Implementing logical synchrony in integrated modular avionics

2009 IEEE/AIAA 28th Digital Avionics Systems Conference Pub Date : 2009-12-04 DOI:10.1109/DASC.2009.5347579

Steven P. Miller, D. Cofer, L. Sha, J. Meseguer, A. Al-Nayeem

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引用次数: 54

Abstract

Many avionics systems must be implemented as redundant, distributed systems in order to provide the necessary level of fault tolerance. To correctly perform their function, the individual nodes of these systems must agree on some part of the global system state. Developing protocols to achieve this agreement is greatly simplified if the nodes execute synchronously relative to each other, but many Integrated Modular Avionics architectures assume nodes will execute asynchronously. This paper presents a simple design pattern, Physically Asynchronous/Logically Synchronous (PALS), that allows developers to design and verify a distributed, redundant system as though all nodes execute synchronously. This synchronous design can then be distributed over a physically asynchronous architecture in such a way that the logical correctness of the design is preserved. Use of this complexity reducing design pattern greatly simplifies the development and verification of fault tolerant distributed applications, ensures optimal system performance, and provides a standard argument for system certification.

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集成模块化航空电子系统中逻辑同步的实现

为了提供必要的容错水平，许多航空电子系统必须实现为冗余的分布式系统。为了正确地执行它们的功能，这些系统的各个节点必须就全局系统状态的某些部分达成一致。如果节点之间的执行是同步的，那么实现这种协议的协议开发就会大大简化，但是许多集成模块化航空电子体系结构假设节点是异步执行的。本文提出了一个简单的设计模式，物理异步/逻辑同步(PALS)，它允许开发人员设计和验证分布式冗余系统，就像所有节点同步执行一样。然后，可以将这种同步设计分布在物理异步架构上，从而保持设计的逻辑正确性。使用这种降低复杂性的设计模式大大简化了容错分布式应用程序的开发和验证，确保了最佳的系统性能，并为系统认证提供了标准论据。

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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来源期刊

2009 IEEE/AIAA 28th Digital Avionics Systems Conference

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