Your search keyword '"Sickert, Salomon"' showing total 22 results

1. A Simple Rewrite System for the Normalization of Linear Temporal Logic

Author

Esparza, Javier, Rubio, Ruben, Sickert, Salomon, Esparza, Javier, Rubio, Ruben, and Sickert, Salomon

Abstract

In the mid 80s, Lichtenstein, Pnueli, and Zuck showed that every formula of Past LTL (the extension of Linear Temporal Logic with past operators) is equivalent to a conjunction of formulas of the form $\mathbf{G}\mathbf{F} \varphi \vee \mathbf{F}\mathbf{G} \psi$, where $\varphi$ and $\psi$ contain only past operators. Some years later, Chang, Manna, and Pnueli derived a similar normal form for LTL. Both normalization procedures have a non-elementary worst-case blow-up, and follow an involved path from formulas to counter-free automata to star-free regular expressions and back to formulas. In 2020, Sickert and Esparza presented a direct and purely syntactic normalization procedure for LTL yielding a normal form similar to the one by Chang, Manna, and Pnueli, with a single exponential blow-up, and applied it to the problem of constructing a succinct deterministic $\omega$-automaton for a given formula. However, their procedure had exponential time complexity in the best case. In particular, it does not perform better for formulas that are almost in normal form. In this paper we present an alternative normalization procedure based on a simple set of rewrite rules.

Published

2023

2. Efficient Normalization of Linear Temporal Logic

Author

Esparza, Javier, Rubio, Rubén, Sickert, Salomon, Esparza, Javier, Rubio, Rubén, and Sickert, Salomon

Abstract

In the mid 80s, Lichtenstein, Pnueli, and Zuck proved a classical theorem stating that every formula of Past LTL (the extension of LTL with past operators) is equivalent to a formula of the form $\bigwedge_{i=1}^n \mathbf{G}\mathbf{F}\, \varphi_i \vee \mathbf{F}\mathbf{G}\, \psi_i $, where $\varphi_i$ and $\psi_i$ contain only past operators. Some years later, Chang, Manna, and Pnueli built on this result to derive a similar normal form for LTL. Both normalization procedures have a non-elementary worst-case blow-up, and follow an involved path from formulas to counter-free automata to star-free regular expressions and back to formulas. We improve on both points. We present direct and purely syntactic normalization procedures for LTL, yielding a normal form very similar to the one by Chang, Manna, and Pnueli, that exhibit only a single exponential blow-up. As an application, we derive a simple algorithm to translate LTL into deterministic Rabin automata. The algorithm normalizes the formula, translates it into a special very weak alternating automaton, and applies a simple determinization procedure, valid only for these special automata., Comment: Accepted in J. ACM. arXiv admin note: text overlap with arXiv:2304.08872, arXiv:2005.00472

Published

2023

3. The Reactive Synthesis Competition (SYNTCOMP): 2018-2021

Author

Jacobs, Swen, Perez, Guillermo, Abraham, Bruyere, Veronique, Cadilhac, Michael, Colange, Maximilien, Delfosse, Charly, Tom, van Dijk, Duret-Lutz, Alexandre, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Klara, Michaud, Thibaud, Pommellet, Adrien, Renkin, Florian, Schlehuber-Caissier, Philipp, Sakr, Mouhammad, Sickert, Salomon, Staquet, Gaetan, Tamines, Clement, Tentrup, Leander, Walker, Adam, Jacobs, Swen, Perez, Guillermo, Abraham, Bruyere, Veronique, Cadilhac, Michael, Colange, Maximilien, Delfosse, Charly, Tom, van Dijk, Duret-Lutz, Alexandre, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Klara, Michaud, Thibaud, Pommellet, Adrien, Renkin, Florian, Schlehuber-Caissier, Philipp, Sakr, Mouhammad, Sickert, Salomon, Staquet, Gaetan, Tamines, Clement, Tentrup, Leander, and Walker, Adam

Abstract

We report on the last four editions of the reactive synthesis competition (SYNTCOMP 2018-2021). We briefly describe the evaluation scheme and the experimental setup of SYNTCOMP. Then, we introduce new benchmark classes that have been added to the SYNTCOMP library and give an overview of the participants of SYNTCOMP. Finally, we present and analyze the results of our experimental evaluations, including a ranking of tools with respect to quantity and quality of solutions.

Published

2022

4. The Reactive Synthesis Competition (SYNTCOMP): 2018-2021

Author

Jacobs, Swen, Perez, Guillermo, Abraham, Bruyere, Veronique, Cadilhac, Michael, Colange, Maximilien, Delfosse, Charly, Tom, van Dijk, Duret-Lutz, Alexandre, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Klara, Michaud, Thibaud, Pommellet, Adrien, Renkin, Florian, Schlehuber-Caissier, Philipp, Sakr, Mouhammad, Sickert, Salomon, Staquet, Gaetan, Tamines, Clement, Tentrup, Leander, Walker, Adam, Jacobs, Swen, Perez, Guillermo, Abraham, Bruyere, Veronique, Cadilhac, Michael, Colange, Maximilien, Delfosse, Charly, Tom, van Dijk, Duret-Lutz, Alexandre, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Klara, Michaud, Thibaud, Pommellet, Adrien, Renkin, Florian, Schlehuber-Caissier, Philipp, Sakr, Mouhammad, Sickert, Salomon, Staquet, Gaetan, Tamines, Clement, Tentrup, Leander, and Walker, Adam

Abstract

We report on the last four editions of the reactive synthesis competition (SYNTCOMP 2018-2021). We briefly describe the evaluation scheme and the experimental setup of SYNTCOMP. Then, we introduce new benchmark classes that have been added to the SYNTCOMP library and give an overview of the participants of SYNTCOMP. Finally, we present and analyze the results of our experimental evaluations, including a ranking of tools with respect to quantity and quality of solutions.

Published

2022

5. On the Translation of Automata to Linear Temporal Logic

Author

Boker, Udi, Lehtinen, Karoliina, Sickert, Salomon, Boker, Udi, Lehtinen, Karoliina, and Sickert, Salomon

Abstract

While the complexity of translating future linear temporal logic (LTL) into automata on infinite words is well-understood, the size increase involved in turning automata back to LTL is not. In particular, there is no known elementary bound on the complexity of translating deterministic $\omega$-regular automata to LTL. Our first contribution consists of tight bounds for LTL over a unary alphabet: alternating, nondeterministic and deterministic automata can be exactly exponentially, quadratically and linearly more succinct, respectively, than any equivalent LTL formula. Our main contribution consists of a translation of general counter-free deterministic $\omega$-regular automata into LTL formulas of double exponential temporal-nesting depth and triple exponential length, using an intermediate Krohn-Rhodes cascade decomposition of the automaton. To our knowledge, this is the first elementary bound on this translation. Furthermore, our translation preserves the acceptance condition of the automaton in the sense that it turns a looping, weak, B\"uchi, coB\"uchi or Muller automaton into a formula that belongs to the matching class of the syntactic future hierarchy. In particular, it can be used to translate an LTL formula recognising a safety language to a formula belonging to the safety fragment of LTL (over both finite and infinite words)., Comment: Full version with appendix of a chapter with the same title that appears in the FoSSaCS 2022 conference proceedings

Published

2022

6. The Reactive Synthesis Competition (SYNTCOMP): 2018-2021

Author

Jacobs, Swen, Perez, Guillermo A., Abraham, Remco, Bruyere, Veronique, Cadilhac, Michael, Colange, Maximilien, Delfosse, Charly, van Dijk, Tom, Duret-Lutz, Alexandre, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Klara, Michaud, Thibaud, Pommellet, Adrien, Renkin, Florian, Schlehuber-Caissier, Philipp, Sakr, Mouhammad, Sickert, Salomon, Staquet, Gaetan, Tamines, Clement, Tentrup, Leander, Walker, Adam, Jacobs, Swen, Perez, Guillermo A., Abraham, Remco, Bruyere, Veronique, Cadilhac, Michael, Colange, Maximilien, Delfosse, Charly, van Dijk, Tom, Duret-Lutz, Alexandre, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Klara, Michaud, Thibaud, Pommellet, Adrien, Renkin, Florian, Schlehuber-Caissier, Philipp, Sakr, Mouhammad, Sickert, Salomon, Staquet, Gaetan, Tamines, Clement, Tentrup, Leander, and Walker, Adam

Abstract

We report on the last four editions of the reactive synthesis competition (SYNTCOMP 2018-2021). We briefly describe the evaluation scheme and the experimental setup of SYNTCOMP. Then, we introduce new benchmark classes that have been added to the SYNTCOMP library and give an overview of the participants of SYNTCOMP. Finally, we present and analyze the results of our experimental evaluations, including a ranking of tools with respect to quantity and quality - that is, the total size in terms of logic and memory elements - of solutions., Comment: accepted for publication in STTT

Published

2022

7. From linear temporal logic and limit-deterministic Büchi automata to deterministic parity automata

Author

Esparza, Javier, Křetínský, Jan, Raskin, Jean-François, Sickert, Salomon, Esparza, Javier, Křetínský, Jan, Raskin, Jean-François, and Sickert, Salomon

Abstract

Controller synthesis for general linear temporal logic (LTL) objectives is a challenging task. The standard approach involves translating the LTL objective into a deterministic parity automaton (DPA) by means of the Safra-Piterman construction. One of the challenges is the size of the DPA, which often grows very fast in practice, and can reach double exponential size in the length of the LTL formula. In this paper, we describe a single exponential translation from limit-deterministic Büchi automata (LDBA) to DPA and show that it can be concatenated with a recent efficient translations from LTL to LDBA to yield a double exponential, ‘Safraless’ LTL-to-DPA construction. We also report on an implementation and a comparison with other LTL-to-DPA translations on several sets of formulas from the literature., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2022

8. Certifying DFA Bounds for Recognition and Separation

Author

Kupferman, Orna, Lavee, Nir, Sickert, Salomon, Kupferman, Orna, Lavee, Nir, and Sickert, Salomon

Abstract

The automation of decision procedures makes certification essential. We suggest to use determinacy of turn-based two-player games with regular winning conditions in order to generate certificates for the number of states that a deterministic finite automaton (DFA) needs in order to recognize a given language. Given a language $L$ and a bound $k$, recognizability of $L$ by a DFA with $k$ states is reduced to a game between Prover and Refuter. The interaction along the game then serves as a certificate. Certificates generated by Prover are minimal DFAs. Certificates generated by Refuter are faulty attempts to define the required DFA. We compare the length of offline certificates, which are generated with no interaction between Prover and Refuter, and online certificates, which are based on such an interaction, and are thus shorter. We show that our approach is useful also for certification of separability of regular languages by a DFA of a given size. Unlike DFA minimization, which can be solved in polynomial time, separation is NP-complete, and thus the certification approach is essential. In addition, we prove NP-completeness of a strict version of separation., Comment: This is the full version of an article with the same title that appears in the ATVA 2021 conference proceedings. The final authenticated publication is available online at https://doi.org/[not-yet-existing-DOI]

Published

2021

9. Certifying Inexpressibility

Author

Kupferman, Orna, Sickert, Salomon, Kupferman, Orna, and Sickert, Salomon

Abstract

Different classes of automata on infinite words have different expressive power. Deciding whether a given language $L \subseteq \Sigma^\omega$ can be expressed by an automaton of a desired class can be reduced to deciding a game between Prover and Refuter: in each turn of the game, Refuter provides a letter in $\Sigma$, and Prover responds with an annotation of the current state of the run (for example, in the case of B\"uchi automata, whether the state is accepting or rejecting, and in the case of parity automata, what the color of the state is). Prover wins if the sequence of annotations she generates is correct: it is an accepting run iff the word generated by Refuter is in $L$. We show how a winning strategy for Refuter can serve as a simple and easy-to-understand certificate to inexpressibility, and how it induces additional forms of certificates. Our framework handles all classes of deterministic automata, including ones with structural restrictions like weak automata. In addition, it can be used for refuting separation of two languages by an automaton of the desired class, and for finding automata that approximate $L$ and belong to the desired class., Comment: This is the full version of an article with the same title that appears in the FoSSaCS 2021 conference proceedings

Published

2021

10. An Efficient Normalisation Procedure for Linear Temporal Logic and Very Weak Alternating Automata

Author

Sickert, Salomon, Esparza, Javier, Sickert, Salomon, and Esparza, Javier

Abstract

In the mid 80s, Lichtenstein, Pnueli, and Zuck proved a classical theorem stating that every formula of Past LTL (the extension of LTL with past operators) is equivalent to a formula of the form $\bigwedge_{i=1}^n \mathbf{G}\mathbf{F} \varphi_i \vee \mathbf{F}\mathbf{G} \psi_i$, where $\varphi_i$ and $\psi_i$ contain only past operators. Some years later, Chang, Manna, and Pnueli built on this result to derive a similar normal form for LTL. Both normalisation procedures have a non-elementary worst-case blow-up, and follow an involved path from formulas to counter-free automata to star-free regular expressions and back to formulas. We improve on both points. We present a direct and purely syntactic normalisation procedure for LTL yielding a normal form, comparable to the one by Chang, Manna, and Pnueli, that has only a single exponential blow-up. As an application, we derive a simple algorithm to translate LTL into deterministic Rabin automata. The algorithm normalises the formula, translates it into a special very weak alternating automaton, and applies a simple determinisation procedure, valid only for these special automata., Comment: This is the extended version of the referenced conference paper and contains an appendix with additional material

Published

2020

11. A Unified Translation of Linear Temporal Logic to ω-Automata

Author

Kupferman, Orna (Prof., Ph.D.), Esparza Estaun, Francisco Javier (Prof. Dr.), Sickert, Salomon, Kupferman, Orna (Prof., Ph.D.), Esparza Estaun, Francisco Javier (Prof. Dr.), and Sickert, Salomon

Abstract

We present a unified translation of LTL formulas into nondeterministic Büchi automata, limit-deterministic Büchi automata (LDBA), and deterministic Rabin automata (DRA). The translations yield automata of asymptotically optimal size (double or single exponential, respectively). All three translations are derived from one single Master Theorem of purely logical nature. The Master Theorem decomposes the language of a formula into a positive Boolean combination of languages that can be translated into ω-automata by elementary means. All three translations are direct and no intermediate constructions are used., Wir präsentieren eine uniforme Übersetzung von LTL Formeln zu nichtdeterministischen Büchi-Automaten (NBA), limit-deterministischen Büchi-Automaten (LDBA) und deterministischen Rabin-Automaten (DRA). Die Übersetzungen erzeugen Automaten von asymptotisch optimaler Größe (doppelt bzw. einfach exponentiell). Alle drei Übersetzungen werden aus einem einzigen Master Theorem abgeleitet. Das Master Theorem zerlegt die Sprache einer Formel in eine Boolesche Kombination von Sprachen, die mit elementaren Techniken zu ω-Automaten übersetzt werden können. Alle drei Übersetzungen sind direkt und benötigen keine Zwischenkonstruktionen.

Published

2019

12. A Verified and Compositional Translation of LTL to Deterministic Rabin Automata

Author

Brunner, Julian, Seidl, Benedikt, Sickert, Salomon, Brunner, Julian, Seidl, Benedikt, and Sickert, Salomon

Abstract

We present a formalisation of the unified translation approach from linear temporal logic (LTL) to omega-automata from [Javier Esparza et al., 2018]. This approach decomposes LTL formulas into "simple" languages and allows a clear separation of concerns: first, we formalise the purely logical result yielding this decomposition; second, we develop a generic, executable, and expressive automata library providing necessary operations on automata to re-combine the "simple" languages; third, we instantiate this generic theory to obtain a construction for deterministic Rabin automata (DRA). We extract from this particular instantiation an executable tool translating LTL to DRAs. To the best of our knowledge this is the first verified translation of LTL to DRAs that is proven to be double-exponential in the worst case which asymptotically matches the known lower bound.

Published

2019

13. A Verified and Compositional Translation of LTL to Deterministic Rabin Automata

Author

Julian Brunner and Benedikt Seidl and Salomon Sickert, Brunner, Julian, Seidl, Benedikt, Sickert, Salomon, Julian Brunner and Benedikt Seidl and Salomon Sickert, Brunner, Julian, Seidl, Benedikt, and Sickert, Salomon

Abstract

We present a formalisation of the unified translation approach from linear temporal logic (LTL) to omega-automata from [Javier Esparza et al., 2018]. This approach decomposes LTL formulas into "simple" languages and allows a clear separation of concerns: first, we formalise the purely logical result yielding this decomposition; second, we develop a generic, executable, and expressive automata library providing necessary operations on automata to re-combine the "simple" languages; third, we instantiate this generic theory to obtain a construction for deterministic Rabin automata (DRA). We extract from this particular instantiation an executable tool translating LTL to DRAs. To the best of our knowledge this is the first verified translation of LTL to DRAs that is proven to be double-exponential in the worst case which asymptotically matches the known lower bound.

Published

2019

14. The 5th Reactive Synthesis Competition (SYNTCOMP 2018): Benchmarks, Participants & Results

Author

Jacobs, Swen, Bloem, Roderick, Colange, Maximilien, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Philipp J., Michaud, Thibaud, Sakr, Mouhammad, Sickert, Salomon, Tentrup, Leander, Walker, Adam, Jacobs, Swen, Bloem, Roderick, Colange, Maximilien, Faymonville, Peter, Finkbeiner, Bernd, Khalimov, Ayrat, Klein, Felix, Luttenberger, Michael, Meyer, Philipp J., Michaud, Thibaud, Sakr, Mouhammad, Sickert, Salomon, Tentrup, Leander, and Walker, Adam

Abstract

We report on the fifth reactive synthesis competition (SYNTCOMP 2018). We introduce four new benchmark classes that have been added to the SYNTCOMP library, and briefly describe the evaluation scheme and the experimental setup of SYNTCOMP 2018. We give an overview of the participants of SYNTCOMP 2018 and highlight changes compared to previous years. Finally, we present and analyze the results of our experimental evaluation, including a ranking of tools with respect to quantity and quality of solutions., Comment: arXiv admin note: substantial text overlap with arXiv:1711.11439, arXiv:1609.00507

Published

2019

15. Practical Synthesis of Reactive Systems from LTL Specifications via Parity Games

Author

Luttenberger, Michael, Meyer, Philipp J., Sickert, Salomon, Luttenberger, Michael, Meyer, Philipp J., and Sickert, Salomon

Abstract

The synthesis of reactive systems from linear temporal logic (LTL) specifications is an important aspect in the design of reliable software and hardware. We present our adaption of the classic automata-theoretic approach to LTL synthesis, implemented in the tool Strix which has won the two last synthesis competitions (Syntcomp2018/2019). The presented approach is (1) structured, meaning that the states used in the construction have a semantic structure that is exploited in several ways, it performs a (2) forward exploration such that it often constructs only a small subset of the reachable states, and it is (3) incremental in the sense that it reuses results from previous inconclusive solution attempts. Further, we present and study different guiding heuristics that determine where to expand the on-demand constructed arena. Moreover, we show several techniques for extracting an implementation (Mealy machine or circuit) from the witness of the tree-automaton emptiness check. Lastly, the chosen constructions use a symbolic representation of the transition functions to reduce runtime and memory consumption. We evaluate the proposed techniques on the Syntcomp2019 benchmark set and show in more detail how the proposed techniques compare to the techniques implemented in other leading LTL synthesis tools.

Published

2019

16. Rabinizer 4: From LTL to Your Favourite Deterministic Automaton.

Author

Kretínský, Jan, Meggendorfer, Tobias, Sickert, Salomon, Ziegler, Christopher, Kretínský, Jan, Meggendorfer, Tobias, Sickert, Salomon, and Ziegler, Christopher

Published

2018

17. LTL Store: Repository of LTL formulae from literature and case studies

Author

Křetínský, Jan, Meggendorfer, Tobias, Sickert, Salomon, Křetínský, Jan, Meggendorfer, Tobias, and Sickert, Salomon

Abstract

This continuously extended technical report collects and compares commonly used formulae from the literature and provides them in a machine readable way.

Published

2018

18. One Theorem to Rule Them All: A Unified Translation of LTL into {\omega}-Automata

Author

Esparza, Javier, Kretinsky, Jan, Sickert, Salomon, Esparza, Javier, Kretinsky, Jan, and Sickert, Salomon

Abstract

We present a unified translation of LTL formulas into deterministic Rabin automata, limit-deterministic B\"uchi automata, and nondeterministic B\"uchi automata. The translations yield automata of asymptotically optimal size (double or single exponential, respectively). All three translations are derived from one single Master Theorem of purely logical nature. The Master Theorem decomposes the language of a formula into a positive boolean combination of languages that can be translated into {\omega}-automata by elementary means. In particular, Safra's, ranking, and breakpoint constructions used in other translations are not needed.

Published

2018

19. LTL to Deterministic Emerson-Lei Automata

Author

Müller, David, Sickert, Salomon, Müller, David, and Sickert, Salomon

Abstract

We introduce a new translation from linear temporal logic (LTL) to deterministic Emerson-Lei automata, which are omega-automata with a Muller acceptance condition symbolically expressed as a Boolean formula. The richer acceptance condition structure allows the shift of complexity from the state space to the acceptance condition. Conceptually the construction is an enhanced product construction that exploits knowledge of its components to reduce the number of states. We identify two fragments of LTL, for which one can easily construct deterministic automata and show how knowledge of these components can reduce the number of states. We extend this idea to a general LTL framework, where we can use arbitrary LTL to deterministic automata translators for parts of formulas outside the mentioned fragments. Further, we show succinctness of the translation compared to existing construction. The construction is implemented in the tool Delag, which we evaluate on several benchmarks of LTL formulas and probabilistic model checking case studies., Comment: In Proceedings GandALF 2017, arXiv:1709.01761

Published

2017

20. From LTL and Limit-Deterministic B\'uchi Automata to Deterministic Parity Automata

Author

Esparza, Javier, Křetínský, Jan, Raskin, Jean-François, Sickert, Salomon, Esparza, Javier, Křetínský, Jan, Raskin, Jean-François, and Sickert, Salomon

Abstract

Controller synthesis for general linear temporal logic (LTL) objectives is a challenging task. The standard approach involves translating the LTL objective into a deterministic parity automaton (DPA) by means of the Safra-Piterman construction. One of the challenges is the size of the DPA, which often grows very fast in practice, and can reach double exponential size in the length of the LTL formula. In this paper we describe a single exponential translation from limit-deterministic B\"uchi automata (LDBA) to DPA, and show that it can be concatenated with a recent efficient translation from LTL to LDBA to yield a double exponential, \enquote{Safraless} LTL-to-DPA construction. We also report on an implementation, a comparison with the SPOT library, and performance on several sets of formulas, including instances from the 2016 SyntComp competition.

Published

2017

21. From ltl and limit-deterministic büchi automata to deterministic parity automata

Author

Esparza, Javier, Křetínský, Jan, Raskin, Jean-François, Sickert, Salomon, Esparza, Javier, Křetínský, Jan, Raskin, Jean-François, and Sickert, Salomon

Abstract

Controller synthesis for general linear temporal logic (LTL) objectives is a challenging task. The standard approach involves translating the LTL objective into a deterministic parity automaton (DPA) by means of the Safra-Piterman construction. One of the challenges is the size of the DPA, which often grows very fast in practice, and can reach double exponential size in the length of the LTL formula. In this paper we describe a single exponential translation from limit-deterministic Büchi automata (LDBA) to DPA, and show that it can be concatenated with a recent efficient translation from LTL to LDBA to yield a double exponential, “Safraless” LTL-to-DPA construction. We also report on an implementation, a comparison with the SPOT library, and performance on several sets of formulas, including instances from the 2016 SyntComp competition., SCOPUS: cp.k, info:eu-repo/semantics/published

Published

2017

22. On Refinements of Boolean and Parametric Modal Transition Systems

Author

Křetínský, Jan, Sickert, Salomon, Křetínský, Jan, and Sickert, Salomon

Abstract

We consider the extensions of modal transition systems (MTS), namely Boolean MTS and parametric MTS and we investigate the refinement problems over both classes. Firstly, we reduce the problem of modal refinement over both classes to a problem solvable by a QBF solver and provide experimental results showing our technique scales well. Secondly, we extend the algorithm for thorough refinement of MTS providing better complexity then via reductions to previously studied problems. Finally, we investigate the relationship between modal and thorough refinement on the two classes and show how the thorough refinement can be approximated by the modal refinement.

Published

2013