Anna Philippou scite author profile

Abstract. In this paper, we i n troduce weak bisimulation in the framework of Labeled Concurrent Markov Chains, that is, probabilistic transition systems which exhibit both probabilistic and nondeterministic behavior. By resolving the nondeterminism present, these models can be decomposed into a possibly in nite number of computation trees. We show that in order to compute weak bisimulation it is su cient to restrict attention to only a nite number of these computations. Finally, w e present an algorithm for deciding weak bisimulation which has polynomial-time complexity in the number of states of the transition system.

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A Network Game with Attackers and a Defender

Mavronicolas

Papadopoulou

Philippou

et al. 2007

Algorithmica

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Consider an information network with threats called attackers; each attacker uses a probability distribution to choose a node of the network to damage. Opponent to the attackers is a protector entity called defender; the defender scans and cleans from attacks some part of the network (in particular, a link), which it chooses independently using its own probability distribution. Each attacker wishes to maximize the probability of escaping its cleaning by the defender; towards a conflicting objective, the defender aims at maximizing the expected number of attackers it catches.We model this network security scenario as a non-cooperative strategic game on graphs. We are interested in its associated Nash equilibria, where no network entity can unilaterally increase its local objective. We obtain the following results:• We obtain an algebraic characterization of (mixed) Nash equilibria.• No (non-trivial) instance of the graph-theoretic game has a pure Nash equilibrium. This is an immediate consequence of some covering properties we prove for the supports of the players in all (mixed) Nash equilibria.• We coin a natural subclass of mixed Nash equilibria, which we call Matching Nash equilibria, for this graph-theoretic game. Matching Nash equilibria are defined by enriching the necessary covering properties we proved with some additional conditions involving other structural parameters of graphs, such as Independent Sets.

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Network Game with Attacker and Protector Entities

Mavronicolas

Papadopoulou

Philippou

et al. 2005

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Consider an information network with harmful procedures called attackers (e.g., viruses); each attacker uses a probability distribution to choose a node of the network to damage. Opponent to the attackers is the system protector scanning and cleaning from attackers some part of the network (e.g., an edge or a path), which it chooses independently using another probability distribution. Each attacker wishes to maximize the probability of escaping its cleaning by the system protector; towards a conflicting objective, the system protector aims at maximizing the expected number of cleaned attackers. We model this network scenario as a non-cooperative strategic game on graphs. We focus on the special case where the protector chooses a single edge. We are interested in the associated Nash equilibria, where no network entity can unilaterally improve its local objective. We obtain the following results: • No instance of the game possesses a pure Nash equilibrium. • Every mixed Nash equilibrium enjoys a graph-theoretic structure, which enables a (typically exponential) algorithm to compute it. • We coin a natural subclass of mixed Nash equilibria, which we call matching Nash equilibria, for this game on graphs. Matching Nash equilibria are defined using structural parameters of graphs, such as independent sets and matchings.

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The Price of Defense

Mavronicolas

Michael

Papadopoulou

et al. 2006

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Simulation and Verification in a Process Calculus for Spatially-Explicit Ecological Models

Philippou¹,

Toro²,

Antonaki³

2013

SACS

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We propose palps, a Process Algebra with Locations for Population Systems. palps allows us to produce spatially-explicit individualbased ecological models and to reason about their behavior. palps has two abstraction levels: At the first level, we may define the behavior of an individual of a population and, at the second level, we may specify a system as the collection of individuals of various species located in space. In palps, the individuals move through their life cycle while changing their location and interact with each other in various ways such as predation, infection or mating. Furthermore, we propose a translation of a subset of palps into the probabilistic model checker prism. We illustrate our framework via models of dispersal in metapopulations and by applying prism on palps models for verifying temporal logic properties and conducting reachability and steady-state analysis.

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Anna Philippou

Weak Bisimulation for Probabilistic Systems

A Network Game with Attackers and a Defender

Network Game with Attacker and Protector Entities

The Price of Defense

Simulation and Verification in a Process Calculus for Spatially-Explicit Ecological Models

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