Robust Satisfaction of Signal Temporal Logics and Applications

Robust Satisfaction of Signal Temporal Logics and Applications
Donze Alexandre

Citation
Donze Alexandre. "Robust Satisfaction of Signal Temporal Logics and Applications". Talk or presentation, 26, September, 2011.

Abstract
The Signal Temporal Logic (STL) is adapted to specify rigorously properties constraining real-valued, dense-time signals such as traces resulting from the simulation of continuous and hybrid systems. Recently, we extended STL with a quantitative (robust) interpretation which provides a numerical margin by which a simulation trace satisfies or violate a property. Moreover, we can estimate in some cases the sensitivity of this margin to a parameter change. By combining this information with different parameters exploration strategies, we get an efficient methodology to investigate which properties are satisfied by a model, how robustly these properties are satisfied and how to find parameters values which guarantees a robust satisfaction. I will describe this methodology and the toolbox which implements it, Breach, along with different application examples.

Electronic downloads

DREAM_Seminar.pdf · application/pdf · 2002 kbytes

Citation formats

HTML

Donze Alexandre. <a
href="http://chess.eecs.berkeley.edu/pubs/855.html"
><i>Robust Satisfaction of Signal Temporal Logics
and Applications</i></a>, Talk or presentation, 
26, September, 2011.

Plain text

Donze Alexandre. "Robust Satisfaction of Signal
Temporal Logics and Applications". Talk or
presentation,  26, September, 2011.

BibTeX

@presentation{Alexandre11_RobustSatisfactionOfSignalTemporalLogicsApplications,
    author = {Donze Alexandre},
    title = {Robust Satisfaction of Signal Temporal Logics and
              Applications},
    day = {26},
    month = {September},
    year = {2011},
    abstract = {The Signal Temporal Logic (STL) is adapted to
              specify rigorously properties constraining
              real-valued, dense-time signals such as traces
              resulting from the simulation of continuous and
              hybrid systems. Recently, we extended STL with a
              quantitative (robust) interpretation which
              provides a numerical margin by which a simulation
              trace satisfies or violate a property. Moreover,
              we can estimate in some cases the sensitivity of
              this margin to a parameter change. By combining
              this information with different parameters
              exploration strategies, we get an efficient
              methodology to investigate which properties are
              satisfied by a model, how robustly these
              properties are satisfied and how to find
              parameters values which guarantees a robust
              satisfaction. I will describe this methodology and
              the toolbox which implements it, Breach, along
              with different application examples.},
    URL = {http://chess.eecs.berkeley.edu/pubs/855.html}
}

Posted by Patricia Derler on 27 Sep 2011.
Groups: chessworkshop
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