數位光學相位共軛用於立體影像顯示之研究

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姓名

陳致維(Chih-Wei Chen) 查詢紙本館藏

畢業系所

光電科學與工程學系

論文名稱

數位光學相位共軛用於立體影像顯示之研究
(Study of 3D Image Display Based on Digital Optical Phase Conjugation)

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至系統瀏覽論文 (2024-12-1以後開放)

摘要(中)

本論文中我們將小貓自泵相位共軛術(Kitty Self-Pumped Phase Conjugate Mirror, Kitty-SPPCM)應用於數位光學相位共軛(Digital Optical Phase Conjugator, DOPC)系統。利用 Kitty-SPPCM 系統之穩定、快速以及角度容忍高等優點，發展出一套高效能的 DOPC 系統，並以此 DOPC 系統為基礎，發展一套能重建三維影像資訊之實像投影系統。在此系統中，我們利用費奈爾反射結構，增加系統被接收到的有效通道數，進而提升共軛訊號效率。接著為了提升立體影像的品質，我們計算分析浮空高度對視場角(Field of View, FOV)與可視聚焦點範圍的關係。最後我們以此三維影像投影系統建立由多個共軛聚焦點所組成的長方體影像，並進一步以這些共軛聚焦點排列出不同的英文字母，重建出立體影像。

摘要(英)

In this paper, we apply Kitty Self-Pumped Phase Conjugate Mirror (Kitty-SPPCM) to the Digital Optical Phase Conjugator (DOPC) system. Using the benefits of the Kitty-SPPCM, such like stable, fast, and highlevel of angle tolerance, we develop a high-performance DOPC system. Based on this DOPC system, we develop a real image projection system that can reconstruct 3D image information. In this system, we use the Fresnel reflective structure to increase the received number of channels, and thus promote the efficiency of conjugate signal of the system. To improve the performance of the 3D image, we calculate and analyze: (1) the relationship between floating height and field of view (FOV). (2) the relationship between floating height and the range of the visible reconstruct points. Finally, we use this 3D image projection system to build up a 3D cube matrix formed with reconstruct points. Then we display a 3D image of the letters N, C, and U with these reconstruct points.

關鍵字(中)

★ 數位光學相位共軛器
★ 小貓自泵相位共軛鏡
★ 立體投影
★ 數位全像
★ 多重鏡面
★ 費奈爾反射結構

關鍵字(英)

★ Digital optical phase conjugator
★ Kitty Self-Pumped Phase Conjugate Mirror
★ 3D projection
★ Digital holography
★ Confetti-like specular surface
★ Fresnel Reflective Structure

論文目次

摘要.......................................................................i
Abstract..................................................................ii
致謝.....................................................................iii
目錄.......................................................................v
圖索引..................................................................viii
表索引....................................................................xv
第一章緒論................................................................1
1-1 研究領域介紹.........................................................1
1-1-1 Yaras團隊的立體投影系統.........................................6
1-2 光學相位共軛器之發展 ................................................9
1-3 數位光學相位共軛器之發展............................................10
1-3-1 Yang 團隊2010年之數位光學相位共軛器............................11
1-3-2 Yang 團隊2012年之數位光學相位共軛器............................13
1-3-3 Yang 團隊2015年之數位光學相位共軛器............................15
1-3-4 Psaltis 團隊2012年之數位光學相位共軛器.........................17
1-4 研究動機與挑戰 .....................................................19
1-5 論文大綱及安排 .....................................................19
第二章實驗相關原理介紹 ..................................................20
2-1 全像術簡介..........................................................20
2-2 Whittaker-Shannon 取樣定理與空間帶寬乘積............................23
2-3 貓式自泵相位共軛器 (Cat-SPPCM)......................................26
2-4 小貓自泵相位共軛器 (Kitty-SPPCM)....................................27
2-5 角頻譜傳遞法 .......................................................28
2-6 訊雜比與有效通道數 .................................................29
第三章數位光學相位共軛系統 ..............................................33
3-1 數位光學相位共軛系統對位............................................34
3-2 讀取光相位擷取......................................................37
3-3 物光相位擷取........................................................40
3-4 觀測共軛聚焦點 CMOS 之定位..........................................42
3-5 重建共軛物光........................................................42
第四章立體投影系統等效模型建立及共軛聚焦點分析...........................45
4-1 立體投影系統設計概念 ...............................................45
4-2 利用費奈爾反射結構之系統等效模型建立................................47
4-3 物光、費奈爾反射結構與收光系統之初階計算............................49
4-4 物光與費奈爾反射結構距離對於共軛聚焦點視場角與可視範圍大小之分析....52
第五章應用費奈爾反射結構於立體投影系統實驗之分析.........................57
5-1 重建多個共軛聚焦點之實驗............................................57
5-2 重建共軛聚焦點之實驗與模擬驗證與 PBR 分析 ..........................66
5-3 重建多個共軛聚焦點之排列圖像實驗....................................69
第六章結論...............................................................73
參考文獻..................................................................75
中英文名詞對照表 .........................................................79
附錄......................................................................85

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指導教授

楊宗勳孫慶成(Tsung-Hsun Yang Ching-Cherng Sun)

審核日期

2019-12-18

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