Nondestructive evaluation using shearography requires a way to stress the inspection target. This technique is able to directly measure the displacement gradient distribution on the object surface. Shearography visualizes the internal structural damages as the anomalous pattern in the shearograpic fringe pattern. A piezoelectric (PZT) excitation system is able to generate loadings in the vibrational, acoustic, and ultrasonic regimes. In this paper, we propose a PZT-excited stroboscopic shearography. The PZT excitation could generate vibrational loading, a stationary wavefield, and a nonstationary propagation wave to fulfill the external loading requirement of shearography. The sweeping of the PZT excitation frequency, the formation of a standing wave, and a small shearing to suppress the incident wave were powerful controllable tools to detect the defects. The sweeping of the PZT excitation frequency enabled us to determine one of the defect-sensitive frequencies almost in real time. In addition, because the defect sensitive frequencies always existed in wide and plural ranges, the risk of the defect being overlooked by the inspector could be alleviated. The results of evaluation using stroboscopic shearography showed that an artificial 20 mm-diameter defect could be visualized at the excitation frequencies of 5–8 kHz range and 12.5–15.5 kHz range. This technique provided full field reliable and repeatable inspection results. Additionally, the proposed method overcame the important drawback of the time-averaged shearography, being required to identify the resonance vibration frequency sensitive to the defect.

1.
Y. Y.
Hung
and
C. E.
Taylor
, “
Speckle-shearing interferometric camera–A tool for measurement of derivatives of surface-displacement
,”
Proc. SPIE
41
,
169
75
(
1973
).
2.
H.
Sanati
,
F.
Reshadi
,
G.
Faraji
 et al, “
Evaluation of residual stress in ultrafine-grained aluminum tubes using shearography
,”
Proc. Inst. Mech. Eng., Part B
229
(
6
),
953
962
(
2015
).
3.
J. R.
Lee
,
J.
Molimard
,
A.
Vautrin
 et al, “
Diffraction grating interferometers for mechanical characterisations of advanced fabric laminates
,”
Opt. Laser Technol.
38
(
1
),
51
66
(
2006
).
4.
D.
Akbari
,
N.
Soltani
, and
M.
Farahani
, “
Numerical and experimental investigation of defect detection in polymer materials by means of digital shearography with thermal loading
,”
Proc. Inst. Mech. Eng., Part B
227
(
3
),
430
442
(
2013
).
5.
G.
De Angelis
,
M.
Meo
,
D. P.
Almond
 et al, “
A new technique to detect defect size and depth in composite structures using digital shearography and unconstrained optimization
,”
NDT&E Int.
45
(
1
),
91
96
(
2012
).
6.
Z.
Liu
,
J.
Gao
,
H.
Xie
 et al, “
NDT capability of digital shearography for different materials
,”
Opt. Lasers Eng.
49
(
12
),
1462
1469
(
2011
).
7.
S. L.
Toh
,
H. M.
Shang
,
F. S.
Chau
 et al, “
Flaw detection in composites using time-average shearography
,”
Opt. Laser Technol.
23
(
1
),
25
30
(
1991
).
8.
L.
Yang
,
W.
Steinchen
,
G.
Kupfer
 et al, “
Vibration analysis by means of digital shearography
,”
Opt. Lasers Eng.
30
(
2
),
199
212
(
1998
).
9.
J.
Schöntag
,
D.
Willemann
, and
A. A.
Gonçalves
, “
Depth assessment of defects in composite plates combining shearography and vibration excitation
,”
Proc. SPIE
7387
,
73871Z
(
2010
).
10.
L.
Zhua
,
S.
Wua
, and
L.
Yang
, “
Stroboscopic digital shearographic system for vibration analysis of large area object
,”
Instrum. Exp. Tech.
57
(
4
),
493
498
(
2014
).
11.
W.
Steinchen
,
Y.
Gan
,
G.
Kupfer
 et al, “
Digital shearography using stroboscopic illumination additional to time average method
,”
Proc. SPIE
5503
,
499
509
(
2004
).
12.
D.
Findeis
and
J.
Gryzagoridis
, “
Digital shearography and vibration excitation for NDT of aircraft components
,”
AIP Conf. Proc.
1600
,
33
38
(
2014
).
13.
H.
Lopes
,
F.
Ferreira
,
J. V.
Araújo dos Santos
 et al, “
Localization of damage with speckle shearography and higher order spatial derivatives
,”
Mech. Syst. Signal Process.
49
,
24
38
(
2014
).
14.
B.
Lamboul
,
O.
Giraudo
, and
D.
Osmont
, “
Detection of disbonds in foam composite assemblies using flexural waves and shearography
,”
AIP Conf. Proc.
1650
,
1155
1166
(
2015
).
15.
D.
Devillers
,
F.
Taillade
,
D.
Osmont
 et al, “
Shearographic imaging of the interaction of ultrasonic waves and defects in plates
,”
Proc. SPIE
3993
,
142
149
(
2000
).
16.
Y. Y.
Hung
and
C. Y.
Liang
, “
Image-shearing camera for direct measurement of surface strains
,”
Appl. Opt.
18
(
7
),
1046
51
(
1979
).
17.
V.
Giurgiutiu
,
Structural Health Monitoring: With Piezoelectric Wafer Active Sensors
(
Academic Press
,
Burlington, MA
,
2007
).
18.
B. A.
Bard
,
G. A.
Gordon
, and
S.
Wu
, “
Laser-modulated phase-stepping digital shearography for quantitative full-field imaging of ultrasonic waves
,”
J. Acoust. Soc. Am.
103
(
6
),
3327
3335
(
1998
).
19.
R.
Dong
,
Y.
Tan
,
H.
Chen
 et al, “
A neural networks based model for rate-dependent hysteresis for piezoceramic actuators
,”
Sens. Actuators, A
143
(
2
),
370
376
(
2008
).
20.
C. J.
Tay
,
C.
Quan
,
F. J.
Yang
 et al, “
A new method for phase extraction from a single fringe pattern
,”
Opt. Commun.
239
,
251
258
(
2004
).
21.
M.
Arevalillo Herráez
,
D. R.
Burton
,
M. J.
Lalor
 et al, “
A fast two dimensional phase unwrapping algorithm based on sorting by reliability following a non-continuous path
,”
Appl. Opt.
41
(
35
),
7437
7444
(
2001
).
22.
See http://oesl.kaist.ac.kr/xndt for X-NDT, Inc., accessed
July 2 2016
.
23.
D. Y.
Bae
and
J. R.
Lee
, “
Development of single channeled serial-connected PZT sensor array and damage visualization based on multi-source wave propagation imaging
,”
J. Intell. Mater. Syst. Struct.
27
(
13
),
1861
1870
(
2016
).
24.
T. C.
Truong
and
J. R.
Lee
, “
A versatile inspection system for pipe structure using ultrasonic waves propagation imager
,”
J. Phys.
628
,
012015
(
2015
).
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