Partition and Time Division Multiplexing Retinal Projection Display Based on Human Visual Characteristics

Zichao WEI; Yimin LOU; Juanmei HU; Fengmin WU

doi:10.3788/gzxb20225105.0511001

[1] Xin YANG, Shuming JIAO, Qiang SONG et al. Computer generated phase-only rainbow holographic near-eye display. Acta Optica Sinica, 41, 2209001(2021).

[2] Shujun XING, Liangcai CAO, Xinzhu SANG et al. Overview of virtual stereo content generation technology for super multi-view light field. Chinese Journal of Lasers, 48, 1509001(2021).

[3] Junguo LIN, Qiang CONG, Chen XU et al. Design of MEMS laser scanning retinal projection display system. Acta Optica Sinica, 37, 1222001(2017).

[4] Y TAKAKI, N FUJIMOTO. Flexible retinal image formation by holographic Maxwellian-view display. Optics Express, 26, 22985-22999(2018).

[5] M DAVID. Vergence-accommodation conflicts hinder visual performance and cause visual fatigue. Journal of Vision, 8, 33-33(2008).

[6] J LIN, D CHENG, Y CHENG et al. Retinal projection head-mounted display. Frontiers of Optoelectronics, 10, 1-8(2017).

[7] A YUUKI, K ITOGA, T SATAKE. A new Maxwellian view display for trouble-free accommodation. Journal of the Society for Information Display, 20, 581-588(2012).

[8] S KIM, J PARK. Optical see-through Maxwellian near-to-eye display with an enlarged eyebox. Optics Letters, 43, 767-770(2018).

[9] M K HEDILI, B SONER, E ULUSOY et al. Light-efficient augmented reality display with steerable eyebox. Optics Express, 27, 12572-12581(2019).

[10] C CHANG, W CUI, J PARK et al. Computational holographic Maxwellian near-eye display with an expanded eyebox. Scientific Reports, 9, 18749(2019).

[11] X SHI, J LIU, Z ZHANG et al. Extending eyebox with tunable viewpoints for see-through near-eye display. Optics Express, 29, 11613-11626(2021).

[12] H TAKAHASHI, Y ITO, S NAKATA et al. Retinal projection type super multi-view head-mounted display, 9012, 90120L(2014).

[13] C JANG, K BANG, S MOON et al. Retinal 3D: augmented reality near-eye display via pupil-tracked light field projection on retina. ACM Transactions on Graphics, 36, 190(2017).

[14] T UENO, Y TAKAKI. Super multi-view near-eye display to solve vergence-accommodation conflict. Optics Express, 26, 30703-30715(2018).

[15] T UENO, Y TAKAKI. Approximated super multi-view head-mounted display to reduce visual fatigue. Optics Express, 28, 14134-14150(2020).

[16] A PATNEY, M SALVI, J KIM et al. Towards foveated rendering for gaze-tracked virtual reality. ACM Transactions on Graphics, 35, Article 179(2016).

[17] Y JU, J PARK. Foveated computer-generated hologram and its progressive update using triangular mesh scene model for near-eye displays. Optics Express, 27, 23725-23738(2019).

[18] J HUA, E HUA, F ZHOU et al. Foveated glasses-free 3D display with ultrawide field of view via a large-scale 2D-metagrating complex. Light: Science & Applications, 10, 213(2021).

[19] Y TAKAKI, K TANAKA, J NAKAMURA. Super multi-view display with a lower resolution flat-panel display. Optics Express, 19, 4129-4139(2011).

[20] Zhe AN, Xiping XU, Jinhua YANG et al. Calibration method of optical transmission AR-HUD system. Acta Photonica Sinica, 48, 0412002(2019).

[21] Yuan JI, Yuansheng SONG, Yuansheng CHEN et al. Bit-plane motion estimation for digitally driven near-eye display. Acta Photonica Sinica, 50, 0710001(2021).