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Abstract

Structural health monitoring systems employing in situ guided wave transducers are being considered for civil, mechanical, and aerospace applications. In particular, guided wave-based imaging methods have been applied to graphically depict the area of interest and localize the damage. Most existing imaging techniques have relied on scattered waves extracted by baseline subtraction to quantify the effects of damage on the guided waves. In many cases, however, baseline data may not have been recorded or may be ineffective for baseline subtraction because of uncompensated variations between baseline and in-service signals. Proposed here is an alternative approach whereby source signals are first adaptively estimated from the in-service signals, direct arrivals are then calculated by forward propagation, and scattered signals are obtained by subtraction of the direct arrivals. Images using these scattered signals can then be created by, for example, delay-and-sum methods. This approach is demonstrated using synthetic signals generated by ray tracing and conventional delay-and-sum imaging. Its feasibility is further demonstrated with experimental data recorded on an aluminum plate using a single in situ transducer as a source and a laser vibrometer to record guided signals around the periphery of the region of interest.

Keywords

adaptive source removal baseline-free imaging dispersion correction guided waves nondestructive evaluation structural health monitoring

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References

Adams

. Health monitoring of structural materials and components: methods with applications. West Sussex: John Wiley & Sons, 2007.

Michaels

. Sparse ultrasonic transducer array for structural health monitoring. In: Review of progress in QNDE (eds Thompson

Chimenti

), vol. 23B, 2004, pp.1476–1483. New York: American Institute of Physics.

Wang

Rose

Chang

F-K

. A synthetic time-reversal imaging method for structural health monitoring. Smart Mater Struct 2004; 13(2): 415–423.

. Crack identification in aluminium plates using Lamb wave signals of a PZT sensor network. Smart Mater Struct 2006; 15(3): 839–849.

Michaels

. Guided wave signal processing and image fusion for in situ damage localization in plates. Wave Motion 2007; 44(6): 482–492.

Zhao

Gao

Zhang

. Active health monitoring of an aircraft wing with embedded piezoelectric sensor/actuator network. I. Defect detection, localization and growth monitoring. Smart Mater Struct 2007; 16(4): 1208–1217.

Croxford

Wilcox

Drinkwater

. Guided wave SHM with a distributed sensor network. In: Proceedings of the SPIE, vol. 6935. Bellingham, WA: SPIE, 2008, pp.69350E-1–69350E-9.

Michaels

. A methodology for structural health monitoring with diffuse ultrasonic waves in the presence of temperature variations. Ultrasonics 2005; 43(9): 717–731.

Konstantinidis

Drinkwater

Wilcox

. The temperature stability of guided wave structural health monitoring systems. Smart Mater Struct 2006; 15(4): 967–976.

10.

Michaels

. Detection, localization and characterization of damage in plates with an in situ array of spatially distributed ultrasonic sensors. Smart Mater Struct 2008; 17(3), 035035 (15pp).

11.

Clarke

Cawley

Wilcox

. Evaluation of the damage detection capability of a sparse-array guided wave SHM system applied to a complex structure under varying thermal conditions. IEEE Trans Ultrason Ferroelectr Freq Control 2009; 56(12): 2666–2678.

12.

Wilcox

. Omni-directional guided wave transducer arrays for the rapid inspection of large areas of plate structures. IEEE Trans Ultrason Ferroelectr Freq Control 2003; 50(6): 699–709.

13.

Purekar

Pines

Sundararaman

. Directional piezoelectric phased array filters for detecting damage in isotropic plates. Smart Mater Struct 2004; 13(4): 838–850.

14.

Rajagopalan

Balasubramaniam

Krishnamurthy

. A single transmitter multi-receiver (STMR) PZT array for guided ultrasonic wave based structural health monitoring of large isotropic plate structures. Smart Mater Struct 2006; 15(5): 1190–1196.

15.

Olson

DeSimio

Derriso

. Beam forming of Lamb waves for structural health monitoring. J Vib Acoust 2007; 129(6): 730–738.

16.

Giurgiutiu

. In situ 2-D piezoelectric wafer active sensors arrays for guided wave damage detection. Ultrasonics 2008; 48(2): 117–134.

17.

Michaels

Croxford

Wilcox

. Imaging algorithms for locating damage via in situ ultrasonic sensors. In: Proceedings of IEEE sensors applications symposium, Piscataway, NJ: IEEE, 2008, pp.63–67.

18.

Michaels

Hall

Hickman

. Sparse array imaging of change-detected ultrasonic signals by minimum variance processing. In: Review of progress in QNDE (eds Thompson

Chimenti

), vol. 28A1, 2009, pp.642–649. New York: American Institute of Physics.

19.

Michaels

Hall

Michaels

. Adaptive imaging of damage from changes in guided wave signals recorded from spatially distributed arrays. In: Proceedings of SPIE, vol. 7295. Bellingham, WA: SPIE, 2009, pp.729515-1–729515-11.

20.

Hall

Michaels

. Minimum variance ultrasonic imaging applied to an in situ sparse guided wave array. IEEE Trans Ultrason Ferroelectr Freq Control 2010; 57(10): 2311–2323.

21.

Gandhi

Lee

. Beamforming of wavefield data from embedded sources for rapid follow-up inspection of inaccessible areas. In: Review of progress in QNDE (eds Thompson

Chimenti

), vol. 29A. New York: American Institute of Physics, 2010, pp.184–191.

22.

Ihn

Chang

F-K

. Pitch-catch active sensing methods in structural health monitoring for aircraft structures. Int J Struct Health Monit 2008; 7(1): 5–19.

23.

Alleyne

Pialucha

Cawley

. A signal regeneration technique for long-range propagation of dispersive Lamb waves. Ultrasonics 1993; 31(3): 201–204.

24.

Wilcox

. A rapid signal processing technique to remove the effect of dispersion from guided wave signals. IEEE Trans Ultrason Ferroelectr Freq Control 2003; 50(4): 419–427.

25.

Levine

Michaels

Lee

. Boundary reflection compensation in guided wave baseline-free imaging. In: Review of progress in QNDE (eds Thompson

Chimenti

), vol. 30B. New York: American Institute of Physics, 2011, pp.113–120.

Baseline-free guided wave imaging via adaptive source removal

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