[1] B Park, H Sohn, P Malinowski, et al. Delamination localization in wind turbine blades based on adaptive time-of-flight analysis of noncontact laser ultrasonic signals. Nondestructive Testing and Evaluation, 32, 1-20(2017).

[2] Y Sohn, S Krishnaswamy. Interaction of a scanning laser-generated ultrasonic line source with a surface-breaking flaw. The Journal of the Acoustical Society of America, 115, 172-181(2004).

[3] H Kim, K Jhang, M Shin, et al. A noncontact NDE method using a laser generated focused-Lamb wave with enhanced defect-detection ability and spatial resolution. NDT & E International, 39, 312-319(2006).

[4] P P Liu, H Sohn, T Kundu, et al. Noncontact detection of fatigue cracks by laser nonlinear wave modulation spectroscopy (LNWMS). NDT & E International, 66, 106-116(2014).

[5] S Choi, H Seo, K Y Jhang. Noncontact evaluation of acoustic nonlinearity of a laser-generated surface wave in a plastically deformed aluminum alloy. Research in Nondestructive Evaluation, 26, 13-22(2015).

[6] H Sohn, D Dutta, J Yang, et al. Automated detection of delamination and disbond from wavefield images obtained using a scanning laser vibrometer. Smart Materials and Structures, 20, 045017(2011).

[7] Ruzzene M. Frequency–wavenumber domain filtering f improved damage visualization[C]AIP Conference Proceedings, 2007, 894(1): 1556.

[8] P Celli, S Gonella. Laser-enabled experimental wavefield reconstruction in two-dimensional phononic crystals. Journal of Sound and Vibration, 333, 114-123(2014).

[9] S Yashiro, J Takatsubo, N Toyama. An NDT technique for composite structures using visualized Lamb-wave propagation. Composites Science and Technology, 67, 3202-3208(2007).

[10] W J Staszewski, B C Lee, L Mallet, et al. Structural health monitoring using scanning laser vibrometry: I. Lamb wave sensing. Smart Materials and Structures, 13, 251-260(2004).

[11] B Park, Y K An, H Sohn, et al. Visualization of hidden delamination and debonding in composites through noncontact laser ultrasonic scanning. Composites Science and Technology, 100, 10-18(2014).

[12] Y K An, B Park, H Sohn, et al. Complete noncontact laser ultrasonic imaging for automated crack visualization in a plate. Smart Materials and Structures, 22, 025022(2013).

[13] T E Michaels, J E Michaels, M Ruzzene. Frequency-wavenumber domain analysis of guided wavefields. Ultrasonics, 51, 452-466(2011).

[14] P P Liu, H Sohn, B Park. Baseline-free damage visualization using noncontact laser nonlinear ultrasonics and state space geometrical changes. Smart Materials and Structures, 24, 065036(2015).

[15] B Park, H Sohn. Accelerated damage visualization using binary search with fixed pitch-catch distance laser ultrasonic scanning. Smart Materials and Structures, 26, 075005(2017).

[16] Lingjuan Yu, Xiaochun Xie. Brief introduction of compressed sensing theory. Video Engineering, 32, 16-18(2008).

[17] D L Donoho. Compressed sensing. IEEE Transactions on Information Theory, 52, 1289-1306(2006).

[18] De Marchi L, Cera G, Guido M. Compressive sensing of full field images in Lamb waves inspections[C]2013 IEEE International Ultrasonics Symposium (IUS), 2013: 154157.

[19] Ianni T Di, Marchi L De, A Perelli, et al. Compressive sensing of full wave field data for structural health monitoring applications. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 62, 1373-1383(2015).

[20] Park B, Sohn H. Reconstruction of laser ultrasonic wavefield images from reduced sparse measurements using compressed sensing aided superresolution[C]AIP Conference Proceedings, 2017, 1806(1): 030003.

[22] Achenbach J. Wave Propagation in Elastic Solids[M]. Amsterdam: Elsevier, 2012.

[23] Neapolitan R E, Naimipour K. Foundations of Algithms[M]. Burlington: Jones & Bartlett Learning, 1997.

[24] A Grinsted, J Moore, S Jevrejeva. Application of the cross wavelet transform and wavelet coherence to geophysical time series. Nonlinear Processes in Geophysics, 11, 561-566(2004).

[25] Gang Wang, Ruofei Zhou, Yikun Zou. Research on image optimization technology based on compressed sensing. Journal of Electronics & Information Technology, 42, 222-233(2020).

[26] Siyuan He, Guiyuan Li, Huajiao Liu, et al. Application and research of optimal wavelet base selection method in seismic data processing. South China Journal of Seismology, 39, 49-56(2019).

[27] Sihai You, Hongli Wang, Lei Feng, et al. Pulsar TOA estimation based on wavelet transform and compressed sensing. Infrared and Laser Engineering, 49, 0226001(2020).

[28] Zhang D. Fundamentals of Image Data Mining[M]. Cham: Springer, 2019: 3544.

[30] Menglu Qian. Laser ultrasonic technigue and its applications. Shanghai Measurement and Testing, 30, 4-7(2003).

[31] Wang Jie. Research on feature extraction imaging method using laser ultrasonic of laminated composites[D]. Taiyuan: Nth University of China, 2020. (in Chinese)

[32] A Zymnis, S Boyd, E Candes. Compressed sensing with quantized measurements. IEEE Signal Processing Letters, 17, 149-152(2009).

[33] Zhiqiang Xu. Compressed sensing: A survey. Scientia Sinica Mathematica, 42, 865-877(2012).

[34] M Elad. Optimized projections for compressed sensing. IEEE Transactions on Signal Processing, 55, 5695-5702(2007).

[35] Y Tsaig, D L Donoho. Extensions of compressed sensing. Signal Processing, 86, 549-571(2006).

[36] A C Gilbert, M J Strauss, J A Tropp, et al. Algorithmic linear dimension reduction in the l_1 norm for sparse vectors. arXiv, cs/0608079(2006).

[37] Z Jiang, T Zhang, X Huang, et al. Trade-off relations of l_1-norm coherence for multipartite systems. Quantum Information Processing, 19, 92(2020).

[38] A V Karkanitsa. Models, algorithms, and architecture for generating adaptive decision support systems. Pattern Recognition and Image Analysis, 30, 174-183(2020).

[39] M A T Figueiredo, R D Nowak, S J Wright. Gradient projection for sparse reconstruction: Application to compressed sensing and other inverse problems. IEEE Journal of Selected Topics in Signal Processing, 1, 586-597(2007).

[40] C Y Ni, C Chen, K N Ying, et al. Non-destructive laser-ultrasonic Synthetic Aperture Focusing Technique (SAFT) for 3D visualization of defects. Photoacoustics, 22, 100248(2021).

[41] Chu Chen, Kaining Ying, Nian Liu, et al. Application of phase shift migration method in laser ultrasonic SAFT. Chinese Journal of Lasers, 48, 0304001(2021).