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Aspect-Oriented Fault Modeling and Anomaly Detection in Ptolemy IIIlge Akkaya, Patricia Derler, Edward A. Lee
Citation
Ilge Akkaya, Patricia Derler, Edward A. Lee. "Aspect-Oriented Fault Modeling and Anomaly Detection in Ptolemy II". Talk or presentation, 7, November, 2013; Presented at the 10th Biennial Ptolemy Miniconference, Berkeley.
.
Abstract
Fault modeling has been a primary focus of the well-established fields of circuit design and fault-tolerant control system research. For the emerging research field of cyber-physical systems, this modeling aspect plays an even more fundamental role due to the increased complexity in the networked-real time system. As concurrency and distributed behavior become ubiquitous in system design, faults due to networks, latency and cyber-physical interactions gain importance and detecting faults in pre-deployment stages becomes essential.
In the domain of modeling and simulation, behavioral modeling often focuses on implementing the correct behavior that takes no account of the faults that might occur in system execution. However, numerous fault scenarios exist in data content, communication, analog and digital component failures, all of which can drive system behavior beyond the model context. Cyber-Physical System models can be refined continuously to address more possible behavior under different fault conditions, however, at the expense of increasing model complexity beyond usefulness.
Aspect-oriented modeling is a means to represent different concerns related to system design as separate entities that are evaluated in concurrency with a functional representation. The separation of concerns in this sense has several benefits in fault modeling such as enabling modular and flexible representations for fault aspects while maintaining model simplicity and the models that define of correct operation. In Ptolemy, an aspect-oriented modeling formalism is developed to inject families of deterministic, nondeterministic and stochastic faults and to apply anomaly detection techniques to monitor anomalies in system behavior. The Modal model domain has been extended to enable probability expressions at transitions, and in turn, to represent Markov chain and Hidden Markov Model behavior. On the anomaly detection side, a component library has been developed for Hidden Markov and Mixture Model parameter estimation and classification. Electronic downloads
- HTML
Ilge Akkaya, Patricia Derler, Edward A. Lee. <a
href="http://chess.eecs.berkeley.edu/pubs/1038.html"><i>Aspect-Oriented
Fault Modeling and Anomaly Detection in Ptolemy
II</i></a>, Talk or presentation, 7, November,
2013; Presented at the <a
href="http://ptolemy.org/conferences/13" >10th
Biennial Ptolemy Miniconference</a>, Berkeley.
.
- Plain text
Ilge Akkaya, Patricia Derler, Edward A. Lee.
"Aspect-Oriented Fault Modeling and Anomaly Detection
in Ptolemy II". Talk or presentation, 7, November,
2013; Presented at the <a
href="http://ptolemy.org/conferences/13" >10th
Biennial Ptolemy Miniconference</a>, Berkeley.
.
- BibTeX
@presentation{AkkayaDerlerLee13_AspectOrientedFaultModelingAnomalyDetectionInPtolemy,
author = {Ilge Akkaya and Patricia Derler and Edward A. Lee},
title = {Aspect-Oriented Fault Modeling and Anomaly
Detection in Ptolemy II},
day = {7},
month = {November},
year = {2013},
note = {Presented at the <a
href="http://ptolemy.org/conferences/13" >10th
Biennial Ptolemy Miniconference</a>, Berkeley.
},
abstract = {Fault modeling has been a primary focus of the
well-established fields of circuit design and
fault-tolerant control system research. For the
emerging research field of cyber-physical systems,
this modeling aspect plays an even more
fundamental role due to the increased complexity
in the networked-real time system. As concurrency
and distributed behavior become ubiquitous in
system design, faults due to networks, latency and
cyber-physical interactions gain importance and
detecting faults in pre-deployment stages becomes
essential. In the domain of modeling and
simulation, behavioral modeling often focuses on
implementing the correct behavior that takes no
account of the faults that might occur in system
execution. However, numerous fault scenarios exist
in data content, communication, analog and digital
component failures, all of which can drive system
behavior beyond the model context. Cyber-Physical
System models can be refined continuously to
address more possible behavior under different
fault conditions, however, at the expense of
increasing model complexity beyond usefulness.
Aspect-oriented modeling is a means to represent
different concerns related to system design as
separate entities that are evaluated in
concurrency with a functional representation. The
separation of concerns in this sense has several
benefits in fault modeling such as enabling
modular and flexible representations for fault
aspects while maintaining model simplicity and the
models that define of correct operation. In
Ptolemy, an aspect-oriented modeling formalism is
developed to inject families of deterministic,
nondeterministic and stochastic faults and to
apply anomaly detection techniques to monitor
anomalies in system behavior. The Modal model
domain has been extended to enable probability
expressions at transitions, and in turn, to
represent Markov chain and Hidden Markov Model
behavior. On the anomaly detection side, a
component library has been developed for Hidden
Markov and Mixture Model parameter estimation and
classification.},
URL = {http://chess.eecs.berkeley.edu/pubs/1038.html}
}
Posted by Barb Hoversten on 21 Nov 2013.
Groups: ptolemy
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