Analyzing Resilience Properties of Different Topologies of Collective Adaptive Systems
Thomas J. Glazier,
Javier Cámara,
Bradley Schmerl and
David Garlan.
In Proceedings of the 3rd FoCAS Workshop on the Fundamentals of Collective Adaptive Systems, Boston, MA, USA, 21 September 2015.
Online links: 
Abstract
| Modern software systems are often compositions
of entities that increasingly use self-adaptive capabilities to
improve their behavior to achieve systematic quality goals. Self-adaptive
managers for each component system attempt to provide
locally optimal results, but if they cooperated and potentially
coordinated their efforts it might be possible to obtain more
globally optimal results. The emergent properties that result
from such composition and cooperation of self-adaptive systems
are not well understood, difficult to reason about, and
present a key challenge in the evolution of modern software
systems. For example, the effects of coordination patterns and
protocols on emergent properties such as the resiliency of the
collectives need to be understood when designing these systems.
In this paper we propose that probabilistic model checking
of stochastic multiplayer games (SMG) provides a promising
approach to analyze, understand, and reason about emergent
properties in collectives of adaptive systems (CAS). Probabilistic
Model Checking of SMGs is a technique particularly suited
to analyzing emergent properties in CAS, since SMG models
capture: (i) the uncertainty and variability intrinsic to the CAS
and its execution environment in the form of probabilistic and
nondeterministic choices, and (ii) the competitive/cooperative
aspects of the interplay among the constituent systems of the
CAS. Analysis of SMGs allows us to reason about things like
the worst case scenarios, which constitutes a new contribution
to understanding emergent properties in CAS. We investigate
the use of SMGs to show how they can be useful in analyzing
the impact of communication topology for collections of fully
cooperative systems defending against an external attack.
|
Keywords: Assurance, Coordination, Model Checking, Self-adaptation, Stochastic Games.
@InProceedings{Glazier/2015/CAS,
AUTHOR = {Glazier, Thomas J. and C\'{a}mara, Javier and Schmerl, Bradley and Garlan, David},
TITLE = {Analyzing Resilience Properties of Different Topologies of Collective Adaptive Systems},
YEAR = {2015},
MONTH = {21 September},
BOOKTITLE = {Proceedings of the 3rd FoCAS Workshop on the Fundamentals of Collective Adaptive Systems},
ADDRESS = {Boston, MA, USA},
PDF = {http://acme.able.cs.cmu.edu/pubs/uploads/pdf/PID3850133.pdf},
ABSTRACT = {Modern software systems are often compositions
of entities that increasingly use self-adaptive capabilities to
improve their behavior to achieve systematic quality goals. Self-adaptive
managers for each component system attempt to provide
locally optimal results, but if they cooperated and potentially
coordinated their efforts it might be possible to obtain more
globally optimal results. The emergent properties that result
from such composition and cooperation of self-adaptive systems
are not well understood, difficult to reason about, and
present a key challenge in the evolution of modern software
systems. For example, the effects of coordination patterns and
protocols on emergent properties such as the resiliency of the
collectives need to be understood when designing these systems.
In this paper we propose that probabilistic model checking
of stochastic multiplayer games (SMG) provides a promising
approach to analyze, understand, and reason about emergent
properties in collectives of adaptive systems (CAS). Probabilistic
Model Checking of SMGs is a technique particularly suited
to analyzing emergent properties in CAS, since SMG models
capture: (i) the uncertainty and variability intrinsic to the CAS
and its execution environment in the form of probabilistic and
nondeterministic choices, and (ii) the competitive/cooperative
aspects of the interplay among the constituent systems of the
CAS. Analysis of SMGs allows us to reason about things like
the worst case scenarios, which constitutes a new contribution
to understanding emergent properties in CAS. We investigate
the use of SMGs to show how they can be useful in analyzing
the impact of communication topology for collections of fully
cooperative systems defending against an external attack.
},
KEYWORDS = {Assurance, Coordination, Model Checking, Self-adaptation, Stochastic Games}
}
|
