[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.4218/etrij.2018-0523

Evolution of spatial light modulator for high-definition digital holography

Choi, Ji Hun (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Pi, Jae-Eun (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Hwang, Chi-Young (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Yang, Jong-Heon (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Kim, Yong-Hae (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Kim, Gi Heon (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Kim, Hee-Ok (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Choi, Kyunghee (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)
Kim, Jinwoong (Broadcasting and Media Research Laboratory, Electronics and Telecommunications Research Institute)
Hwang, Chi-Sun (ICT Materials & Components Research Laboratory, Electronics and Telecommunications Research Institute)

Publication Information

ETRI Journal / v.41, no.1, 2019 , pp. 23-31 More about this Journal

Abstract

Since the late 20th century, there has been rapid development in the display industry. Only 30 years ago, we used big cathode ray tube displays with poor resolution, but now most people use televisions or smartphones with very high-quality displays. People now want images that are more realistic, beyond the two-dimensional images that exist on the flat screen, and digital holography-one of the next-generation displaysis expected to meet that need. The most important parameter that determines the performance of a digital hologram is the pixel pitch. The smaller the pixel pitch, the higher the level of hologram implementation possible. In this study, we fabricated the world-smallest $3-{\mu}m$ -pixel-pitch holographic backplane based on the spatial light modulator technology. This panel could display images with a viewing angle of more than $10^{\circ}$ . Furthermore, a comparative study was conducted on the fabrication processes and the corresponding holographic results from the large to the small pixel-pitch panels.

Keywords

Digital holography; holographic panel; pixel pitch; spatial light modulator; viewing angle;

Citations & Related Records

Reference

1	J. Hahn et al., Wide viewing angle dynamic holographic stereogram with a curved array of spatial light modulators, Opt. Express 16 (2008), 12372-12386. DOI
2	K. Machida et al., Three-dimensional image reconstruction with a wide viewing-zone-angle using a GMR-based hologram, in Proc. Digit. Holography Three-Dimensional Image, Kohala Coast, HI, USA, Apr. 21-25, 2013, DTh2A.5:1- DTh2A.5:5.
3	D. Dudley, W. M. Duncan, J. Slaughter, Emerging digital micromirror device (DMD) applications, Proc. SPIE 4985 (2003), 14-25.
4	W. P. Bleha, L. A. Lei, Advances in Liquid Crystal on Silicon (LCoS) Spatial Light Modulator Technology, Proc. SPIE 8736 (2013), 87360A:1-87360A:8.
5	S. Reichelt, Spatially resolved phase-response calibration of liquid-crystal-based spatial light modulators, Appl. Opt. 52 (2013), 2610-2618. DOI
6	D. E. Smalley et al., Anisotropic leaky-mode modulator for holographic video displays, Nature 498 (2013), 313-318. DOI
7	R. Stahl et al., Modular sub-wavelength diffractive light modulator for high-definition holographic displays, J. Phys. 415 (2013), 012057. DOI
8	J. H. Choi et al., InZnO/AlSnZnInO bilayer oxide thin-film transistors with high mobility and high uniformity, IEEE Electron Device Lett. 37 (2016), 1295-1298. DOI
9	J. H. Choi et al., 1- ${\mu}m$ short-channel oxide thin-film transistors with triangular gate spacer, IEEE Electron Device Lett. 38 (2017), 1398-1400. DOI
10	X. Xun, R. W. Cohn, Phase calibration of spatially nonuniform spatial light modulators, Appl. Opt. 43 (2004), 6400-6406. DOI
11	Z. Zhang et al., Diffraction based phase compensation method for phase-only liquid crystal on silicon devices in operation, Appl. Opt. 51 (2012), 3837-3846. DOI
12	V. Lopez et al., Non-uniform spatial response of the LCoS spatial light modulator, Opt. Commun. 366 (2016), 419-424. DOI

Reference

8	(2019) Journal of the Society for Information Display The new route for realization of 1‐μm‐pixel‐pitch high‐resolution displays / 27 (8) , 487
1	(2019) Society for Information Display International Symposium digest of technical papers 23‐3: <I>Distinguished Paper:</I> The New Route for Realization of 1µm‐pixel‐pitch High Resolution Displays / 50 (1) , 319
1	(2019) Society for Information Display International Symposium digest of technical papers 8.3: <I>Invited Paper:</I> Ultra High Resolution Display for Digital Holography / 50 (1) , 79
12	(2019) Journal of the Optical Society of America. A, Optics, image science, and vision Crafting a 15 µm pixel pitch spatial light modulator using Ge<SUB>2</SUB>Sb<SUB>2</SUB>Te<SUB>5</SUB> phase change material [Invited] / 36 (12) , D23
1	(2019) Society for Information Display International Symposium digest of technical papers 21‐2:<I>Invited Paper:</I>1µm Pixel Pitch Spatial Light Modulator Panel for Digital Holography / 51 (1) , 297
10	(2019) 한국정보통신학회논문지 유사홀로그램 가시화 기반 가상 휴먼의 제스쳐 상호작용 영향 분석 / 24 (10) , 1390
11	(2019) 한국정보통신학회논문지 이기종 유사홀로그램 시스템 간 콘텐츠 자동 가시화 기법 / 24 (11) , 1445
5	(2019) Applied optics Past, current, and future of holographic video display [Invited] / 61 (5) , B237