iec61499动态重构的回滚序列

Laurin Prenzel, Simon Hofmann, S. Steinhorst
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引用次数: 0

摘要

动态重构是未来工业控制系统灵活性和敏捷性的核心因素。验证和确认可以为重新配置的成功提供一些信心,但是意外的外部事件或错误总是会导致重新配置过程的终止。这可能会威胁到实时行为,必须进行预测。在本文中,我们扩展了现有的动态重构实时模型,以纳入安全回滚场景,允许重构过程的无中断逆转,从而提供容错性。我们引入了不可返回点的概念,在此之后,回滚不再可行。我们在两个示例系统中演示了操作的顺序如何影响回滚序列的长度,并在两个阶段优化操作的顺序,以找到一个提供最大容错性的序列,同时最小化实时中断。结果表明,考虑潜在的故障模式需要额外的开销,但它可以提供容错,从而促进动态重构在实际应用中的进一步应用。这可能会导致未来工业控制系统更高的敏捷性和弹性。
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Rollback Sequences for Dynamic Reconfiguration of IEC 61499
Dynamic reconfiguration is a core contributor to the flexibility and agility of future industrial control systems. Verification and validation can provide some confidence in the success of a reconfiguration, yet unexpected external events or bugs can always lead to the abortion of the reconfiguration process. This can threaten the real-time behavior and must be anticipated. In this paper, we extend existing real-time models of dynamic reconfiguration to incorporate safe rollback scenarios that allow a disruption-free reversal of the reconfiguration process, thus providing fault-tolerance. We introduce the concept of a point of no return, after which a rollback is no longer feasible. We demonstrate in two example systems how the ordering of operations can affect the length of the rollback sequence and optimize the ordering of operations in two stages to find a sequence that offers a maximal fault-tolerance, while minimizing the real-time disruption. The results indicate that while considering potential failure modes requires additional overhead, it can provide fault-tolerance that promotes the further application of dynamic reconfiguration in practical applications. This may lead to higher agility and resilience in industrial control systems of the future.
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