Verification of orbitally self-stabilizing distributed algorithms using Lyapunov functions and Poincare maps

Verification of orbitally self-stabilizing distributed algorithms using Lyapunov functions and Poincare maps

Self-stabilization is a novel method for achieving fault tolerance in distributed applications. A self-stabilizing algorithm will reach a legal set of states, regardless of the starting state or states adopted due to the effects of transient faults, infinite time. However, proving self-stabilization...

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Hauptverfasser: Dhama, A., Oehlerking, J., Theel, O.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Application software
Communication system control
Computer science
Distributed algorithms
Fault tolerance
Feedback control
Hybrid Systems
Law
Legal factors
Lyapunov method
Lyapunov Theory
Poincar´e maps
Self-Stabilization
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Verification
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Beschreibung
Zusammenfassung:Self-stabilization is a novel method for achieving fault tolerance in distributed applications. A self-stabilizing algorithm will reach a legal set of states, regardless of the starting state or states adopted due to the effects of transient faults, infinite time. However, proving self-stabilization is a difficult task. In this paper, we present a method for showing self-stabilization of a class of non-silent distributed algorithms, namely orbitally self-stabilizing algorithms. An algorithm of this class is modeled as a hybrid feedback control system. We then employ the control theoretic methods of Poincare maps and Lyapunov functions to show convergence to an orbit cycle
ISSN:1521-9097
2690-5965
DOI:10.1109/ICPADS.2006.108