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"ELC lens"

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"ELC lens"

An Optical Analysis of Viewing-angle Switchable Display Using ELC Lens
Shin-yong Jeong, Woo-sang Park
J Electr Electron Mater 2017;30(4):241-245.   Published online April 1, 2017
This paper proposes a private display that can adjust viewing angles by using an electric-field-driven (EFD) LC Lens. The EFD LC Lens design and simulation were analyzed by using the Extended Jones Matrix Method. The conventional method for attaching a private film to the display was difficult. In order to solve this problem, in this study, by using the EFD LC Lens, we devised a method that can view images more conveniently. We analyzed the luminance and illumination of the optical viewing distance by using the Extended Jones Matrix Method. We also measured the intensity of the viewing angles. The simulation attached the EFD LC Lens to the 14" Full HD RGB stripe wide panel. We calculated the relative luminance distribution and the luminance distribution on the viewing angle of the image at the optimum viewing distance of 60 cm, using the EFD LC Lens and the lenticular lens. The proposed method could be used to design private displays that can adjust the viewing angle of the EFD LC Lens.
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Rigorous Analysis of Viewing Zone for 3D Display with Electric-field-driven Liquid Crystal Lens
Tae Hyeon Kim, Bong Sik Kim, Woo Sang Park
J Electr Electron Mater 2016;29(8):494-498.   Published online August 1, 2016
In this paper, we proposed the 3-dimenstional (3D) analysis for calculating the optical characteristics of an autostereoscopic display with electric field driven liquid crystal (ELC) lens. From 3D analysis considering the slanting of lens, we calculate the cross-talk of each images and the distortion of viewing zone. Using geometric opics and extended Jones matrix method (EJMM), phase retardation of ELC lens according to position is calculated and then optical path difference in 3D space considering tilt and azimuth angle of incident light is gotten. Then, intensity distribution is presented in the space. Through camparing the intensity distribution using ideal lens with the ELC lens, we identify the noise and image distortion of ELC lens. As a result, this analysis is expected to provide optimum design conditions for realistic and rigorous 3D display with ELC lens.
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A Geometrical Analysis Method of ELC Lens for The 3D Display for Optimum Design
Bong Sik Kim, Keon Woo Kim, Seung Jo Baik, Woo Sang Park
J Electr Electron Mater 2013;26(6):457-461.   Published online June 1, 2013
In this paper a novel method based on geometrical optics proposed to calculate the optical characteristics of an electric field driven liquid crystal (ELC) lens. For an optimally designed ELC lens, effective refractive index is calculated and then ray tracing is carried out using Huygens′ principle. From the results, the intensity distribution at the optimum viewing distance (OVD) is obtained. To confirm the validity of our work, the result is compared with that calculated by the extended Jones matrix method (EJMM). As a result, it turns out that the novel method provides more simple and rigorous simulation results than the EJMM.
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Optimal Design of Electric Field Driven Liquid Crystal Fresnel Lens Using Taguchi`s Method
Bong Sik Kim, Jong Woon Kim, Woo Sang Park
J Electr Electron Mater 2012;25(3):218-223.   Published online March 1, 2012
A rigorous electro-optical simulation and ray tracing for an electric field driven liquid crystal Fresnel lens was proposed to obtain design parameters of the electrode pattern of the Fresnel lens. The optimal design was carried out using Taguchi`s experimental method for 17.1"(368×229.5 mm) wide LCD panels with 9 views. For the calculation of the distribution of liquid crystal molecules and the optical transmission of the panel, finite difference method and extended Jones matrix method were used to deal effectively with highly nonlinear and complicated motional equations of the liquid crystal molecules and to obtain the oblique transmission characteristics of the LCD panel. As simulation results, the optimal lengths of the 3 electrodes of the Fresnel lens are 4.0 μm, 30 μm and 83 μm, respectively, and the locations of the second and third electrodes are 32.9-33.0 μm and 45.9-46.0 μm, respectively. The optimal applied voltage of the 3 electrodes are found to be 5.75 V, 7.80 V and 11.9 V, respectively.
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