Title:
Optimum Sensor Localization/Selection In A Diagnostic/Prognostic Architecture
Optimum Sensor Localization/Selection In A Diagnostic/Prognostic Architecture
Author(s)
Zhang, Guangfan
Advisor(s)
Ferri, Bonnie H.
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Abstract
Optimum Sensor Localization/Selection in
A Diagnostic/Prognostic Architecture
Guangfan Zhang
107 Pages
Directed by Dr. George J. Vachtsevanos
This research addresses the problem of sensor localization/selection for fault diagnostic purposes in Prognostics and Health Management (PHM)/Condition-Based Maintenance (CBM) systems. The performance of PHM/CBM systems relies not only on the diagnostic/prognostic algorithms used, but also on the types, location, and number of sensors selected. Most of the research reported in the area of sensor localization/selection for fault diagnosis focuses on qualitative analysis and lacks a uniform figure of merit. Moreover, sensor localization/selection is mainly studied as an open-loop problem without considering the performance feedback from the on-line diagnostic/prognostic system. In this research, a novel approach for sensor localization/selection is proposed in an integrated diagnostic/prognostic architecture to achieve maximum diagnostic performance.
First, a fault detectability metric is defined quantitatively. A novel graph-based approach, the Quantified-Directed Model, is called upon to model fault propagation in complex systems and an appropriate figure-of-merit is defined to maximize fault detectability and minimize the required number of sensors while achieving optimum performance.
Secondly, the proposed sensor localization/selection strategy is integrated into a diagnostic/prognostic system architecture while exhibiting attributes of flexibility and scalability. Moreover, the performance is validated and verified in the integrated diagnostic/prognostic architecture, and the performance of the integrated diagnostic/prognostic architecture acts as useful feedback for further optimizing the sensors considered. The approach is tested and validated through a five-tank simulation system.
This research has led to the following major contributions:
??generalized methodology for sensor localization/selection for fault diagnostic purposes.
??quantitative definition of fault detection ability of a sensor, a novel Quantified-Directed Model (QDG) method for fault propagation modeling purposes, and a generalized figure of merit to maximize fault detectability and minimize the required number of sensors while achieving optimum diagnostic performance at the system level.
??novel, integrated architecture for a diagnostic/prognostic system.
??lidation of the proposed sensor localization/selection approach in the integrated diagnostic/prognostic architecture.
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Date Issued
2005-02-17
Extent
1625998 bytes
Resource Type
Text
Resource Subtype
Dissertation