[1] Yap C Y, Chua C K, Dong Z L, et al. Review of selective laser melting: Materials and applications[J]. Applied Physics Reviews, 2, 041101(2015).

[2] Zavala-Arredondo M, Boone N, Willmott J, et al. Laser diode area melting for high speed additive manufacturing of metallic components[J]. Materials & Design, 117, 305-315(2017).

[3] Matthews M J, Guss G, Drachenberg D R, et al. Diode-based additive manufacturing of metals using an optically-addressable light valve[J]. Optics express, 25, 11788-11800(2017).

[4] Zavala-Arredondo M, Groom K M, Mumtaz K. Diode area melting single-layer parametric analysis of 316L stainless steel powder[J]. The International Journal of Advanced Manufacturing Technology, 94, 2563-2576(2018).

[6] [6] Kamarudin K, Wahab M S, Raus A A, et al. Benchmarking of dimensional accuracy surface roughness f AlSi10Mg part by ive laser melting (SLM)[C]American Institute of Physics Conference Series. 2017.

[9] Zhao Yu, Yu Tianbiao, Sun Jiayu, et al. Effect of laser cladding on forming microhardness and tensile strength of YCF101 alloy powder in the different full lap joint modes[J]. Journal of Alloys and Compounds, 820, 150230(2020).

[10] Presotto A G C, Barão V A R, Bhering C L B, et al. Dimensional precision of implant-supported frameworks fabricated by 3D printing[J]. The Journal of Prosthetic Dentistry, 122, 38-45(2019).

[11] Lin Liu, Li Lin, Zhao Zhu, et al. A remote laser focusing system with spatial light modulator[J]. Computer Communications, 154, 92-98(2020).

[13] Uhlmann Eckart, Saber Yassin. Conceptualization of a measurement procedure for determination of characteristic properties of SLM produced parts by means of computed tomography[J]. Procedia Manufacturing, 47, 1016-1022(2020).

[14] Guo Meng, Gu Dongdong, Xi Lixia, et al. Formation of scanning tracks during selective laser melting (SLM) of pure tungsten powder: Morphology, geometric features and forming mechanisms[J]. International Journal of Refractory Metals and Hard Materials, 79, 37-46(2018).

[15] Liu Ning, Yang Chao. The elimination of zero-order diffraction of 10.6 μm infrared digital holography[J]. Infrared Physics and Technology, 82, 133-139(2017).

[16] Yurlov V, Lapchuk A, Sang K Y, et al. A study of image contrast restriction in displays using diffractive spatial light modulators[J]. Displays, 31, 15-24(2010).

[17] Weiner A M. Femtosecond pulse shaping using spatial light modulators[J]. Review of Scientific Instruments, 71, 1929-1960(2000).

[18] Li Nannan, Wang Di, Liu Chao, et al. Large-size holographic display method based on effective utilization of two spatial light modulators[J]. Optics Communications, 453, 124311(2019).

[19] Moreno I, Gutierrez B K, Sánchez-López M M, et al. Diffraction efficiency of stepped gratings using high phase-modulation spatial light modulators[J]. Optics and Lasers in Engineering, 126, 105910(2019).

[20] Li Sensen, Lu Zhiwei, Wang Yulei, et al. Spatial beam shaping for high-power frequency tripling lasers based on a liquid crystal spatial light modulator[J]. Optics Communications, 367, 181-185(2016).

[21] Wischeropp T M, Emmelmann C, Brandt M, et al. Measurement of actual powder layer height and packing density in a single layer in selective laser melting[J]. Additive Manufacturing, 28, 176-183(2019).