Diagnoser design strategy for discrete event system: Case study of neutralization system

Advanced Control for Applications Pub Date : 2022-08-12 DOI:10.1002/adc2.114

Abhay Deep Seth, Santosh Biswas, Amit Kumar Dhar

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引用次数: 2

Abstract

In fault diagnosis, we study model-based approaches to diagnose the discrete event system that efficiently represents the determined ambiguity, unpredictability, and the observation and judgment of several real-life problems. Diagnosability is a crucial task for system reliability. This article presents a strategy for verifying the diagnosability of discrete event systems (DESs) using conjunctive normal form (CNF). This strategy introduces CNF-based finite state machine (FSM). First, the scheme considers the model of the system for diagnosis, and CNF represents all transitions of the DES. CNF-based FSM constructs a diagnoser known as CNF-based diagnoser. Diagnoser tests whether faulty events can be detected or not in a given system model, that is, DES. The diagnoser verifies the diagnosability of the given DES-based FSM using the resolve rule. The construction of diagnoser and diagnosability verification with respect to a real-world industrial system is illustrated. The complexity of the diagnoser construction and diagnosability verification are shown to be efficient.

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离散事件系统的诊断器设计策略:以中和系统为例

在故障诊断中，我们研究了基于模型的方法来诊断离散事件系统，该系统有效地代表了确定的模糊性、不可预测性以及对几个现实问题的观察和判断。可诊断性是保证系统可靠性的关键。本文提出了一种利用合取范式(CNF)验证离散事件系统可诊断性的策略。该策略引入了基于cnf的有限状态机(FSM)。该方案首先考虑系统的模型进行诊断，用CNF表示DES的所有过渡，基于CNF的FSM构造一个诊断器，称为基于CNF的诊断器。诊断程序测试在给定的系统模型(即DES)中是否可以检测到故障事件。诊断程序使用resolve规则验证给定的基于DES的FSM的可诊断性。以实际工业系统为例，说明了诊断器的构造和可诊断性验证。诊断器的构造和可诊断性验证的复杂性是有效的。

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

Advanced Control for Applications

CiteScore

2.60

自引率

0.00%

发文量