References
- Park JH, Kim J, Kim Y, et al. Resolution-enhanced three-dimension/two-dimension convertible display based on integral imaging. Opt Express. 2005;13:1875–1884.
- Cho SW, Park JH, Kim Y, et al. Convertible two-dimensional-three-dimensional display using an LED array based on modified integral imaging. Opt Lett. 2006;31:2852–2854.
- Choi H, Park JH, Kim J, et al. Wide-viewing-angle 3D/2D convertible display system suing two display devices and a lens array. Opt Express. 2005;13:8424–8432.
- Jung JH, Kim Y, Kim Y, et al. Integral imaging system using an electroluminescent film backlight for three-dimensional-two-dimensional convertibility and a curved structure. Appl Opt. 2009;48:998–1007.
- Park SG, Song BS, Min SW. 2D/3D convertible display with enhanced 3D viewing region based on integral imaging. Proc SPIE. 2010;7524:75240O.
- Lee TH, Joo KI, Kim HR. Switchable lens design for multi-view 2D/3D switching display with wide-viewing window. Crystals. 2020;10:418.
- Kim Y, Kim J, Kang JM, et al. Point light source integral imaging with improved resolution and viewing angle by the use of electrically movable pinhole array. Opt Express. 2007;15:18253–18267.
- Chou PY, Wu JY, Huang SH, et al. Hybrid light field head-mounted display using time-multiplexed liquid crystal lens array for resolution enhancement. Opt Express. 2019;27:164–177.
- Ren H, Xing Y, Zhang HL, et al. 2D/3D mixed display based on integral imaging and a switchable diffuser element. Appl Opt. 2019;58:G276–G281.
- Deng H, Li Q, and He W, et al. 2D/3D mixed frontal projection system based on integral imaging. Opt Express. 2020;28():26385–26394.
- Cao LC, Wang Z, and Zhang H, et al. Volume holographic printing using unconventional angular multiplexing for three-dimensional display. Appl Opt. 2016;55():6046–6051.
- He ZH, Sui XM, and Jin GF, et al. Optimal quantization for amplitude and phase in computer-generated holography. Opt Express. 2021;29():119–133.
- Rathinavel K, Wang HP, Blate A, et al. An extended depth-at-field volumetric near-eye augmented reality display. IEEE Trans Visual Comput Graphics. 2018;24:2857–2866.
- Suzuki K, Fukano Y, and Oku H. 1000-volume/s high-speed volumetric display for high-speed HMD. Opt Express. 2020;28():29455–29468.
- Liu SX, Li Y, and Zhou PC, et al. Reverse-mode PSLC multi-plane optical see-through display for AR applications. Opt Express. 2018;26():3394–3403.
- Lee B, Jung SY, Min SW, et al. Three-dimensional display by use of integral photography with dynamically variable image planes. Opt Lett. 2001;26:1481–1482.
- Choi H, Park JH, Hong J, et al. Depth-enhanced integral imaging with a stepped lens array or a composite lens array for three-dimensional display. Jpn J Appl Phys. 2004;43:5330–5336.
- Kwon KC, Erdenebat MU, Lim YT, et al. Enhancement of the depth-of-field of integral imaging microscope by using switchable bifocal liquid-crystalline polymer micro lens array. Opt Express. 2017;25:30503–30512.
- Park JH, Jung S, Choi H, et al. Integral imaging with multiple image planes using a uniaxial crystal plate. Opt Express. 2003;11:1862–1875.
- Jang JS, Javidi B. Large depth-of-focus time-multiplexed three-dimensional integral imaging by use of lenslets with nonuniform focal lengths and aperture sizes. Opt Lett. 2003;28:1924–1926.
- Wang X, Qin Y, Hua H, et al. Digitally switchable multi-focal lens using freeform optics. Opt Express. 2018;26:11007–11017.
- Kwon KC, Lim YT, Shin CW, et al. Enhanced depth-of-field of an integral imaging microscope using a bifocal holographic optical element-micro lens array. Opt Lett. 2017;42:3209–3212.
- Kim CJ, Chang M, Lee M, et al. Depth plane adaptive integral imaging using a varifocal liquid lens array. Appl Opt. 2015;54:2565–2571.
- Shin D, Kim C, Koo G, et al. Depth plane adaptive integral imaging system using a varifocal liquid lens array for realizing augmented reality. Opt Express. 2020;28:5602–5616.
- Algorri JF, Bennis N, Urruchi V, et al. Tunable liquid crystal multifocal microlens array. Sci Rep. 2017;7:17318.
- Min SW, Javidi B, Lee B. Enhanced three-dimensional integral imaging system by use of double display devices. Appl Opt. 2003;42:4186–4189.
- Ren H, Zhang HL, Xing Y, et al. Depth-enhanced integral imaging display system based on transmissive mirror device. J Soc Inf Display. 2020;51:1619–1622.
- Wang L, Deng H, Zhong FY, et al. Integral imaging display with enhanced depth of field based on bifocal lens array. J Soc Inf Display. 2021;29:1–8.
- Joo KI, Park MK, Park H, et al. Light-field camera for fast switching of time-sequential two-dimensional and three-dimensional image capturing at video rate. IEEE T Ind Electron. 2020;67:6975–6985.
- Park M, Park H, Joo K, et al. Polarization-dependent liquid crystalline polymeric lens array with aberration-improved aspherical curvature for low 3D crosstalk in 2D/3D switchable mobile multi-view display. Opt Express. 2018;26:20281–20297.
- Park MK, Park H, Joo KI, et al. Fast-switching laterally virtual-moving microlens array for enhancing spatial resolution in light-field imaging system without degradation of angular sampling resolution. Sci Rep. 2019;9:11297.