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Sparse Deconvolution for the Inverse Problem of Multiple-Impact Force Identification Read chapter Read first chapter

2019 | OriginalPaper | Chapter

19. Using 2D Phase-Based Motion Estimation and Video Magnification for Binary Damage Identification on a Wind Turbine Blade

Authors : Aral Sarrafi, Zhu Mao

Published in: Model Validation and Uncertainty Quantification, Volume 3

Publisher: Springer International Publishing

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Abstract

Videos (sequence of images) as three-dimensional signals may be considered as a very rich source of information for several applications in structural dynamics identification and structural health monitoring (SHM) systems. Within this paper high-speed cameras are used to record the sequence of images (video) of a baseline and damaged wind turbine blade (WTB) while vibrating due to the external loadings. Among several computer vision algorithms for motion extraction from the videos, phase-based motion estimation technique is used to extract the response of both the baseline and damaged wind turbine blade. Modal parameters (natural frequencies and operating deflection shapes) were used as damage sensitive features in order to detect the occurrence of damage in the wind turbine blade. The first four natural frequencies of the both baseline and damaged wind turbine blade are extracted by analyzing the estimated motion provided by the phase based motion estimation in the frequency domain. The motion magnification algorithm is also utilized to visualize and extract the operating deflection shapes of the wind turbine blade which may be used later as an indicator of the presence of damage. It has been shown that changes in the dynamic behavior of the wind turbine blade will result to deviations in the nominal natural frequencies and operating deflection shapes, and the damaged wind turbine blade can be differentiated from the baseline WTB using this non-contact measurement approach.

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previous chapter Feasibility of Applying Phase-Based Video Processing for Modal Identification of Concrete Gravity Dams
next chapter Hierarchical Bayesian Calibration and Response Prediction of a 10-Story Building Model
Literature
1.
Doebling, S.W., Farrar, C.R., Prime, M.B.: A summary review of vibration-based damage identification methods. Shock Vib. Dig. 30, 91–105 (1998)CrossRef
2.
Fan, W., Qiao, P.: Vibration-based damage identification methods: a review and comparative study. Struct. Health Monit. 10, 83–111 (2011)CrossRef
3.
Reynders, E.: System identification methods for (operational) modal analysis: review and comparison. Arch. Comput. Meth. Eng. 19, 51–124 (2012)MathSciNetCrossRef
4.
Ebrahimkhanlou, A., Salamone, S.: Acoustic emission source localization in thin metallic plates: a single-sensor approach based on multimodal edge reflections. Ultrasonics. 78, 134–145 (2017)CrossRef
5.
Ebrahimkhanlou, A., Dubuc, B., Salamone, S.: Damage localization in metallic plate structures using edge-reflected lamb waves. Smart Mater. Struct. 25, 085035 (2016)CrossRef
6.
Ewins, D.J.: Modal Testing: Theory and Practice, vol. 15. Research Studies Press, Letchworth (1984)
7.
Chiariotti, P., Martarelli, M., Castellini, P.: Exploiting continuous scanning laser Doppler Vibrometry in timing belt dynamic characterisation. Mech. Syst. Signal Process. 86, 66–81 (2017)CrossRef
8.
Baqersad, J., Poozesh, P., Niezrecki, C., Avitabile, P.: Photogrammetry and optical methods in structural dynamics–a review. Mech. Syst. Signal Process. 86, 17–34 (2016)CrossRef
9.
Castellini, P., Martarelli, M., Tomasini, E.P.: Laser Doppler Vibrometry: development of advanced solutions answering to technology's needs. Mech. Syst. Signal Process. 20, 1265–1285 (2006)CrossRef
10.
Ebrahimkhanlou, A., Farhidzadeh, A., Salamone, S.: Multifractal analysis of crack patterns in reinforced concrete shear walls. Struct. Health Monit. 15(1), 81–92 (2016)CrossRef
11.
Poozesh, P., Baqersad, J., Niezrecki, C., Avitabile, P., Harvey, E., Yarala, R.: Large-area photogrammetry based testing of wind turbine blades. Mech. Syst. Signal Process. 86, 98–115 (2016)CrossRef
12.
Sarrafi, A., Mao, Z.: Wind turbine blade damage detection via 3-dimensional phase-based motion estimation. Struct. Health Monit. 2017, 2545–2552 (2017)
13.
Cheli, F., Mazzoleni, P., Pezzola, M., Ruspini, E., Zappa, E.: Vision-based measuring system for rider's pose estimation during motorcycle riding. Mech. Syst. Signal Process. 38, 399–410 (2013)CrossRef
14.
Baqersad, M., Hamedi, A., Mohammadafzali, M., Ali, H.: Asphalt mixture segregation detection: digital image processing approach. Adv. Mater. Sci. Eng. 2017, 1–6 (2017)
15.
Sarrafi, A., Poozesh, P., Mao, Z.: A comparison of computer-vision-based structural dynamics characterizations. In: Model Validation and Uncertainty Quantification, vol. 3, pp. 295–301. Springer, Cham (2017)CrossRef
16.
Javh, J., Slavič, J., Boltežar, M.: The subpixel resolution of optical-flow-based modal analysis. Mech. Syst. Signal Process. 88, 89–99 (2017)CrossRef
17.
Fleet, D., Weiss, Y.: Optical flow estimation. In: Handbook of Mathematical Models in Computer Vision, pp. 237–257. Springer, Boston (2006)CrossRef
18.
Baker, S., Matthews, I.: Lucas-kanade 20 years on: a unifying framework. Int. J. Comput. Vis. 56, 221–255 (2004)CrossRef
19.
Horn, B.K., Schunck, B.G.: Determining optical flow. Artif. Intell. 17, 185–203 (1981)CrossRef
20.
Fleet, D.J., Jepson, A.D.: Computation of component image velocity from local phase information. Int. J. Comput. Vis. 5, 77–104 (1990)CrossRef
21.
Wadhwa, N., Rubinstein, M., Durand, F., Freeman, W.T.: Phase-based video motion processing. ACM Trans. Graph. (TOG). 32, 80 (2013)CrossRef
22.
Chen, J.G., Wadhwa, N., Cha, Y.-J., Durand, F., Freeman, W.T., Buyukozturk, O.: Modal identification of simple structures with high-speed video using motion magnification. J. Sound Vib. 345, 58–71 (2015)CrossRef
23.
Wadhwa, N., Rubinstein, M., Durand, F., Freeman, W. T.: Riesz pyramids for fast phase-based video magnification. US Patent 9,338,331, 2016
24.
Yang, Y., Dorn, C., Mancini, T., Talken, Z., Kenyon, G., Farrar, C., et al.: Blind identification of full-field vibration modes from video measurements with phase-based video motion magnification. Mech. Syst. Signal Process. 85, 567–590 (2017)CrossRef
25.
Yang, Y., Dorn, C., Mancini, T., Talken, Z., Theiler, J., Kenyon, G., et al.: Reference-free detection of minute, non-visible, damage using full-field, high-resolution mode shapes output-only identified from digital videos of structures. Struct. Health Monit. 0, 1475921717704385 (2017)
26.
Sarrafi, A., Poozesh, P., Niezrecki, C., Mao, Z.: Mode extraction on wind turbine blades via phase-based video motion estimation. In SPIE Smart Structures and Materials+ Nondestructive Evaluation and Health Monitoring, pp. 101710E-101710E-12 (2017)
27.
Poozesh, P., Sarrafi, A., Mao, Z., Avitabile, P., Niezrecki, C.: Feasibility of extracting operating shapes using phase-based motion magnification technique and stereo-photogrammetry. J. Sound Vib. 407, 350–366 (2017)CrossRef
28.
Sarrafi, A., Mao, Z.: Uncertainty quantification of phase-based motion estimation on noisy sequence of images. In SPIE Smart Structures and Materials+ Nondestructive Evaluation and Health Monitoring, pp. 101702M–101702M-8 (2017)
29.
Freeman, W.T., Adelson, E.H.: The design and use of steerable filters. IEEE Trans. Pattern Anal. Mach. Intell. 13, 891–906 (1991)CrossRef
Metadata
Title
Using 2D Phase-Based Motion Estimation and Video Magnification for Binary Damage Identification on a Wind Turbine Blade
Authors
Aral Sarrafi
Zhu Mao
Copyright Year
2019
Book
Model Validation and Uncertainty Quantification, Volume 3

Print ISBN: 978-3-319-74792-7

Electronic ISBN: 978-3-319-74793-4

Copyright Year: 2019

DOI
https://doi.org/10.1007/978-3-319-74793-4_19

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