基于信度误差估计的结构自适应

Rima Al Ali, T. Bures, I. Gerostathopoulos, Jaroslav Keznikl, F. Plášil
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引用次数: 13

摘要

信息物理系统(CPS)是由相互协作的自主组件组成的系统,这些组件与物理环境密切交互并控制物理环境。由于是分布式的,并且通常基于周期性活动,CPS必须处理这样的问题,即捕获系统及其环境的分布式状态的数据本质上是不准确的(它们代表对状态的信念)。特别是,当追求可靠性时,这就产生了一个问题。在本文中,我们通过在体系结构级别对信念进行建模来解决这个问题。特别是,我们通过描述随时间变化的信念不准确性的模型来增强体系结构。我们利用这些模型在运行时量化信念过时对其不准确性的影响。然后,我们使用此量化来驱动架构适应,目的是提高运行的CPS系统的可靠性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Architecture Adaptation Based on Belief Inaccuracy Estimation
Cyber-physical systems (CPS) are systems of cooperating autonomous components which closely interact with and control the physical environment. Being distributed and typically based on periodic activities, CPS have to cope with the problem that data capturing a distributed state of the system and its environment are inherently inaccurate (they represent belief on the state). In particular, this poses a problem when dependability is being pursued. In this paper we address this issue by modeling belief at the architecture level. In particular, we enhance the architecture by models describing belief inaccuracy over time. We exploit these models to quantify at runtime the impact of belief staleness on its inaccuracy. We then use this quantification to drive architectural adaptation with the aim to increase dependability of the running CPS system.
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