Full-color reflection hologram with optimized diffraction efficiency in a one-layer photopolymer

被引:1
作者
Wu, Hui-Ying [1 ]
Shin, Chang-Won [1 ]
Kim, Joon Hyun [1 ]
Rupali, Shindae [1 ]
Lee, Kwon-Yeon [2 ]
Park, Seong Gyoon [3 ]
Kim, Nam [1 ]
机构
[1] Chungbuk Natl Univ, Sch Informat & Commun Engn, 1 Chungdae Ro, Cheongju 28644, Chungbuk, South Korea
[2] Sunchon Natl Univ, Dept Elect Engn, 255 Jungang Ro, Sunchon 57922, Jeonnam, South Korea
[3] Kongju Natl Univ, Dept Informat & Commun Engn, 1223-24 Cheonandae Ro, Cheonan 31080, Chungnam, South Korea
来源
PRACTICAL HOLOGRAPHY XXXVI: DISPLAYS, MATERIALS, AND APPLICATIONS | 2022年 / 12026卷
关键词
Holographic optical element (HOE); photopolymer; diffraction efficiency; DISPLAY;
D O I
10.1117/12.2610463
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
In this paper, A full-color Denisyuk-type hologram using photopolymer has been recorded by the sequential exposure method. The photopolymer's optical characteristics show that inhibition periods of the photopolymer at three lasers are different in the same beam intensity. To increase the average diffraction efficiency of a full-color holographic optical element ( HOE), the three lasers should be sequentially exposed to the photopolymer. The experimental results show that the average efficiency of a full-color reflection HOE is 59.6% and the standard deviation is 2.1. Also, the full-color hologram recorded in a one-layer photopolymer can reconstruct a high-quality image.
引用
收藏
页数:6
相关论文
共 14 条
  • [1] Bayfol® HX photopolymer for full-color transmission volume Bragg gratings
    Berneth, Horst
    Bruder, Friedrich-Karl
    Faecke, Thomas
    Jurbergs, David
    Hagen, Rainer
    Hoenel, Dennis
    Roelle, Thomas
    Walze, Guenther
    [J]. PRACTICAL HOLOGRAPHY XXVIII: MATERIALS AND APPLICATIONS, 2014, 9006
  • [2] The Chemistry and Physics of Bayfol® HX Film Holographic Photopolymer
    Bruder, Friedrich-Karl
    Faecke, Thomas
    Roelle, Thomas
    [J]. POLYMERS, 2017, 9 (10):
  • [3] Erdenebat M.-U., 2018, STATE ART VIRTUAL RE
  • [4] Kim N., 2017, HOLOGRAPHIC MAT OPTI
  • [5] COUPLED WAVE THEORY FOR THICK HOLOGRAM GRATINGS
    KOGELNIK, H
    [J]. BELL SYSTEM TECHNICAL JOURNAL, 1969, 48 (09): : 2909 - +
  • [6] Enhanced depth-of-field of an integral imaging microscope using a bifocal holographic optical element-micro lens array
    Kwon, Ki-Chul
    Lim, Young-Tae
    Shin, Chang-Won
    Erdenebat, Munkh-Uchral
    Hwang, Jae-Moon
    Kim, Nam
    [J]. OPTICS LETTERS, 2017, 42 (16) : 3209 - 3212
  • [7] Holographic Solar Energy Concentrator Using Angular Multiplexed and Iterative Recording Method
    Lee, Jeong-Hyeon
    Wu, Hui-Ying
    Piao, Mei-Lan
    Kim, Nam
    [J]. IEEE PHOTONICS JOURNAL, 2016, 8 (06):
  • [8] Holographic display for see-through augmented reality using mirror-lens holographic optical element
    Li, Gang
    Lee, Dukho
    Jeong, Youngmo
    Cho, Jaebum
    Lee, Byoungho
    [J]. OPTICS LETTERS, 2016, 41 (11) : 2486 - 2489
  • [9] Full Color Holographic Optical Element Fabrication for Waveguide-type Head Mounted Display Using Photopolymer
    Piao, Jing-Ai
    Li, Gang
    Piao, Mei-Lan
    Kim, Nam
    [J]. JOURNAL OF THE OPTICAL SOCIETY OF KOREA, 2013, 17 (03) : 242 - 248
  • [10] Full-color holographic diffuser using time-scheduled iterative exposure
    Piao, Mei-Lan
    Kwon, Ki-Chul
    Kang, Hoon-Jong
    Lee, Kwon-Yeon
    Kim, Nam
    [J]. APPLIED OPTICS, 2015, 54 (16) : 5252 - 5259
12