The compensation technique of tensile force effect on the electro-mechanical impedance method for structural health monitoring

In this article, the external axial tension applied on structure was considered in electro-mechanical impedance method. An experiment was performed to study the effect of external axial force on the electro-mechanical impedance–based structural health monitoring. The axial tensions were applied on b...

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Veröffentlicht in:	Journal of intelligent material systems and structures 2015-12, Vol.26 (18), p.2477-2488
Hauptverfasser:	Yang, Jingwen, Zhu, Hongping, Wang, Dansheng, Ai, Demi
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Sprache:	eng
Schlagworte:	Artificial neural networks Axial stress Compensation Deviation Health monitoring (engineering) Impedance method Mathematical models Structural health monitoring
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container_issue	18
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container_title	Journal of intelligent material systems and structures
container_volume	26
creator	Yang, Jingwen Zhu, Hongping Wang, Dansheng Ai, Demi
description	In this article, the external axial tension applied on structure was considered in electro-mechanical impedance method. An experiment was performed to study the effect of external axial force on the electro-mechanical impedance–based structural health monitoring. The axial tensions were applied on both healthy and damaged steel beam pasted by surface-bonded piezoelectric transducers. The study results showed that the electrical admittance (the inverse of impedance) curves had an obvious tendency of decline with the increase in tension; thus, this effect would mislead the judgment of health status. Then, the artificial neural network based on radial basis function was introduced to compensate the effect of tension on EMI method. Numerical examples showed that artificial neural network method can prevent the root mean square deviation index from changing with increase in tension. An additional experiment was performed to verify the artificial neural network method. The same conclusion as the first experiment was obtained. The reasonable experiment result demonstrated that artificial neural network method has its generality for application.
doi_str_mv	10.1177/1045389X14568879
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An experiment was performed to study the effect of external axial force on the electro-mechanical impedance–based structural health monitoring. The axial tensions were applied on both healthy and damaged steel beam pasted by surface-bonded piezoelectric transducers. The study results showed that the electrical admittance (the inverse of impedance) curves had an obvious tendency of decline with the increase in tension; thus, this effect would mislead the judgment of health status. Then, the artificial neural network based on radial basis function was introduced to compensate the effect of tension on EMI method. Numerical examples showed that artificial neural network method can prevent the root mean square deviation index from changing with increase in tension. An additional experiment was performed to verify the artificial neural network method. The same conclusion as the first experiment was obtained. 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An experiment was performed to study the effect of external axial force on the electro-mechanical impedance–based structural health monitoring. The axial tensions were applied on both healthy and damaged steel beam pasted by surface-bonded piezoelectric transducers. The study results showed that the electrical admittance (the inverse of impedance) curves had an obvious tendency of decline with the increase in tension; thus, this effect would mislead the judgment of health status. Then, the artificial neural network based on radial basis function was introduced to compensate the effect of tension on EMI method. Numerical examples showed that artificial neural network method can prevent the root mean square deviation index from changing with increase in tension. An additional experiment was performed to verify the artificial neural network method. The same conclusion as the first experiment was obtained. 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An experiment was performed to study the effect of external axial force on the electro-mechanical impedance–based structural health monitoring. The axial tensions were applied on both healthy and damaged steel beam pasted by surface-bonded piezoelectric transducers. The study results showed that the electrical admittance (the inverse of impedance) curves had an obvious tendency of decline with the increase in tension; thus, this effect would mislead the judgment of health status. Then, the artificial neural network based on radial basis function was introduced to compensate the effect of tension on EMI method. Numerical examples showed that artificial neural network method can prevent the root mean square deviation index from changing with increase in tension. An additional experiment was performed to verify the artificial neural network method. The same conclusion as the first experiment was obtained. 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subjects	Artificial neural networks Axial stress Compensation Deviation Health monitoring (engineering) Impedance method Mathematical models Structural health monitoring
title	The compensation technique of tensile force effect on the electro-mechanical impedance method for structural health monitoring
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