[1] Chen Y B[M]. Modern laser welding technology(2006).

[2] Chen W Z[M]. Quality control of laser welding and cutting(2010).

[3] Zhang M J, Zhang Z, Tang K et al. Analysis of mechanisms of underfill in full penetration laser welding of thick stainless steel with a 10 kW fiber laser[J]. Optics & Laser Technology, 98, 97-105(2018).

[4] Dubey A K, Yadava V. Laser beam machining—a review[J]. International Journal of Machine Tools and Manufacture, 48, 609-628(2008).

[5] Ma Y R, Cai C, Liu Z J et al. Plasma monitoring during laser-MIG hybrid welding process based on LabVIEW[J]. Chinese Journal of Lasers, 49, 0202014(2022).

[6] Hong K M, Shin Y C. Prospects of laser welding technology in the automotive industry: a review[J]. Journal of Materials Processing Technology, 245, 46-69(2017).

[7] Chen G Y, Mei L F, Zhang M J et al. Application and research of laser processing automobile body manufacturing[J]. Laser & Optoelectronics Progress, 46, 17-23(2009).

[8] Cai H, Xiao R S. Statistic analysis on spatter characteristics in high power CO2 laser and fiber laser welding of thin sheet aluminum alloy[J]. Transactions of the China Welding Institution, 34, 27-30, 114(2013).

[9] Kawahito Y, Wang H Z, Katayama S et al. Ultra high power (100 kW) fiber laser welding of steel[J]. Optics Letters, 43, 4667-4670(2018).

[10] Li S C, Chen G Y, Katayama S et al. Relationship between spatter formation and dynamic molten pool during high-power deep-penetration laser welding[J]. Applied Surface Science, 303, 481-488(2014).

[11] Kaplan A F H, Powell J. Spatter in laser welding[J]. Journal of Laser Applications, 23, 032005(2011).

[12] Volpp J. Keyhole stability during laser welding—part II: process pores and spatters[J]. Production Engineering, 11, 9-18(2017).

[13] Gao X D, Wen Q, Katayama S. Analysis of high-power disk laser welding stability based on classification of plume and spatter characteristics[J]. Transactions of Nonferrous Metals Society of China, 23, 3748-3757(2013).

[14] Jiang B, Huang R S, Li L L et al. Study on laser welding technology of 10 thousand watt fiber[J]. Electric Welding Machine, 51, 8-14, 151(2021).

[15] Cai W, Wang J Z, Jiang P et al. Application of sensing techniques and artificial intelligence-based methods to laser welding real-time monitoring: a critical review of recent literature[J]. Journal of Manufacturing Systems, 57, 1-18(2020).

[16] Miao R, Gao Y T, Ge L et al. Online defect recognition of narrow overlap weld based on two-stage recognition model combining continuous wavelet transform and convolutional neural network[J]. Computers in Industry, 112, 103115(2019).

[17] Zhang M J. Steam behavior and defect control of thick plate welded by 10 thousand watt fiber laser deep penetration welding[D](2013).

[18] Chen X, Zhang X S, Pang S Y et al. Vapor plume oscillation mechanisms in transient keyhole during tandem dual beam fiber laser welding[J]. Optics and Lasers in Engineering, 100, 239-247(2018).

[19] Wu D S, Hua X M, Li F et al. Understanding of spatter formation in fiber laser welding of 5083 aluminum alloy[J]. International Journal of Heat and Mass Transfer, 113, 730-740(2017).

[20] Gao X D, Sun Y, Katayama S. Neural network of plume and spatter for monitoring high-power disk laser welding[J]. International Journal of Precision Engineering and Manufacturing-Green Technology, 1, 293-298(2014).

[21] Wang D, Dou W H, Ou Y H et al. Characteristics of droplet spatter behavior and process-correlated mapping model in laser powder bed fusion[J]. Journal of Materials Research and Technology, 12, 1051-1064(2021).

[22] Nakamura H, Kawahito Y, Nishimoto K et al. Elucidation of melt flows and spatter formation mechanisms during high power laser welding of pure titanium[J]. Journal of Laser Applications, 27, 032012(2015).

[23] Zhang M J, Chen G Y, Zhou Y et al. Observation of spatter formation mechanisms in high-power fiber laser welding of thick plate[J]. Applied Surface Science, 280, 868-875(2013).

[24] Katayama S, Kawahito Y, Mizutani M. Elucidation of laser welding phenomena and factors affecting weld penetration and welding defects[J]. Physics Procedia, 5, 9-17(2010).

[25] Kawahito Y, Mizutani M, Katayama S. High quality welding of stainless steel with 10 kW high power fibre laser[J]. Science and Technology of Welding and Joining, 14, 288-294(2009).

[26] Yin J, Hao L, Yang L L et al. Investigation of interaction between vapor plume and spatter during selective laser melting additive manufacturing[J]. Chinese Journal of Lasers, 49, 1402202(2022).

[27] Zhang G L, Kong H, Zou J L et al. Spatter characteristics of high-power fibre laser deep penetration welding and effect of defocus on spatter[J]. Chinese Journal of Lasers, 48, 2202008(2021).

[28] Huang Y, Hua X M, Li F et al. Spatter feature analysis in laser welding based on motion tracking method[J]. Journal of Manufacturing Processes, 55, 220-229(2020).

[29] Xia X M, Jiang Z L, Xu P F. A detection algorithm of spatter on welding plate surface based on machine vision[J]. Optoelectronics Letters, 15, 52-56(2019).

[30] You D Y, Gao X D, Katayama S. Monitoring of high-power laser welding using high-speed photographing and image processing[J]. Mechanical Systems and Signal Processing, 49, 39-52(2014).

[31] Li Y J, Fan X, Long G F et al. Spatter dynamic recognition and feature analysis during high-power disk laser welding[J]. Acta Photonica Sinica, 50, 0214002(2021).

[32] Zheng Y F, Liu S R, Zhang Q L et al. Influence of arc power on droplet transfer and spatter in high power laser-arc hybrid welding[J]. Chinese Journal of Lasers, 50, 1202107(2023).