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http://dx.doi.org/10.12989/smm.2018.5.2.273

Sensor clustering technique for practical structural monitoring and maintenance  

Celik, Ozan (Department of Civil Environmental and Construction Engineering, University of Central Florida)
Terrell, Thomas (Department of Civil Environmental and Construction Engineering, University of Central Florida)
Gul, Mustafa (Department of Civil and Environmental Engineering, University of Alberta)
Catbas, F. Necati (Department of Civil Environmental and Construction Engineering, University of Central Florida)
Publication Information
Structural Monitoring and Maintenance / v.5, no.2, 2018 , pp. 273-295 More about this Journal
Abstract
In this study, an investigation of a damage detection methodology for global condition assessment is presented. A particular emphasis is put on the utilization of wireless sensors for more practical, less time consuming, less expensive and safer monitoring and eventually maintenance purposes. Wireless sensors are deployed with a sensor roving technique to maintain a dense sensor field yet requiring fewer sensors. The time series analysis method called ARX models (Auto-Regressive models with eXogeneous input) for different sensor clusters is implemented for the exploration of artificially induced damage and their locations. The performance of the technique is verified by making use of the data sets acquired from a 4-span bridge-type steel structure in a controlled laboratory environment. In that, the free response vibration data of the structure for a specific sensor cluster is measured by both wired and wireless sensors and the acceleration output of each sensor is used as an input to ARX model to estimate the response of the reference channel of that cluster. Using both data types, the ARX based time series analysis method is shown to be effective for damage detection and localization along with the interpretations and conclusions.
Keywords
structural health monitoring; damage detection; wireless sensors; ARX models; time series modeling; sensor roving; practical maintenance;
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