[1] Gibson R F. A review of recent research on mechanics of multifunctional composite materials and structures[J]. Composite Structures, 92, 2793-2810(2010).

[2] Zhan X L, Zhao W T. Classification of carbon fiber reinforced polymer defects based on one-dimensional CNN[J]. Laser & Optoelectronics Progress, 57, 101013(2020).

[3] Gomes G F, Mendéz Y A D, da Silva Lopes Alexandrino P et al. The use of intelligent computational tools for damage detection and identification with an emphasis on composites: a review[J]. Composite Structures, 196, 44-54(2018).

[4] Heslehurst R B. Defects and damage in composite materials and structures[M]. Zhang X J, Zhang W, Zhang Y H, Transl(2017).

[5] Yang W B, Yuan S F, Qiu L et al. Prediction of fatigue crack propagation based on auxiliary particle filtering[J]. Journal of Vibration and Shock, 37, 114-119, 125(2018).

[6] Zhu L, Chen M, Jia M P. Approach for structural health assessment based on the Bayesian theory[J]. Journal of Vibration and Shock, 39, 59-63, 88(2020).

[7] Chen X F, Yang Z B, Tian S H et al. A review of the damage detection and health monitoring for composite structures[J]. Journal of Vibration,Measurement & Diagnosis, 38, 1-10, 202(2018).

[8] Qiu L, Yuan S F, Zhang X Y et al. Shannon complex wavelet and time reversal focusing based multi-damage imaging method on composite structures[J]. Acta Materiae Compositae Sinica, 27, 101-107(2010).

[9] Sharif-Khodaei Z, Aliabadi M H. Assessment of delay-and-sum algorithms for damage detection in aluminium and composite plates[J]. Smart Materials and Structures, 23, 075007(2014).

[10] Xu X J, Ji H L, Qiu J H et al. Interlaminar contact resistivity and its influence on eddy currents in carbon fiber reinforced polymer laminates[J]. NDT & E International, 94, 79-91(2018).

[11] Zhu Q, Qiu J H, Zhang C et al. Application of laser ultrasonic detection method for double-layer laminated material[J]. Laser & Optoelectronics Progress, 53, 031402(2016).

[12] Bao Q, Qiu L, Yuan S F. Development and challenges of PZT-guided wave based imaging technique in aircraft structural health monitoring[J]. Aeronautical Science & Technology, 31, 15-33(2020).

[13] Yan H, Zhou L. Damage identification of composite structures based on reconstruction algorithm for probabilistic inspection of damage[J]. Journal of Vibration and Shock, 31, 76-80(2012).

[14] Wu Z J, Liu K H, Wang Y S et al. Validation and evaluation of damage identification using probability-based diagnostic imaging on a stiffened composite panel[J]. Journal of Intelligent Material Systems and Structures, 26, 2181-2195(2015).

[15] Sharif-Khodaei Z, Rojas-Diaz R, Aliabadi M H. Lamb-wave based technique for impact damage detection in composite stiffened panels. Key Engineering Materials, 488/489, 5-8(2011).

[16] Liu B, Qiu L, Yuan S F et al. The probability imaging algorithm of composite T-joint damage monitoring[J]. Journal of Vibration,Measurement & Diagnosis, 35, 519-524, 593-594(2015).

[17] Tanaka H, Sharif Khodaei Z. Reliability assessment of SHM methodologies for damage detection[J]. Key Engineering Materials, 713, 244-247(2016).

[18] Liu G Q, Xiao Y C, Zhang H et al. Elliptical ring distribution probability-based damage imaging method for complex aircraft structures[J]. Journal of Vibroengineering, 19, 4936-4952(2017).

[19] Liu G Q, Xiao Y C, Zhang H et al. Probability-based diagnostic imaging for damage identification of stiffened composite panel[J]. Acta Materiae Compositae Sinica, 35, 311-319(2018).

[20] Saxena A, Goebel K, Larrosa C, Chang F. CFRP composites dataset[R]. Moffett Field: NASA Ames Research Center(2008).