs in polynomial time for simpler acceptance conditions like generalized Rabin, Streett, or parity. In fact, the algorithm provides a unifying view on emptiness checks for these simpler automata classes. We have implemented the algorithm in Spot and PRISM and our experiments show improved performance over previous solutions.}, doi = {10.1007/978-3-030-31784-3_26} }