[1] Zhong M. Radiation effects on optical properties and laser damage performance of sapphire and fused silica[D]. Chengdu: University of Electronic Science and Technology of China, 6-8(2016).
[4] Wang S H, Luo G. Naturalness preserved image enhancement using a priori multi-layer lightness statistics[J]. IEEE Transactions on Image Processing, 27, 938-948(2018).
[6] Si S H, Hu F Y, Gu Y J et al. Improved denoising algorithm based on non-regular area Gaussian filtering[J]. Computer Science, 41, 313-316(2014).
[8] Duncan M D, Bashkansky M, Reintjes J. Subsurface defect detection in materials using optical coherence tomography[J]. Optics Express, 2, 540-545(1998).
[9] Chen J, You Z, Zhou Z Y et al. A new laser non-destructive method of detecting micro/nano bulk defects in silicon materials[J]. Applied Laser, 17, 54-56, 68(1997).
[10] Williams W B. A novel fluorescence based method of assessing subsurface damage in optical materials[D]. Charlotte: The University of North Carolina, 45-47(2009).
[13] Neauport J, Cormont P, Legros P et al. Imaging subsurface damage of grinded fused silica optics by confocal fluorescence microscopy[J]. Optics Express, 17, 3543-3554(2009).
[14] Herman G T, Liu H K. Three-dimensional display of human organs from computed tomograms[J]. Computer Graphics and Image Processing, 9, 1-21(1979).
[15] Schroeder W J, Lorensen B, Martin K. The visualization toolkit: an object-oriented approach to 3D graphics[M]. 3rd ed. New York: Kitware, 178-180(2004).
[16] Lorensen W E, Cline H E. Marching cubes: a high resolution 3D surface construction algorithm[J]. ACM SIGGRAPH Computer Graphics, 21, 163-169(1987).
[18] Du X R, Zhang X Q, Wang H et al. Study of subsurface damage in polished silica glass[J]. Bulletin of the Chinese Ceramic Society, 36, 47-49, 77(2017).
[19] Wang H X, Zhu B W, Wang J H et al. Subsurface defects detection for the polishing surface of fused silica optics[J]. Materials Science and Technology, 23, 8-12(2015).