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姓名	林子閎(Tzu-Hung Lin)  查詢紙本館藏	畢業系所	光電科學與工程學系
論文名稱	使用透鏡陣列做為屏幕之數位光學相位共軛投影系統與適應性光學優化之研究 (Study of Digital Optical Phase Conjugation Image Projection System Using Lens-Array as Screen and Adaptive Optics Optimization)
檔案	[Endnote RIS 格式]    [Bibtex 格式]    [相關文章]   [文章引用]   [完整記錄]   [館藏目錄]   至系統瀏覽論文 (2026-10-5以後開放)
摘要(中)	本論文利用透鏡陣列 (lens array) 做為數位光學相位共軛 (digital optical phase conjugator, DOPC) 投影系統的屏幕，利用DOPC重建訊號光的能力與透鏡陣列在空間中重建出大可視角度 (angle of view) 與 Eyebox 的 3D 立體實像。在此系統中利用 SLM 調製相位的能力，藉由補償不同階數的像差提高成像的峰值與背景雜訊比 (peak to background ratio，PBR)。接著比較利用單一透鏡作為屏幕與利用透鏡陣列作為屏幕，兩者之間的Eyebox大小。最後我們藉由調製重建物光資訊在SLM上XY軸的傾斜 (tilt) ，使原本的重建訊號光位置產生位移，並在SLM上將多張重建物光資訊的相位圖疊加，使我們可以利用此系統重建出英文字母投影至空間中。
摘要(英)	In this thesis, we use the lens-array as the screen of the Digital Optical Phase Conjugator (DOPC) system. By using the ability of DOPC system with the lens-array, we can reconstruct a three-dimensional image with large field of view (FOV) and Eyebox. Since the Spatial Light Modulator (SLM) has the ability to modulate phase, we compensate different modes of the orthonormal rectangular polynomials to raise the peak to background ratio (PBR) of the reconstructed point. Then, we compare the difference of the reconstructed image’s Eyebox between using single lens as the screen with using lens-array as the screen. At last, we modulate the tilt of the X and Y axis on the SLM of the phase of the reconstructed signal light. The reconstructed point will move to different position. By superimposing two or more phases to one picture on the SLM, we can finally reconstruct a latter to the space by using one point.
關鍵字(中)	★ 光學 ★ 全像 ★ 數位全像 ★ 數位光學共軛 ★ 3D影像 ★ 適應性光學 ★ 透鏡陣列	關鍵字(英)	★ Optics ★ Holography ★ Digital Holography ★ Digital Optical Phase Conjugation ★ 3D image ★ Adaptive Optics ★ Lens-array
論文目次	摘要 i Abstract ii 致謝 iii 目錄 v 圖索引 viii 第一章 緒論 1 1-1 研究領域介紹 1 1-2 DOPC發展 9 1-3 適應性光學 16 1-4 研究動機 21 1-5 論文安排 21 第二章 原理介紹 22 2-1 全像術簡介 22 2-2 小貓自汞相位共軛鏡 (Kitty-SPPCM) 25 2-3 Field of View (FOV) 與 Eyebox 28 2-4 峰值與背景雜訊比 (Peak-Backgroung Ratio，PBR) 31 2-5 適應性光學像差 32 第三章 數位光學共軛系統 39 3-1 數位光學共軛系統對位 39 3-2 相位擷取與重建 42 3-3 適應性光學校正系統誤差 48 3-4 lens-array 體積成像 (integral imaging) 50 3-5 立體系統設計 52 3-6 系統成像範圍的極限 53 第四章 成像系統分析 58 4-1 透鏡陣列(lens-array)與單一透鏡(single lens)成像比較 58 4-2 適應性光學前後比較分析 63 4-3 立體系統完整影像分析 65 第五章 結論 69 參考文獻 71 中英文名詞對照表 76
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指導教授	孫慶成 余業緯 楊宗勳(Ching-Cherng Sun Yeh-Wei Yu Tsung-Hsun Yang)	審核日期	2021-10-6
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