拓扑波动对自稳定算法的影响

2016 International Conference on Distributed Computing in Sensor Systems (DCOSS) Pub Date : 2016-05-26 DOI:10.1109/DCOSS.2016.44

Stefan Lohs, Gerry Siegemund, J. Nolte, V. Turau

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引用次数: 1

摘要

自稳定系统在理论上具有独特的、可证明的能力，即使面对故障也能始终恢复到有效的系统状态。对于具有许多不可预测故障的无线自组织网络等域，这些属性当然是理想的。不幸的是，系统返回到有效状态的时间是不可预测的，并且可能不受限制。故障率通常取决于物理现象，在自稳定系统中，每个节点都试图通过循环观察其邻居的状态，以一种固有的自适应方式对故障做出反应。当状态变化太快或太慢时，系统可能永远无法达到对特定任务足够稳定的状态。本文以实际网络实验中获取的拓扑信息为基础，研究了错误率对(稳定)收敛时间的影响。这使我们能够评估典型无线网络中相关自稳定算法的渐近行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Influence of Topology-Fluctuations on Self-Stabilizing Algorithms

Self-stabilizing systems have in theory the unique and provable ability, to always return to a valid system state even in the face of failures. These properties are certainly desirable for domains like wireless ad-hoc networks with numerous unpredictable faults. Unfortunately, the time in which the system returns to a valid state is not predictable and potentially unbound. The failure rate typically depends on physical phenomena and in self-stabilizing systems each node tries to react to failures in an inherently adaptive fashion by the cyclic observation of the states of its neighbors. When state changes are either too quick or too slow the system might never reach a state that is sufficiently stable for a specific task. In this paper, we investigate the influences of the error rate on the (stability) convergence time on the basis of topology information acquired in real network experiments. This allows us to asses the asymptotic behavior of relevant self-stabilizing algorithms in typical wireless networks.

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2016 International Conference on Distributed Computing in Sensor Systems (DCOSS)

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