References
- Chen HW, Lee JH, Lin BY, et al. Liquid crystal display and organic light-emitting diode display: present status and future perspectives. Light-SCI Appl. 2018;7:17168.
- Barnes D. LCD or OLED: who wins? SID Int Symp Dig Tech. 2013;44:26–27.
- Kim DH, Lim YJ, Kim DE, et al. Past, present, and future of fringe-field switching-liquid crystal display. J Disp Technol. 2014;15:99–106.
- Yoon JH, Lee SJ, Lim YJ, et al. Fast switching, high contrast and high resolution liquid crystal device for virtual reality display. Opt Express. 2018;26:34142–34149.
- Wu ST. Nematic liquid crystal modulator with response time less than 100 μs at room temperature. Appl Phys Lett. 1990;57:986–988.
- Wu ST, Wu CS. Small angle relaxation of highly deformed nematic liquid crystals. Appl Phys Lett. 1988;53:1794–1796.
- Choi BD, Han JW, Kim CS, et al. Motion-compensated frame interpolation using bilateral motion estimation and adaptive overlapped block motion compensation. IEEE T Circ Syst Vid. 2007;17:407–416.
- Peng F, Chen H, Gou F, et al. Analytical equation for the motion picture response time of display devices. J Appl Phys. 2017;121:023108.
- Talukder JR, Huang Y, Wu ST. High performance LCD for augmented reality and virtual reality displays. Liq Cryst. 2019;46:920–929.
- Oh-e M, Kondo K. Electro-optical characteristics and switching behavior of the in-plane switching mode. Appl Phys Lett. 1995;67:3895–3897.
- Lee SH, Lee SL, Kim HY. Electro-optic characteristics and switching principle of a nematic liquid crystal cell controlled by fringe-field switching. Appl Phys Lett. 1998;73:2881–2883.
- Wu ST. Phase-matched compensation films for liquid crystal displays. Mater Chem Phys. 1995;42:163–168.
- Oh SW, Yoon TH. Elimination of light leakage over the entire viewing cone in a homogeneously-aligned liquid crystal cell. Opt Express. 2014;22:5808–5817.
- Chen H, Zhu R, Li MC, et al. Pixel-by-pixel local dimming for high-dynamic-range liquid crystal displays. Opt Express. 2017;25:1973–1984.
- Huang W, Li JM, Yang LM, et al. Local dimming algorithm and color gamut calibration for RGB LED backlight LCD display. Opt Laser Technol. 2011;43:214–217.
- Eom YH, Yoon SS, Park SR, et al. Novel in-plane switching (IPS) mode with high transmittance using negative dielectric liquid crystal. SID Int Symp Dig Tech. 2018;49:1092–1094.
- Rao L, Ge Z, Wu ST, et al. Low voltage blue-phase liquid crystal displays. Appl Phys Lett. 2009;95:231101.
- Rao L, Cheng HC, Wu ST. Low voltage blue-phase LCDs with double-penetrating fringe fields. J Disp Technol. 2010;6:287–289.
- Kim SS, Berkeley BH, Kim KH, et al. New technologies for advanced LCD-TV performance. J Soc Inf Display. 2004;12: 353–259.
- Lu R, Wu ST, Ge Z, et al. Bending angle effects on the multi-domain in-plane-switching liquid crystal displays. J Disp Technol. 2005;1:207–216.
- Rao L, Ge Z, Wu ST. Zigzag electrodes for suppressing the color shift of Kerr effect-based liquid crystal displays. J Disp Technol. 2010;6:115–120.
- Park JH, Oh SW, Huh JW, et al. Four-domain electrode structure for wide viewing angle in a fringe-field switching liquid crystal display. J Disp Technol. 2016;12:667–672.
- Shin YC, Park MK, Kim B, et al. Micropatterned vertical alignment liquid crystal mode with dual threshold voltages for improved off-axis gamma distortion. IEEE T Electron Dev. 2018;65:150–157.
- Kim SU, Lee BY, Suh JH, et al. Reduction of gamma distortions in liquid crystal display by anisotropic voltage-dividing layer of reactive mesogens. Liq Cryst. 2017;44:364–371.
- Guo Y, Fu M, Ren Y, et al. Low-voltage blue-phase liquid crystal display with single-penetration electrodes. Liq Cryst. 2017;44:2321–2326.
- Chen H, Lan YF, Tsai CY, et al. Low-voltage blue-phase liquid crystal display with diamond-shape electrodes. Liq Cryst. 2017;44:1124–1130.
- Guo Y, Li X, Sun Y, et al. Low gamma shift blue-phase liquid crystal display with electric field induced multi-domain electrode structure. Liq Cryst. 2019. DOI:10.1080/02678292.2019.1627434.
- Guo Y, Li X, Yang Y, et al. Low-gamma shift asymmetrical double-side blue-phase liquid crystal display. Liq Cryst. 2019. DOI:10.1080/02678292.2019.1635719.
- Tian LL, Chu F, Dou H, et al. A transflective polymer-stabilised blue-phase liquid display with partitioned wall-shaped electrodes. Liq Cryst. 2018;45:1259–1263.
- Chu F, Dou H, Song YL, et al. A transflective blue-phase liquid crystal display with alternate electrodes. Liq Cryst. 2017;44:1316–1320.
- De Gennes PG, Prost J. The physics of liquid crystals. 2nd ed. Clarendon: Clarendon Press; 1993.
- Yang DK, Wu ST. Fundamentals of Liquid Crystal Devices. 2nd ed. Chichester: John Wiley & Sons, Ltd; 2015.
- Zhang Z, You Z, Chu D. Fundamentals of phase-only liquid crystal on silicon (LCOS) devices. Light-SCI Appl. 2014;3:e213.
- Corning.com [Internet]. New York: Corning; [ cited 2019 May 23]. Available from: https://www.corning.com.
- Li J, Wu ST. Extended Cauchy equations for the refractive indices of liquid crystals. J Appl Phys. 2004;95:896–901.
- Ge Z, Rao L, Gauza S, et al. Modeling of blue-phase liquid crystal displays. J Disp Technol. 2009;5:250–256.
- Yan J, Xing Y, Guo Z, et al. Low voltage and high resolution phase modulator based on blue phase liquid crystals with external compact optical system. Opt Express. 2015;23:15256–15264.
- Lien A. Extended Jones matrix representation for the twisted nematic liquid-crystal display at oblique incidence. Appl Phys Lett. 1990;57:2767–2769.
- Chen HW, Zhu RD, He J, et al. Going beyond the limit of an LCD’s color gamut. Light-SCI Appl. 2017;6:e17043.
- Guo Y, Li X, Mu Q, et al. Single electro-optic curve for RGB colours in blue-phase liquid crystal display. Liq Cryst. 2019;46:835–845.