日本語
 
Help Privacy Policy ポリシー/免責事項
  詳細検索ブラウズ

アイテム詳細


公開

成果報告書

Multilevel Monte Carlo Method for Statistical Model Checking of Hybrid Systems

MPS-Authors
/persons/resource/persons144805

Soudjani,  Sadegh
Group R. Majumdar, Max Planck Institute for Software Systems, Max Planck Society;

/persons/resource/persons144534

Majumdar,  Rupak
Group R. Majumdar, Max Planck Institute for Software Systems, Max Planck Society;

External Resource
There are no locators available
Fulltext (restricted access)
There are currently no full texts shared for your IP range.
フルテキスト (公開)

arXiv:1706.08270.pdf
(プレプリント), 540KB

付随資料 (公開)
There is no public supplementary material available
引用

Soudjani, S., Majumdar, R., & Nagapetyan, T. (2017). Multilevel Monte Carlo Method for Statistical Model Checking of Hybrid Systems. Retrieved from http://arxiv.org/abs/1706.08270.


引用: https://hdl.handle.net/21.11116/0000-0000-ED3B-4
要旨
We study statistical model checking of continuous-time stochastic hybrid systems. The challenge in applying statistical model checking to these systems is that one cannot simulate such systems exactly. We employ the multilevel Monte Carlo method (MLMC) and work on a sequence of discrete-time stochastic processes whose executions approximate and converge weakly to that of the original continuous-time stochastic hybrid system with respect to satisfaction of the property of interest. With focus on bounded-horizon reachability, we recast the model checking problem as the computation of the distribution of the exit time, which is in turn formulated as the expectation of an indicator function. This latter computation involves estimating discontinuous functionals, which reduces the bound on the convergence rate of the Monte Carlo algorithm. We propose a smoothing step with tunable precision and formally quantify the error of the MLMC approach in the mean-square sense, which is composed of smoothing error, bias, and variance. We formulate a general adaptive algorithm which balances these error terms. Finally, we describe an application of our technique to verify a model of thermostatically controlled loads.