References
- Sato S. Liquid-crystal lens-cells with variable focal length. Jpn J Appl Phys. 1979;18:1679–1684.
- Riza NA, Dejule MC. Three-terminal adaptive nematic liquid-crystal lens device. Opt Lett. 1994;19:1013–1015.
- Sato S. Applications of liquid crystals to variable-focusing lenses. Opt Rev. 1999;6:471–485.
- Naumov AF, Loktev MY, Guralnik IR, et al. Liquid crystal adaptive lenses with modal control. Opt Lett. 1998;23:992–994.
- Ye M, Sato S. Optical properties of liquid crystal lens of any size. Jpn J Appl Phys. 2002;41:L571–L573.
- Lin YH, Wang YJ and Reshetnyak V. Liquid crystal lenses with tunable focal length. Liq Cryst Rev. 2017;5(2):111–143.
- Hiddink MGH, Zwart STD, Willemsen OH, et al. Locally switchable 3D displays. Soc Inf Disp Tech Dig. 2006;20(1):1142–1145.
- Wang B, Ye M, Honma M, et al. Liquid crystal lens with spherical electrode. Jpn J Appl Phys. 2002;41:L1232–L1233.
- Wang B, Ye M, Sato S. Lens of electrically controllable focal length made by a glass lens and liquid crystal layers. Appl Opt. 2004;43(17):3420–3425.
- Dou H, Chu F, Wang L, et al. A polarisation-free blue phase liquid crystal lens with enhanced tunable focal length range. Liq Cryst. 2018. DOI:10.1080/02678292.2018.1542748.
- Li LW, Bryant D, Heugten TV, et al. Physical limitations and fundamental factors affecting performance of liquid crystal tunable lenses with concentric electrode rings. Appl Opt. 2013;52(9):1978–1986.
- Li LW, Bryant D, Heugten TV, et al. Near-diffraction-limited and low-haze electro-optical tunable liquid crystal lens with floating electrodes. Opt Express. 2013;21(7):8371–8381.
- Wang XQ, Yang WQ, Liu Z, et al. Switchable Fresnel lens based on hybrid photo-aligned dual frequency nematic liquid crystal. Opt Mater Express. 2017;7(1):8–15.
- Kim SU, Na JH, Kim C, et al. Design and fabrication of liquid crystal-based lenses. Liq Cryst. 2017;44:2121–2132.
- Ye M, Wang B, Uchida M, et al. Focus tuning by liquid crystal lens in imaging system. Appl Opt. 2012;51(31):7630–7635.
- Hsu CJ, Sheu CR. Using photopolymerization to achieve tunable liquid crystal lenses with coaxial Bifocals. Opt Express. 2012;20(4):4738–4746.
- Galstian T, Asatryan K, Presniakov V, et al. High optical quality electrically variable liquid crystal lens using an additional floating electrode. Opt Lett. 2016;41:3265–3268.
- Hsu CJ, Jhang JJ and Huang CY. Large aperture liquid crystal lens with an imbedded floating ring electrode. Opt Express. 2016;24:16722–16731.
- Li Y, Wu ST. Polarization independent adaptive microlens with a blue-phase liquid crystal. Opt Express. 2011;19:8045–8050.
- Lee CT, Li Y, Lin HY, et al. Design of polarization-insensitive multi-electrode GRIN lens with a blue-phase liquid crystal. Opt Express. 2011;19:17402–17407.
- Li Y, Liu YF, Li Q, et al. Polarization independent blue-phase liquid crystal cylindrical lens with a resistive film. Appl Opt. 2012;51:2568–2572.
- Cui JP, Fan HX, Wang QH. A polarisation-independent blue-phase liquid crystal microlens using an optically hidden dielectric structure. Liq Cryst. 2017;44:643–647.
- Chu F, Dou H, Li GP, et al. A polarisation-independent blue-phase liquid crystal lens array using gradient electrodes. Liq Cryst. 2018;45:715–720.
- Dou H, Chu F, Song YL, et al. A multifunctional blue phase liquid crystal lens based on multi-electrode structure. Liq Cryst. 2018;45:491–497.
- Chu F, Dou H, Tian LL, et al. Polarisation-independent blue-phase liquid crystal microlens array with different dielectric layer. Liq Cryst. 2018. DOI:10.1080/02678292.2018.1550221.
- Li R, Chu F, Dou H, et al. A blue-phase liquid crystal lens array based on dual square ring-patterned electrodes. Liq Cryst. 2018. DOI:10.1080/02678292.2018.1549284.