Probabilistic Black-Box Checking via Active MDP Learning
This work addresses the challenge of verifying stochastic embedded systems, offering an incremental improvement over prior black-box checking methods.
The paper tackles the problem of testing stochastic black-box systems by enhancing the traditional black-box checking (BBC) technique with ProbBBC, which integrates active MDP learning, probabilistic model checking, and statistical hypothesis testing, resulting in improved performance over existing methods, particularly for systems with limited observation.
We introduce a novel methodology for testing stochastic black-box systems, frequently encountered in embedded systems. Our approach enhances the established black-box checking (BBC) technique to address stochastic behavior. Traditional BBC primarily involves iteratively identifying an input that breaches the system's specifications by executing the following three phases: the learning phase to construct an automaton approximating the black box's behavior, the synthesis phase to identify a candidate counterexample from the learned automaton, and the validation phase to validate the obtained candidate counterexample and the learned automaton against the original black-box system. Our method, ProbBBC, refines the conventional BBC approach by (1) employing an active Markov Decision Process (MDP) learning method during the learning phase, (2) incorporating probabilistic model checking in the synthesis phase, and (3) applying statistical hypothesis testing in the validation phase. ProbBBC uniquely integrates these techniques rather than merely substituting each method in the traditional BBC; for instance, the statistical hypothesis testing and the MDP learning procedure exchange information regarding the black-box system's observation with one another. The experiment results suggest that ProbBBC outperforms an existing method, especially for systems with limited observation.