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研究生:林碩恩
研究生(外文):Lin, Shuo-En
論文名稱:利用時間多工降低光斑實現彩色全像抬頭顯示器
論文名稱(外文):Reducing Impacts of Speckle on Color Holographic Head-up Display by Time-Division Multiplexing Method
指導教授:黃乙白黃乙白引用關係黃柏蒼黃柏蒼引用關係
指導教授(外文):Huang, Yi-PaiHuang, Po-Tsang
口試委員:黃乙白黃柏蒼陳政寰范姜冠旭
口試委員(外文):Huang, Yi-PaiHuang, Po-TsangChen, Jeng-HuanFan-Jiang, Guan-Shiu
口試日期:2019-11-27
學位類別:碩士
校院名稱:國立交通大學
系所名稱:電機學院電子與光電學程
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2020
畢業學年度:108
語文別:英文
論文頁數:57
中文關鍵詞:全像投影彩色全像投影時間多工光斑消除
外文關鍵詞:HologramColor hologramTDMReduce speckle
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隨著科技的進展,顯示技術日漸成熟,多年前人們在科幻電影中才能看到的景象,已經一一地被實現在現實生活中。想要看到影像栩栩如生的在眼前呈現,甚至不用出門去電影院看立體電影,在家裡打開頭戴式顯示器,虛擬實境就如同親臨現場。
目前市面上最常接觸的3D影像種類如立體電影,頭戴式顯示器(head-mounted display),甚至是光柵式裸眼顯示器(parallax barriers display),都是利用雙眼的視差在空間中錯位,來達到立體成像的效果。然而這種方式有一個缺點,利用視差呈現立體影像會產生所謂的視覺輻輳 (Vergence Accommodation Conflict;VAC),這是指雙眼對焦的焦點與實際呈現畫面的顯示器位置有所差異,這會導致部分使用者在體驗這類產品時會感到暈眩。
由於上述問題,在一些不允許暈眩現象產生的使用狀況如車用抬頭顯示器,利用全像投影來進行立體投射又開始被重視。全像投影是一個把光聚焦在半空中的技術,配合電腦生成全像片演算法,讓即時的路況資訊,可以立體地被呈現在駕駛者的面前,提供良好及時的警示與輔助作用。
本文目的為提供一個彩色的全像車用抬頭顯示器方案,內容包含兩種消除色差(Chromatic Aberration)的投影架構。另外針對全像投影常見的光斑問題,我們利用時間多工技術達到光斑補償,在對單張投影片的對比度提升上使用演算法的改進,進而達到最佳的彩色投影成果。
With the rapid development of display technology, people could now have amazing experiences realizing those scenes that were only seen in sci-fi movies years ago. People don’t even need to go out for a movie but just turn on the head-mounted display, and there’s a whole new world waiting for you to explore further.
The most accessible stereoscopic display, such as 3D film, head-mounted display, and even parallax barriers display, are all utilizing binocular parallax to produce 3D perception. However, there’s a disadvantage as the so-called Vergence Accommodation Conflict (VAC), which means there would be distances between points that focused on the panel and the actual projected images, thus causes users to feel dizzy.
Due to the issues of VAC, people then start further developments toward the application of holographic display on HUD, for example, an automobile head-up display. This is to avoid danger during some specific circumstances. To be brief, the holographic display is a technology that can focus images in the mid-air. With the usage of computer-generated hologram (CGH) technology, real-time driving information can be projected in the mid-air as a 3D image, which provides drivers some timely warnings and safety support.
In this study, two structures of color holographic display are proposed for HUD. Those different structures provide two ways to eliminate chromatic aberration. On the other hand, the speckle issue is a common problem of holographic display. Part of the research would be focusing on utilizing time-division multiplexing (TDM) method to suppress speckle, also improving contrast with the computer-generated hologram algorithm in holographic display.
摘 要 i
Abstract ii
誌謝 iv
Contents v
Figure Captions vii
List of Tables ix
Chapter 1 Introduction 1
1.1 Introduction of HUD using CGH display 1
1.2 Color head-up display realized by the holographic display 3
1.3 Motivation and objective 4
1.4 Organization of the thesis 5
Chapter 2 Prior Arts 6
2.1 The method of light transportation in holographic 6
2.1.1 Inverse Fourier transform algorithm (IFTA) 6
2.1.2 The single Fourier-transform-based Fresnel method (SFT-FR) 7
2.1.3 The double Fourier transform-based method 8
2.2 Multi-constraint algorithm 12
2.3 Off-axis holographic display 14
2.4 The method to reduce speckle contrast 16
2.4.1 Speckle suppress with negative correlation coefficient[7][8] 17
Chapter 3 Proposed Methods 20
3.1 The multi-constraints method for SFT-FR 20
3.2 Speckle suppression by the integrated sum of two negative correlated images 22
3.3 Spherical distortion correction for holographic display 25
3.4 The method to realize the color holographic display 27
3.4.1 Color holographic display with tilted projection [11] 29
3.4.2 Color holographic display with three SLM 32
Chapter 4 Experimental Result 35
4.1 The experiment result of multi-constraints SFT-FR 35
4.2 The experiment result of integrated sum of two negative correlated images 39
4.3 Experiment result of spherical distortion correction for holographic display 44
4.4 The experiment result of color holographic display 48
4.4.1 Color holographic display with a tilted projection 48
4.4.2 Color holographic display with three SLM 50
Chapter 5 Conclusions and Future Works 53
5.1 Conclusion 53
5.2 Future work 54
Reference 56
Reference

[1] Goodman, Joseph W., Introduction to Fourier optics. Roberts and Company Publishers, 2005.
[2] R.W. Gerchberg. “Super-resolution through error energy reduction.”, Optica Acta, 2 1 :709-720,1974
[3] Matsushima, Kyoji and Tomoyoshi Shimobaba. "Band-limited angular spectrum method for numerical simulation of free-space propagation in far and near fields." Optics Express 17.22 (2009): 19662-19673.
[4] Che-Yung Shen. “Holographic Head-Up Display System with a Wide Depth Range Realized by Hybrid Superimposing Multi-Constraints Algorithm”, National Chiao Tung University, master thesis, June 2019.
[5] K. Matsushima, “Shifted Angular Spectrum Method for Off-Axis Numerical Propagation,” Optics Express, vol. 18, no. 17, pp. 18453-18463, 2010.
[6] Yi Cheng. “Wide Field of View Holographic Head-up Display Realized by Hybrid Multi-Constraint Shifted Angular Spectrum Algorithm”, National Chiao Tung University, master thesis, June 2019.
[7] Wei-Feng Hsu and Chuan-Feng Yeh, "Speckle suppression in holographic projection displays using temporal integration of speckle images from diffractive optical elements," Appl. Opt. 50, H50-H55, 2011.
[8] Wei-Feng Hsu and I.-L. Chu, "Speckle Suppression by Integrated Sum of Fully Developed Negatively Correlated Patterns in Coherent Imaging," Progress In Electromagnetics Research B, Vol. 34, 1-13, 2011.
[9] Tomoyoshi Shimobaba, Takayuki Takahashi, Nobuyuki Masuda, and Tomoyoshi Ito, "Numerical study of color holographic projection using space-division method," Opt. Express 19, 10287-10292, 2011.
[10] Makowski, Izabela Ducin, Maciej Sypek, Agnieszka Siemion, Andrzej Siemion, Jaroslaw Suszek, and Andrzej Kolodziejczyk, "Color image projection based on Fourier holograms," Opt. Lett. 35, 1227-1229, 2010.
[11] Tomoyoshi Ito and Koji Okano, "Color electro holography by three colored reference lights simultaneously incident upon one hologram panel," Opt. Express 12, 4320-4325, 2004.
Opt. Lett. 35, 1227-1229 (2010)
[12] Kyongsik Choi, Hwi Kim, and Byoungho Lee, "Full-color autostereoscopic 3D display system using color-dispersion-compensated synthetic phase holograms," Opt. Express 12, 5229-5236, 2004.
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