Enhancing Damage Identification Robustness to Noise and Damping Using Integrated Bistable and Adaptive Piezoelectric Circuitry

Jinki Kim, R. L. Harne, K. W. Wang

Research output: Contribution to book or proceedingChapter

Abstract

The accurate and reliable identification of damage in modern engineered structures is essential for timely corrective measures. Vibration-based damage prediction has been studied extensively by virtue of its global damage detection ability and simplicity in practical implementation. However, due to noise and damping effects, the accuracy of this method is inhibited when direct peak detection (DPD) is utilized to determine resonant frequency shifts. This research investigates an alternative method to detect frequency shifts caused by structural damage based on the utilization of strongly nonlinear bifurcation phenomena in bistable electrical circuits coupled with piezoelectric transducers integrated with the structure. It is shown that frequency shift predictions by the proposed approach are significantly less susceptible to error than DPD when realistic noise and damping levels distort the shifting resonance peaks. As implemented alongside adaptive piezoelectric circuitry with tunable inductance, the new method yields damage location and severity identification that is significantly more robust and accurate than results obtained following the DPD approach.
Original languageAmerican English
Title of host publicationProceedings of the International Design Engineering Technical Conferences and Computers and Information in Engineering Conference
DOIs
StatePublished - Aug 17 2014

Keywords

  • Adaptive piezoelectric circuitry
  • Damage identification robustness
  • Damping
  • Enhancing
  • Integrated bistable
  • Noise

DC Disciplines

  • Mechanical Engineering

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