Probabilistic Bisimulation for Parameterized Systems

Hong, Chih-Duo; Lin, Anthony W.; Majumdar, Rupak; Rümmer, Philipp

doi:10.1007/978-3-030-25540-4_27

Cited by 6 publications

(9 citation statements)

References 49 publications

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“…This transformation generates PRA in the size of SREs; however, the obtained automata is still not minimized. There, some techniques can be applied using probabilistic bisimulation [86], or state equivalence techniques [50] to minimize the PRA.…”

Section: Illustrative Example: From An Sre To a Pamentioning

confidence: 99%

Quantitative Verification of Stochastic Regular Expressions

Yaman

Pavese

Grunske

2021

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In this article, we introduce a probabilistic verification algorithm for stochastic regular expressions over a probabilistic extension of the Action based Computation Tree Logic (ACTL*). The main results include a novel model checking algorithm and a semantics on the probabilistic action logic for stochastic regular expressions (SREs). Specific to our model checking algorithm is that SREs are defined via local probabilistic functions. Such functions are beneficial since they enable to verify properties locally for sub-components. This ability provides a flexibility to reuse the local results for the global verification of the system; hence, the framework can be used for iterative verification. We demonstrate how to model a system with an SRE and how to verify it with the probabilistic action based logic and present a preliminary performance evaluation with respect to the execution time of the reachability algorithm.

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Section: Illustrative Example: From An Sre To a Pamentioning

confidence: 99%

Quantitative Verification of Stochastic Regular Expressions

Yaman

Pavese

Grunske

2021

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“…Numerous results suggest that the answer is that it is very expressive. On the practical side, many benchmarks (especially from paramterized systems) have indicated this to be the case, e.g., see [36,17,34,30,37,3,44,38,24,33]. On the theoretical side, this framework is in fact complete for important properties like safety and liveness for many classes of infinite-state systems that can be captured by regular model checking, including pushdown systems, reversal-bounded counter systems, two-dimensional vector addition systems, communication-free Petri nets, and tree-rewrite systems (for the extension to trees), among others, e.g., see [41,42,7,32,23,35].…”

Section: The Following Well-known Closure and Algorithmic Property Is...mentioning

confidence: 99%

“…Encoding bisimulation and probabilistic bisimulation for parameterized systems is a bit trickier since we will need infinitely many action labels (i.e. to distinguish the action of the ith process), but this can also be encoded in our framework; see the first-order proof rules over automatic structures in the recent paper [24].…”

Section: Isomorphism and Bisimulationmentioning

confidence: 99%

“…liveness, even for probabilistic distributed protocols [34,30]), as well as new correctness properties (e.g. safety games [37] and probabilistic bisimulation with applications to proving anonymity [24]). Despite these recent successes, these techniques are rather ad-hoc, and often difficult to adapt to new correctness properties.…”

Section: Introductionmentioning

confidence: 99%

“…Finally, we show that restricting to regular proofs (i.e. proofs that can be expressed by finite automata) is sufficient in practice, and allows us to have powerful verification algorithms that unify the recent successful automata synthesis algorithms [36,34,30,24] for safety, liveness, reachability games, and other interesting correctness properties.…”

Section: Introductionmentioning

confidence: 99%

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Regular Model Checking Revisited (Technical Report)

Lin¹,

Rümmer²

2020

Preprint

Self Cite

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In this contribution we revisit regular model checking, a powerful framework that has been successfully applied for the verification of infinite-state systems, especially parameterized systems (concurrent systems with an arbitrary number of processes). We provide a reformulation of regular model checking with length-preserving transducers in terms of existential second-order theory over automatic structures. We argue that this is a natural formulation that enables us tap into powerful synthesis techniques that have been extensively studied in the software verification community. More precisely, in this formulation the first-order part represents the verification conditions for the desired correctness property (for which we have complete solvers), whereas the existentially quantified second-order variables represent the relations to be synthesized. We show that many interesting correctness properties can be formulated in this way, examples being safety, liveness, bisimilarity, and games. More importantly, we show that this new formulation allows new interesting benchmarks (and old regular model checking benchmarks that were previously believed to be difficult), especially in the domain of parameterized system verification, to be solved.

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Regular Model Checking Revisited

Lin

Rümmer

2021

Lecture Notes in Computer Science

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Probabilistic Bisimulation for Parameterized Systems

Cited by 6 publications

References 49 publications

Quantitative Verification of Stochastic Regular Expressions

Quantitative Verification of Stochastic Regular Expressions

Regular Model Checking Revisited (Technical Report)

Regular Model Checking Revisited

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