[1] [1] Carmigniani J, Furht B, Anisetti M, et al. Augmented reality technologies, systems and applications［J］. Multimedia Tools & Applications, 2011, 51(1)： 341-377.

[2] [2] Kress B C, Cummings W J. 11‐1： Invited paper： Towards the ultimate mixed reality experience： Hololens display architecture choices［J］. SID Symposium Digest of Technical Papers, 2017, 48(1)： 127-131.

[3] [3] Google. Glass Enterprise Edition 2［EB/OL］. https：//www.google.com/glass/tech-specs.html.

[4] [4] Magic Leap Corporation. Magic Leap One Creator Edition［EB/OL］. https：//www.magicleap.com/en-us/magic-leap-1.html.

[5] [5] Koulieris G A, Bui B, Banks M S, et al. Accommodation and comfort in head-mounted displays［J］. ACM Trans. Graph, 2017, 36(4)： 87.

[6] [6] Kim D, Lee S, Moon S, et al. Hybrid multi-layer displays providing accommodation cues［J］. Optics Express, 2018, 26(13)： 17170.

[7] [7] Lee S, Cho J, Lee B, et al. Foveated retinal optimization for see-through near-eye multi-layer displays［J］. IEEE Access, 2017, 6： 2170-2180.

[8] [8] Westheimer G. The maxwellian view［J］. Vision Research, 1966, 6(11-12)： 669-682.

[9] [9] Kim S B, Park J H. Optical see-through Maxwellian near-to-eye display with an enlarged eyebox［J］. Optics Letters, 2018, 43(4)：767.

[10] [10] Yasuhiro, Takaki, Naohiro, et al. Flexible retinal image formation by holographic Maxwellian-view display［J］. Optics Express, 2018, 26(18)： 22985-22999.

[11] [11] Park J H, Hong K, Lee B. Recent progress in three-dimensional information processing based on integral imaging［J］. Applied Optics, 2009, 48(34)： 77-94.

[14] [14] Hua H, Javidi B. A 3D integral imaging optical see-through head-mounted display［J］. Optics Express, 2014, 22(11)： 13484-13491.

[15] [15] Cheng D, Wang Y, Hong H, et al. Design of a wide-angle, lightweight head-mounted display using free-form optics tiling［J］. Optics Letters, 2011, 36(11)： 2098-2100.

[16] [16] Qin Z, Wu J Y, Chou P Y, et al. Revelation and addressing of accommodation shifts in microlens array-based 3D near-eye light field displays［J］. Optics Letters, 2020, 45(1)： 228-231.

[17] [17] Chanhyung, Yoo, Kiseung, et al. Dual-focal waveguide see-through near-eye display with polarization-dependent lenses［J］. Optics Letters, 2019, 44(8)： 1920-1923.

[18] [18] Ao L, Zhang Y, Weng Y, et al. Diffraction efficiency distribution of output grating in holographic waveguide display system［J］. IEEE Photonics Journal, 2018, 10(4)： 1-10.

[19] [19] Changwon, Jang, Chang-Kun, et al. Recent progress in see-through three-dimensional displays using holographic optical elements ［Invited］［J］. Applied Optics, 2016, 55(3)： A71-A85.

[20] [20] Hong K, Yeom J, Jang C, et al. Two-dimensional and three-dimensional transparent screens based on lens-array holographic optical elements［J］. Optics Express, 2014, 22(12)： 14363-14374.

[21] [21] Keehoon, Hong, Jiwoon, et al. Full-color lens-array holographic optical element for three-dimensional optical see-through augmented reality［J］. Optics Letters, 2014, 39(1)： 127-130.

[22] [22] Zhang H L, Deng H, Yu W T, et al. Tabletop augmented reality 3D display system based on integral imaging［J］. Journal of the Optical Society of America B, 2017, 34(5)： B16.

[23] [23] Deng H, Chen C, et al. High-resolution augmented reality 3D display with use of a lenticular lens array holographic optical element［J］. Journal of the Optical Society of America A, 2019, 36(4)： 588-593.

[24] [24] Wakunami K, Hsieh P Y, Oi R, et al. Projection-type see-through holographic three-dimensional display［J］. Nature Communications, 2016, 7(1)： 1-7.

[25] [25] Jessie J B, Lode J, Ryutaro O, et al. Digitally designed holographic optical element for light field displays［J］. Optics Letters, 2018, 43(15)： 3738-3741.

[26] [26] Luo C G, Deng H, Li L, et al. Integral imaging pickup method with extended depth-of-field by gradient-amplitude modulation［J］. Journal of Display Technology, 2016, 12(10)： 1205-1211.