[1] D NAM, J H LEE, Y H CHO et al. Flat panel light-field 3-D display: concept, design, rendering, and calibration. Proceedings of the IEEE, 105, 876-891(2017).

[2] K LI, A Ö YöNTEM, Y DENG et al. Full resolution auto-stereoscopic mobile display based on large scale uniform switchable liquid crystal micro-lens array. Optics Express, 25, 9654-9675(2017).

[3] J HUA, D YI, W QIAO et al. Multiview holographic 3D display based on blazed Fresnel DOE. Optics Communications, 472, 125829(2020).

[4] Y SU, Z CAI, L SHI et al. Dual-view holographic three-dimensional display using a single spatial light modulator and a directional light-guide plate composed of pixelated gratings. Applied Optics, 58, 6912-6919(2019).

[5] Liangcai CAO, Zehao HE, Kexuan LIU. Progress and challenges in dynamic holographic 3D display for the metaverse (Invited). Infrared and Laser Engineering, 51, 20210935(2022).

[6] ZHAO. R, SAIN B, WEI Q, et al. Multichannel vectorial holographic display and encryption. Light: Science & Applications, 7, 95(2018).

[7] Z YUE, G XUE, J LIU et al. Nanometric holograms based on a topological insulator material. Nature Communications, 8, 15354(2017).

[8] K C KWON, Y T LIM, C W SHIN et al. Enhanced depth-of-field of an integral imaging microscope using a bifocal holographic optical element-micro lens array. Optics Letters, 42, 3209-3212(2017).

[9] Chao ZUO, Xiaolei ZHANG, Yan HU. Has 3D finally come of age? ——An introduction to 3D structured-light sensor. Infrared and Laser Engineering, 49, 0303001-0303001-45(2020).

[10] Y MENG, Z YU, C ZHANG et al. Numerical simulation and experimental verification of a dense multi-view full-resolution autostereoscopic 3D-display-based dynamic shutter parallax barrier. Applied Optics, 58, A228-A233(2019).

[11] RANIERI N, HEINZLE S, SMITHWICK Q, et al. Multi‐layered automultiscopic displays [C]Computer Graphics Fum. Oxfd, UK: Blackwell Publishing Ltd., 2012, 31(7): 21352143.

[12] S U KIM, J KIM, J H SUH et al. Concept of active parallax barrier on polarizing interlayer for near-viewing autostereoscopic displays. Optics Express, 24, 25010-25018(2016).

[13] T HUANG, B HAN, X ZHANG et al. High-performance autostereoscopic display based on the lenticular tracking method. Optics Express, 27, 20421-20434(2019).

[14] L YANG, X SANG, X YU et al. Demonstration of an improved integral imaging with large viewing angle based on two crossed lenticular lens combined arrays. Optik, 172, 578-584(2018).

[15] M H SONG, J S JEONG, M U ERDENEBAT et al. Integral imaging system using an adaptive lens array. Applied Optics, 55, 6399-6403(2016).

[16] Y SU, Z CAI, Q LIU et al. Binocular holographic three-dimensional display using a single spatial light modulator and a grating. JOSA A, 35, 1477-1486(2018).

[17] S BANERJI, M MEEM, A MAJUMDER et al. Imaging with flat optics: metalenses or diffractive lenses?. Optica, 6, 805-810(2019).

[18] C CHANG, W CUI, L GAO. Foveated holographic near-eye 3D display. Optics Express, 28, 1345-1356(2020).

[19] WAN W, QIAO W, PU D, et al. Holographic sampling display based on metagratings[J]. iScience , 2020, 23(1): 100773.

[20] J SHI, W QIAO, J HUA et al. Spatial multiplexing holographic combiner for glasses-free augmented reality. Nanophotonics, 9, 3003-3010(2020).

[21] F ZHOU, F ZHOU, Y CHEN et al. Vector light field display based on an intertwined flat lens with large depth of focus. Optica, 9, 288-294(2022).

[22] Xingjian XIAO, Shining ZHU, Tao LI. Design and parametric analysis of the broadband achromatic flat lens. Infrared and Laser Engineering, 49, 20201032(2020).