Modeling and instrumentation for fault detection and isolation of a cooling system

Proceedings of the IEEE SoutheastCon 2000. 'Preparing for The New Millennium' (Cat. No.00CH37105) Pub Date : 2000-04-07 DOI:10.1109/SECON.2000.845594

P. Feenstra, E. Manders, P. Mosterman, Gautam Biswas, R. Barnett

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引用次数: 13

Abstract

Functional redundancy techniques for fault detection and isolation (FDI) in dynamic systems requires close interaction between system instrumentation, modeling and analysis. Effective FDI requires detailed and accurate models to trade and analyze system behavior, including transient phenomena that result from faults. It also requires appropriate instrumentation technology to provide the measurements to capture and analyze system behavior. Models and measurements must be matched carefully to provide sufficient observability and effective analysis. In this paper we demonstrate the development of FDI systems for complex applications by presenting the modeling and instrumentation of an automobile combustion engine cooling system. We have developed a qualitative parameter estimation methodology for FDI. A system model is represented as a graph that captures the dynamic behavior of the system. To demonstrate the applicability a small leak is artificially introduced in the cooling system and accurately detected and isolated.

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冷却系统故障检测和隔离的建模和仪表

动态系统故障检测与隔离(FDI)的功能冗余技术要求系统仪表、建模和分析之间的密切交互。有效的FDI需要详细和准确的模型来交易和分析系统行为，包括由故障引起的瞬态现象。它还需要适当的仪器技术来提供捕获和分析系统行为的测量。模型和测量必须仔细匹配，以提供足够的可观察性和有效的分析。在本文中，我们通过展示汽车内燃机冷却系统的建模和仪表来展示复杂应用的FDI系统的发展。我们开发了一种外商直接投资的定性参数估计方法。系统模型表示为捕获系统动态行为的图形。为了证明该方法的适用性，人为地在冷却系统中引入了一个小泄漏，并进行了精确的检测和隔离。

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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Proceedings of the IEEE SoutheastCon 2000. 'Preparing for The New Millennium' (Cat. No.00CH37105)

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