[1] Lee E, Kim T, Suh H, et al. Effect of metal thickness on the sensitivity of crack-based sensors[J]. Sensors, 2018, 18(9): 2872.

[2] Zhao L, Li C J, Duan Z X, et al. The metal thickness detection using pulsed eddy-current computation and detection method[J]. Cluster Computing, 2019, 22: 6551-6562.

[3] Kravcov A, Shibaev I A, Blokhin D I, et al. Examination of structural members of aerial vehicles by laser ultrasonic structuroscopy[J]. International Journal of Civil Engineering and Technology, 2018, 9(11): 2258-2265.

[4] Kusano M, Hatano H, Watanabe M, et al. Mid-infrared pulsed laser ultrasonic testing for carbon fiber reinforced plastics[J]. Ultrasonics, 2018, 84: 310-318.

[5] Yan G Q, Raetz S, Chigarev N, et al. Characterization of progressive fatigue damage in solid plates by laser ultrasonic monitoring of zero-group-velocity lamb modes[J]. Physical Review Applied, 2018, 9(6): 061001.

[6] Zarubin V, Bychkov A, Zhigarkov V, et al. Model-based measurement of internal geometry of solid parts with sub-PSF accuracy using laser-ultrasonic imaging[J]. NDT & E International, 2019, 105: 56-63.

[7] Zhou Z G, Zhang K S, Zhou J H, et al. Application of laser ultrasonic technique for non-contact detection of structural surface-breaking cracks[J]. Optics & Laser Technology, 2015, 73: 173-178.

[8] 睢晓乐, 肖夏, 戚海洋, 等. 残余应力对激光激发超声表面波技术检测二氧化硅体材料杨氏模量的影响[J]. 激光与光电子学进展, 2017, 54(12): 121202.

    Sui X L, Xiao X, Qi H Y, et al. Influence of residual stress on young modulus detection of SiO2 bulk materials by laser-induced surface ultrasonic wave technique[J]. Laser & Optoelectronics Progress, 2017, 54(12): 121202.

[9] Sun G K, Zhou Z G, Li G H, et al. Development of an optical fiber-guided robotic laser ultrasonic system for aeronautical composite structure testing[J]. Optik, 2016, 127(12): 5135-5140.

[10] 张闯, 刘成立, 刘素贞, 等. 基于电磁加载的铝板应力超声检测[J]. 仪器仪表学报, 2018, 39(8): 169-177.

    Zhang C, Liu C L, Liu S Z, et al. Ultrasonic detection of aluminumstress based on electromagnetic loading[J]. Chinese Journal of Scientific Instrument, 2018, 39(8): 169-177.

[11] He J P, Dixon S, Hill S, et al. A new electromagnetic acoustic transducer design for generating and receiving S0 lamb waves in ferromagnetic steel plate[J]. Sensors, 2017, 17(5): 1023.

[12] Murav'eva O V, Len'kov S V, Murashov S A. Torsional waves excited by electromagnetic-acoustic transducers during guided-wave acoustic inspection of pipelines[J]. Acoustical Physics, 2016, 62(1): 117-124.

[13] Zhang Y, Huang S L, Wang S, et al. Direction-controllable electromagnetic acoustic transducer for SH waves in steel plate based on magnetostriction[J]. Progress In Electromagnetics Research M, 2016, 50: 151-160.

[14] Huang S L, Zhang Y, Wang S, et al. Multi-mode electromagnetic ultrasonic lamb wave tomography imaging for variable-depth defects in metal plates[J]. Sensors, 2016, 16(5): 628.

[15] Finkel P, Godinez V. Electromagnetic stimulation of the ultrasonic signal for nondestructive detection of ferromagnetic inclusions and flaws[J]. IEEE Transactions on Magnetics, 2004, 40(4): 2179-2181.

[16] Ribichini R, Cegla F, Nagy P, et al. Study and comparison of different EMAT configurations for SH wave inspection[J]. IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 2011, 58(12): 2571-2581.

[17] 杨理践, 邢燕好, 张佳, 等. 基于电磁超声导波的铝板裂纹缺陷检测方法[J]. 仪器仪表学报, 2018, 39(4): 150-160.

    Yang L J, Xing Y H, Zhang J, et al. Crack defect detection of aluminum plate based on electromagnetic ultrasonic guided wave[J]. Chinese Journal of Scientific Instrument, 2018, 39(4): 150-160.