网络物理系统的分层多形式证明

2015 ACM/IEEE International Conference on Formal Methods and Models for Codesign (MEMOCODE) Pub Date : 2015-12-03 DOI:10.1109/MEMCOD.2015.7340474

M. Whalen, Sanjai Rayadurgam, Elaheh Ghassabani, A. Murugesan, O. Sokolsky, M. Heimdahl, Insup Lee

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引用次数: 3

摘要

为了管理设计的复杂性和提供验证的可追溯性，复杂的网络物理系统的模型通常被分层地组织成多个抽象层。高级分析探索系统与其物理环境的相互作用，而嵌入式软件则根据派生的需求单独开发。这种低级和高级分析的分离也给可伸缩性带来了希望，因为我们能够使用适合每个级别的工具。当尝试在这样的环境中执行组合推理时，必须注意确保一个工具的结果可以在另一个工具中使用，以避免由于底层形式化的语义“不匹配”而导致的错误。本文提出了一种连接高级连续时间模型和低级离散时间模型的形式化方法。

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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Hierarchical multi-formalism proofs of cyber-physical systems

To manage design complexity and provide verification tractability, models of complex cyber-physical systems are typically hierarchically organized into multiple abstraction layers. High-level analysis explores interactions of the system with its physical environment, while embedded software is developed separately based on derived requirements. This separation of low-level and high-level analysis also gives hope to scalability, because we are able to use tools that are appropriate for each level. When attempting to perform compositional reasoning in such an environment, care must be taken to ensure that results from one tool can be used in another to avoid errors due to “mismatches” in the semantics of the underlying formalisms. This paper proposes a formal approach for linking high-level continuous time models and lower-level discrete time models.

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2015 ACM/IEEE International Conference on Formal Methods and Models for Codesign (MEMOCODE)

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