A complete approximation theory for weighted transition systems

Mikkel Hansen; Kim Guldstrand Larsen; Radu Mardare; Mathias Ruggaard Pedersen; Bingtian Xue

doi:10.1007/978-3-319-47677-3_14

A complete approximation theory for weighted transition systems

Mikkel Hansen
, Kim Guldstrand Larsen
, Radu Mardare
, Mathias Ruggaard Pedersen
, Bingtian Xue

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

2 Citations (Scopus)

Abstract

We propose a way of reasoning about minimal and maximal values of the weights of transitions in a weighted transition system (WTS). This perspective induces a notion of bisimulation that is coarser than the classic bisimulation: it relates states that exhibit transitions to bisimulation classes with the weights within the same boundaries. We propose a customized modal logic that expresses these numeric boundaries for transition weights by means of particular modalities. We prove that our logic is invariant under the proposed notion of bisimulation. We show that the logic enjoys the finite model property which allows us to prove the decidability of satisfiability and provide an algorithm for satisfiability checking. Last but not least, we identify a complete axiomatization for this logic, thus solving a long-standing open problem in this field. All our results are proven for a class of WTSs without the image-finiteness restriction, a fact that makes this development general and robust.

Original language	English
Title of host publication	Dependable Software Engineering: Theories, Tools, and Applications
Subtitle of host publication	Second International Symposium, SETTA 2016, Beijing, China, November 9-11, 2016, Proceedings
Editors	Martin Fränzle, Deepak Kapur, Naijun Zhan
Publisher	Springer
Pages	213-228
Number of pages	16
Volume	9984
ISBN (Electronic)	978-3-319-47677-3
ISBN (Print)	978-3-319-47676-6
DOIs	https://doi.org/10.1007/978-3-319-47677-3_14
Publication status	Published - 6 Oct 2016

Publication series

Name	Lecture Notes in Computer Science
ISSN (Print)	0302-9743

Keywords

modal logic
axiomatic system
finite model
complete axiomatization
arbitrary formula

Access to Document

10.1007/978-3-319-47677-3_14

https://www.scopus.com/pages/publications/84994515747

Cite this

Hansen, M., Larsen, K. G., Mardare, R., Pedersen, M. R., & Xue, B. (2016). A complete approximation theory for weighted transition systems. In M. Fränzle, D. Kapur, & N. Zhan (Eds.), Dependable Software Engineering: Theories, Tools, and Applications: Second International Symposium, SETTA 2016, Beijing, China, November 9-11, 2016, Proceedings (Vol. 9984, pp. 213-228). (Lecture Notes in Computer Science). Springer. https://doi.org/10.1007/978-3-319-47677-3_14

Hansen, Mikkel ; Larsen, Kim Guldstrand ; Mardare, Radu et al. / A complete approximation theory for weighted transition systems. Dependable Software Engineering: Theories, Tools, and Applications: Second International Symposium, SETTA 2016, Beijing, China, November 9-11, 2016, Proceedings. editor / Martin Fränzle ; Deepak Kapur ; Naijun Zhan. Vol. 9984 Springer, 2016. pp. 213-228 (Lecture Notes in Computer Science).

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title = "A complete approximation theory for weighted transition systems",

abstract = "We propose a way of reasoning about minimal and maximal values of the weights of transitions in a weighted transition system (WTS). This perspective induces a notion of bisimulation that is coarser than the classic bisimulation: it relates states that exhibit transitions to bisimulation classes with the weights within the same boundaries. We propose a customized modal logic that expresses these numeric boundaries for transition weights by means of particular modalities. We prove that our logic is invariant under the proposed notion of bisimulation. We show that the logic enjoys the finite model property which allows us to prove the decidability of satisfiability and provide an algorithm for satisfiability checking. Last but not least, we identify a complete axiomatization for this logic, thus solving a long-standing open problem in this field. All our results are proven for a class of WTSs without the image-finiteness restriction, a fact that makes this development general and robust.",

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author = "Mikkel Hansen and Larsen, \{Kim Guldstrand\} and Radu Mardare and Pedersen, \{Mathias Ruggaard\} and Bingtian Xue",

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Hansen, M, Larsen, KG, Mardare, R, Pedersen, MR & Xue, B 2016, A complete approximation theory for weighted transition systems. in M Fränzle, D Kapur & N Zhan (eds), Dependable Software Engineering: Theories, Tools, and Applications: Second International Symposium, SETTA 2016, Beijing, China, November 9-11, 2016, Proceedings. vol. 9984, Lecture Notes in Computer Science, Springer, pp. 213-228. https://doi.org/10.1007/978-3-319-47677-3_14

A complete approximation theory for weighted transition systems. / Hansen, Mikkel; Larsen, Kim Guldstrand; Mardare, Radu et al.
Dependable Software Engineering: Theories, Tools, and Applications: Second International Symposium, SETTA 2016, Beijing, China, November 9-11, 2016, Proceedings. ed. / Martin Fränzle; Deepak Kapur; Naijun Zhan. Vol. 9984 Springer, 2016. p. 213-228 (Lecture Notes in Computer Science).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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T1 - A complete approximation theory for weighted transition systems

AU - Hansen, Mikkel

AU - Larsen, Kim Guldstrand

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AU - Pedersen, Mathias Ruggaard

AU - Xue, Bingtian

PY - 2016/10/6

Y1 - 2016/10/6

N2 - We propose a way of reasoning about minimal and maximal values of the weights of transitions in a weighted transition system (WTS). This perspective induces a notion of bisimulation that is coarser than the classic bisimulation: it relates states that exhibit transitions to bisimulation classes with the weights within the same boundaries. We propose a customized modal logic that expresses these numeric boundaries for transition weights by means of particular modalities. We prove that our logic is invariant under the proposed notion of bisimulation. We show that the logic enjoys the finite model property which allows us to prove the decidability of satisfiability and provide an algorithm for satisfiability checking. Last but not least, we identify a complete axiomatization for this logic, thus solving a long-standing open problem in this field. All our results are proven for a class of WTSs without the image-finiteness restriction, a fact that makes this development general and robust.

AB - We propose a way of reasoning about minimal and maximal values of the weights of transitions in a weighted transition system (WTS). This perspective induces a notion of bisimulation that is coarser than the classic bisimulation: it relates states that exhibit transitions to bisimulation classes with the weights within the same boundaries. We propose a customized modal logic that expresses these numeric boundaries for transition weights by means of particular modalities. We prove that our logic is invariant under the proposed notion of bisimulation. We show that the logic enjoys the finite model property which allows us to prove the decidability of satisfiability and provide an algorithm for satisfiability checking. Last but not least, we identify a complete axiomatization for this logic, thus solving a long-standing open problem in this field. All our results are proven for a class of WTSs without the image-finiteness restriction, a fact that makes this development general and robust.

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Hansen M, Larsen KG, Mardare R, Pedersen MR, Xue B. A complete approximation theory for weighted transition systems. In Fränzle M, Kapur D, Zhan N, editors, Dependable Software Engineering: Theories, Tools, and Applications: Second International Symposium, SETTA 2016, Beijing, China, November 9-11, 2016, Proceedings. Vol. 9984. Springer. 2016. p. 213-228. (Lecture Notes in Computer Science). doi: 10.1007/978-3-319-47677-3_14

A complete approximation theory for weighted transition systems

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