應用DMD提高幀率之數位光學相位共軛投影系統之研究

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姓名

黃啓翔(Chi-Hsiang Huang) 查詢紙本館藏

畢業系所

光電科學與工程學系

論文名稱

應用DMD提高幀率之數位光學相位共軛投影系統之研究
(Study of Improving Frame Rate of Projector System Base on Digital Optical Phase Conjugation by DMD)

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至系統瀏覽論文 (2025-7-1以後開放)

摘要(中)

本論文將數位微陣鏡元件 (digital micromirror device，DMD) 應用於數位光學相位共軛 (digital optical phase conjugator，DOPC) 投影系統。利用 DOPC 系統抑制散射能力，將牆面前之聚焦光點重建，配合 DMD 的高切換速率，使重建光點形成 3D 立體實像。在此系統中使用費奈爾反射鏡增加系統準確因子 (system fidelity)，進而提高投影系統之效率。接著我們利用考量系統準確因子之峰值與背景雜訊比 (peak to background ratio，PBR) 與實驗結果做比較，再由比較結果中提出系統之極限。最後我們利用此系統將英文字母投影至 1mm×1mm×20mm 空間中，展示系統結果，並整理此系統極限，將其結果與 LC-SLM 調製的 DOPC 投影系統做比較。

摘要(英)

In this thesis, the digital micro-mirror device (DMD) is applied to digital optical phase conjugator (DOPC) projection system. DOPC projection system based on DMD have turbidity suppression and high switching rate, so we can reconstruct focus point in front of the wall and form 3D real image. We improve system efficiency by using Fresnel reflect mirror to increase system fidelity. We present the limit of the system by experiment result and theory which is including system fidelity and PBR. In order to show the result, we project symbol to free space which area is 1mm×1mm×20mm. Finally, we compare limit of DOPC projection system based on DMD or LC-SLM.

關鍵字(中)

★ DOPC

關鍵字(英)

論文目次

摘要 i
Abstract ii
致謝 iii
目錄 iv
圖目錄 vii
表目錄 xiii
第一章緒論 1
1-1 研究領域介紹 1
1-1-1 Kujawinska 團隊的立體投影系統 7
1-1-2 Wakunami 團隊的立體投影系統 9
1-2 光學相位共軛器之發展 11
1-3 數位光學相位共軛器之發展 12
1-3-1 Psaltis 團隊 2012 年之 DOPC 系統 13
1-3-2 Yang 團隊2014年之 DOPC 對位優化系統 15
1-3-3 Yang 團隊2015年之 DOPC 系統 18
1-4 研究動機與挑戰 20
1-5 論文大綱及安排 20
第二章原理介紹 21
2-1 全像術簡介 21
2-2 光展量 (Étendue) 24
2-3 DMD 調製原理 26
2-4 DOPC 系統數位校正 29
2-5 峰值與背景雜訊比 (PBR) 31
第三章數位光學共軛器 (DOPC) 34
3-1 DOPC 對位 37
3-2 數位微陣鏡元件 (DMD) 相位校正 42
3-3 DOPC 系統相位擷取及重建 45
3-3-1 物光相位擷取 47
3-3-2 重建共軛物光 48
3-4 立體系統設計概念 51
3-5 費奈爾反射結構設計 52
第四章立體投影系統分析與結果 55
4-1 立體投影系統架構分析 55
4-1-1 立體投影系統鏡組初階計算及設計 55
4-1-2 系統光展量評價 57
4-2 共軛聚焦光點實驗分析及 PBR 計算 60
4-3 立體投影系統多點掃描 64
4-3-1 立體投影系統陣列 65
4-3-2 立體投影系統完整影像 70
4-4 LC-SLM 與 DMD 之立體投影系統比較 73
第五章結論 75
參考文獻 77
中英名詞對照表 82

參考文獻

1. J. Geng, “Three-dimensional display technologies,” Adv. Opt. Photonics 5, 456-535 (2013).
2. F. Matsuura, and N. Fujisawa, “Anaglyph stereo visualization by the use of a single image and depth information,” J. Vis. 11, 79-86 (2008).
3. I. Ideses, and L. Yaroslavsky, “New methods to produce high quality color anaglyphs for 3-D visualization,” in International Conference Image Analysis and Recognition, A. Campilho and M. Kamel, ed. (2004), pp. 273-280.
4. I. Ideses, and L. Yaroslavsky, “Three methods that improve the visual quality of colour anaglyphs,” J. Opt. A: Pure Appl. Opt. 7, 755 (2005).
5. S. E. B. Sorensen, P. S. Hansen, and N. L. Sorensen, “Method for recording and viewing stereoscopic images in color using multichrome filters,” U.S. patent6,687,003 (February3, 2004).
6. S. Pastoor, and M. Wöpking, “3-D displays: A review of current technologies,” Displays 17, 100-110 (1997).
7. Y. Bastanlar, D. Canturk, and H. Karacan, “Effects of color-multiplex stereoscopic view on memory and navigation,” in Proceedings of IEEE Conference on 2007 3DTV Conference(IEEE2007), pp. 1-4.
8. A. J. Woods, and T. Rourke, “Ghosting in anaglyphic stereoscopic images,” Proc. SPIE 5291, pp. 354-365 (2004).
9. W. Kruger, C.-A. Bohn, B. Frohlich, H. Schuth, W. Strauss, and G. Wesche, “The responsive workbench: A virtual work environment,” Computer 28, 42-48 (1995).
10. C. Cruz-Neira, D. J. Sandin, T. A. DeFanti, R. V. Kenyon, and J. C. Hart, “The CAVE: audio visual experience automatic virtual environment,” Commun. ACM 35, 64-73 (1992).
11. J. Leigh, A. Johnson, L. Renambot, T. DeFanti, M. Brown, B. Jeong, R. Jagodic, C. Krumbholz, D. Svistula, and H. Hur, “Emerging from the CAVE: Collaboration in ultra high resolution environments,” presented at the First International Symposium on Universal Communication, Kyoto, Japan, 14-15 June 2007.
12. T. Shibata, “Head mounted display,” Displays 23, 57-64 (2002).
13. N. Cochrane, “VFX-1 Virtual Reality Helmet by Forte,” GameBytes, (1994).
14. S. Lee, Y. Jo, D. Yoo, J. Cho, D. Lee, and B. Lee, “Tomographic near-eye displays,” Nat. Commun. 10, 1-10 (2019).
15. J. W. Goodman, Introduction to Fourier Optics, 3rd eds. (McGraw (McGraw-Hill, New York, 2002).
16. M. Faraday, “Thoughts on ray vibrations,” Philos. Mag. 28, 345–350 (1846).
17. A. Gershun, “The light field,” Moscow, 1936, P. Moon and G. Timoshenko, translators, J. Math. Phys. XVIII, 51–151 (1939).
18. X. Xia, X. Zhang, L. Zhang, P. Surman, and Y. Zheng, “Time-multiplexed multi-view three-dimensional display with projector array and steering screen,” Opt. Express 26, 15528-15538 (2018).
19. D. Smalley, E. Nygaard, K. Squire, J. Van Wagoner, J. Rasmussen, S. Gneiting, K. Qaderi, J. Goodsell, W. Rogers, and M. Lindsey, “A photophoretic-trap volumetric display,” Nature 553, 486-490 (2018).
20. S. Tay, P.-A. Blanche, R. Voorakaranam, A. Tunç, W. Lin, S. Rokutanda, T. Gu, D. Flores, P. Wang, and G. Li, “An updatable holographic three-dimensional display,” Nature 451, 694-698 (2008).
21. T. Kozacki, M. Kujawińska, G. Finke, W. Zaperty, and B. Hennelly, “Holographic capture and display systems in circular configurations,” J. Disp. Technol. 8, 225–232 (2012).
22. K. Wakunami, P.-Y. Hsieh, R. Oi, T. Senoh, H. Sasaki, Y. Ichihashi, M. Okui, Y.-P. Huang, and K. Yamamoto, “Projection-type see-through holographic three-dimensional display,” Nat. Commun. 7, 1-7 (2016).
23. A. Askin, G. Boyd, J. Dziedzic, R. Smith, A. Ballman, J. Levinstein, and K. Nassau, “Optically-induced refractive index inhomogeneities in LiNbO3 and LiTaO3,” Appl. Phys. Lett 9, 111 (1966).
24. F. S. Chen, J. T. LaMacchia, and D. B. Fraser, “HOLOGRAPHIC STORAGE IN LITHIUM NIOBATE,” Appl. Phys. Lett 13, 223-225 (1968).
25. F. Chen, “Optically induced change of refractive indices in LiNbO3 and LiTaO3,” J. Appl. Phys. 40, 3389-3396 (1969).
26. N. V. Kukhtarev, V. B. Markov, S. G. Odulov, M. S. Soskin, and V. L. Vinetskii, “Holographic storage in electrooptic crystals. i. steady state,” Ferroelectrics 22, 949-960 (1978).
27. M. Cronin-Golomb, J. O. White, B. Fischer, and A. Yariv, “Exact solution of a nonlinear model of four-wave mixing and phase conjugation,” Opt. Lett. 7, 313-315 (1982).
28. A. Yariv, and D. M. Pepper, “Amplified reflection, phase conjugation, and oscillation in degenerate four-wave mixing,” Opt. Lett. 1, 16-18 (1977).
29. J. Feinberg, “Asymmetric self-defocusing of an optical beam from the photorefractive effect,” J. Opt. Soc. Am. 72, 46–51 (1982)..
30. P. Yeh, “Two-wave mixing in nonlinear media,” IEEE J. Quantum Electron. 25, 484–519 (1989).
31. R. A. Fisher, Optical phase conjugation (Academic Press, 2012).
32. C. C. Sun, R. H. Tsou, W. Shen, H. H. Chan, J. Y. Chan, and M. W. Chan, “Shearing interferometer with a Kitty self-pumped phase-conjugate mirror,” Appl. Opt. 35, 1815-1819 (1996).
33. W. C. Su, C. C. Sun, Y. C. Chen, and Y. Ouyang, “Duplication of phase key for random-phase-encrypted volume holograms,” Appl. Opt. 43, 1728-1733 (2004).
34. C. C. Sun, and W. C. Su, “Three-dimensional shifting selectivity of random phase encoding in volume holograms,” Appl. Opt. 40, 1253-1260 (2001).
35. C. C. Sun, S. Yeh, M. W. Chang, and K. Y. Hsu, “Optimal incident conditions for a Cat-type self-pumped phase-conjugate mirror,” Appl. Opt. 31, 5769-5772 (1992).
36. B. Wang, C. C. Sun, W. C. Su, and A. E. Chiou, “Shift-tolerance property of an optical double-random phase-encoding encryption system,” Appl. Opt. 39, 4788-4793 (2000).
37. W. C. Su, Y. W. Chen, Y. Ouyang, C. C. Sun, and B. Wang, “Optical identification using a random phase mask,” Opt. Commun. 219, 117-123 (2003).
38. C. C. Sun, W. C. Su, B. Wang, and A. E. Chiou, “Lateral shifting sensitivity of a ground glass for holographic encryption and multiplexing using phase conjugate readout algorithm,” Opt. Commun. 191, 209-224 (2001).
39. H. F. Yau, H. C. Kung, H. Y. Lee, C. C. Sun, T. C. Chen, C. C. Chang, Y. P. Tong, and J. Chen, “Ordinary polarized phase conjugator using the photovoltaic effect,” Opt. Commun. 184, 257-263 (2000).
40. Z. Yaqoob, D. Psaltis, M. S. Feld, and C. Yang, “Optical phase conjugation for turbidity suppression in biological samples,” Nat. Photonics 2, 110-115 (2008).
41. I. M. Vellekoop, M. Cui, and C. Yang, “Digital optical phase conjugation of fluorescence in turbid tissue,” Appl. Phys. Lett. 101, 081108 (2012).
42. M. Cui, and C. Yang, “Implementation of a digital optical phase conjugation system and its application to study the robustness of turbidity suppression by phase conjugation,” Opt. Express 18, 3444-3455 (2010).
43. Y. M. Wang, B. Judkewitz, C. A. DiMarzio, and C. Yang, “Deep-tissue focal fluorescence imaging with digitally time-reversed ultrasound-encoded light,” Nat. Commun. 3, 1-8 (2012).
44. B. Judkewitz, Y. M. Wang, R. Horstmeyer, A. Mathy, and C. Yang, “Speckle-scale focusing in the diffusive regime with time reversal of variance-encoded light (TROVE),” Nat. Photonics 7, 300-305 (2013).
45. K. Si, R. Fiolka, and M. Cui, “Fluorescence imaging beyond the ballistic regime by ultrasound-pulse-guided digital phase conjugation,” Nature photonics 6, 657-661 (2012).
46. M. Jang, A. Sentenac, and C. Yang, “Optical phase conjugation (OPC)-assisted isotropic focusing,” Opt. Express 21, 8781-8792 (2013).
47. M. Cui, and C. Yang, “Optical phase conjugation 4Pi microscope,” California Institute of Techology, US Patent US8830573 B2 (2014).
48. I. N. Papadopoulos, S. Farahi, C. Moser, and D. Psaltis, “Focusing and scanning light through a multimode optical fiber using digital phase conjugation,” Opt. Express 20, 10583-10590 (2012).
49. I. N. Papadopoulos, S. Farahi, C. Moser, and D. Psaltis, “High-resolution, lensless endoscope based on digital scanning through a multimode optical fiber,” Biomed. Opt. Express 4, 260-270 (2013).
50. C. L. Hsieh, Y. Pu, R. Grange, and D. Psaltis, “Digital phase conjugation of second harmonic radiation emitted by nanoparticles in turbid media,” Opt. Express 18, 12283-12290 (2010).
51. M. Jang, H. Ruan, H. Zhou, B. Judkewitz, and C. Yang, “Method for auto-alignment of digital optical phase conjugation systems based on digital propagation,” Opt. Express 22, 14054-14071 (2014).
52. D. Wang, E. H. Zhou, J. Brake, H. Ruan, M. Jang, and C. Yang, “Focusing through dynamic tissue with millisecond digital optical phase conjugation,” Optica 2, 728-735 (2015).
53. D. Gabor, “A new microscopic principle,” Nature 161, 777-778 (1948).
54. E. N. Leith, and J. Upatnieks, “Reconstructed wavefronts and communication theory,” J. Opt. Soc. Am. 52, 1123-1130 (1962).
55. E. N. Leith, and J. Upatnieks, “Wavefront reconstruction with continuous-tone objects,” Opt. Soc. Am. 53, 1377-1381 (1963).
56. J. M. Palmer, and B. G. Grant, The art of radiometry, (SPIE, 2009).
57. S. N. Chandrasekaran, H. Ligtenberg, W. Steenbergen, and I. M. Vellekoop, “Using digital micromirror devices for focusing light through turbid media,” Proc. SPIE 8979, 897905 (2014).
58. Y. Liu, C. Ma, Y. Shen, J. Shi, and L. V. Wang, “Focusing light inside dynamic scattering media with millisecond digital optical phase conjugation,” Optica 4, 280-288 (2017).
59. I. M. Vellekoop, “Controlling the propagation of light in disordered scattering media,” Ph.D. thesis (University of Twente, 2008).
60. I. M. Vellekoop, and A. Mosk, “Focusing coherent light through opaque strongly scattering media,” Opt. Lett. 32, 2309-2311 (2007).
61. A. Papoulis, and S. U. Pillai, Probability, random variables, and stochastic processes, (Tata McGraw-Hill Education, 2002).
62. 陳致維，數位光學相位共軛用於立體影像顯示之研究，國立中央大學碩士論文，中華民國一百零八年。
63. Y. W. Yu, C. C. Sun, X. C. Liu, W. H. Chen, S. Y. Chen, Y. H. Chen, C. S. Ho, C. C. Lin, T. H. Yang, and P. K. Hsieh, “Continuous amplified digital optical phase conjugator for focusing through thick, heavy scattering medium,” OSA Continuum 2, 703-714 (2019).
64. P. Mouroulis, J. Macdonald, Geometrical Optics and Optical Design (Oxford U. Press, New York, 1997).
65. 孫慶成，光電工程概論，全華圖書股份有限公司，中華民國一百零一年。
66. 陳宇恆，基於數位光學相位共軛器浮空於多重鏡面之立體投影之研究，國立中央大學碩士論文，中華民國一百零六年。
67. G. Makey, Ö. Yavuz, D. K. Kesim, A. Turnalı, P. Elahi, S. Ilday, O. Tokel, and F. Ö. Ilday, “Breaking crosstalk limits to dynamic holography using orthogonality of high-dimensional random vectors,” Nat. Photonics 13, 251-256 (2019).

指導教授

孫慶成楊宗勳余業緯(Ching-Cherng Sun Tsung-Hsun Yang Yeh-Wei Yu)

審核日期

2020-8-11

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