Please use this identifier to cite or link to this item: http://hdl.handle.net/11455/4228
標題: 色序背光在電濕潤光閥之色彩顯示研究
Color Appearance of Electrowetting Light Valve using Color Sequential Back Light
作者: 灍壯宇
Cyue, Jhuang-Yu
關鍵字: Electrowetting Light Valve;電濕潤光閥;Electrowetting Display;Color Sequential;Color Breakup;電濕顯示器;色序法;色分裂現象
出版社: 精密工程學系所
引用: 1. 蔡宇翔,色序驅動應用之視覺量化探討,中興大學,2007。 2. 呂國弘,電濕顯示器多區塊圖形驅動對反應時間之影響,中興大學,2007。 3. 程孝龍,電濕潤顯示器製程與反應時間之影響,中興大學,2008。 4. L. Arend, J. Lubin, J. Gille, J. Larimer, “Color Breakup in Sequentially Scanned LCDs”, SID, pp.201-204, DIGEST 1994. 5. D. L. Post, A. L. Nagy, P. Monnier, C. S. Calhpun, “Predicting Color Breakup on Filed-Sequential Displays: Part 2”, SID, pp.1037-1039, DIGEST 1998. 6. F. Yamada, H. Nakamura, Y. Sakauchi, and Y. Taira, “Color sequential LCD based on OCB with an LED backlight”, SID, pp.1180-1183, DIGEST 2000. 7. N. Koma, T. Miyashita, T. Uchida, and N. Mitani, “Color sequential LCD using an OCB-TFT-LCD”, SID, pp.632-635, DIGEST 2000. 8. 顧鴻壽,平面面板顯示器基本概論,高立圖書有限公司,2005。 9. auod590,http://blog.udn.com/auod590/1498510,2007 10. OLED BLOG,http://oledtech.blogspot.com/search/label/OLED%20%E7%94%A2%E6%A5%AD%E7%99%BC%E5%B1%95,2008 11. Pochi Yeh, “Optics Of Liquid Crystal Displays”, Wiley l999. 12. B. J. Feenstra1, R. A. Hayes, “A reflective display based on electrowetting: principle and properties”, IDRC, P.51, 2003. 13. Robert A. Hayes, B. J. Feenstra, “Video-speed electronic paper based on electrowetting”, Nature Vol.425, pp.383-385, 2003. 14. Robert A. Hayes, B. J. Feenstra, “Liquid behavior inside a reflective display based on electrowetting”, Journal of Applied Physics, Vol.95 number8, pp.4389-4396, 2004. 15. B. J. Feenstra1, R. A. Hayes, “Rapid switching in multiple color active driven electrowetting displays”, IDW/AD, pp.861-864, 2005. 16. Paul Hauser, “Lab on a chip”, Features, P.38, 2008 17. Kuiper, S. and B. H. W. Hendriks (2004). "Variable-focus liquid lens for miniature cameras." Applied Physics Letters 85(7): 1128-1130. 18. 大田登著,陳鴻興譯,基礎色彩再現工程,全華出版社,2004。 19. N. Koma, T. Miyashita, T. Uchida, and N. Mitani, “Color sequential LCD using an OCB-TFT-LCD”, SID, pp.632-635, DIGEST 2000. 20. *Norio Koma and Tatsuo Uchida, “A Novel Display Method for Field Sequential Color LCD without Color Break-up”, SID, pp.400-403, DIGEST 2001. 21. 台証投顧通路研究組,TFT-LCD顯示器新應用-LED背光模組,台証投顧,2007 22. Beni, G. and S. Hackwood (1981). "Electro-wetting displays." Applied Physics Letters 38(4): 207-209. 23. Hayes, R. A. and B. J. Feenstra (2003). "Video-speed electronic paper based on electrowetting." Nature 425(6956): 383-385. 24. J. C. Heikenfeld and A. J. Steckl, “Liquid Light”, Information Display, 26, 11/04. 25. Heikenfeld, J. and A. J. Steckl (2005). "Intense switchable fluorescence in light wave coupled electrowetting devices." Applied Physics Letters 86(1): 011105. 26. A. J Steckl, J. C. Heikenfeld and S. C. Allen, “Light Wave Coupled Flat Panel Displays and Solid-State Light Using Hybrid Inorganic/Organic Materials”, IEEE/OSA JDT, Vol. 1, No. 1, 2005.。 27. 陳致維,http://www.ieo.nctu.edu.tw/comm1/viewtopic.php?CID=46&Topic_ID=35 國立交通大學,2006。 28. 陳啟鈞,跳視眼球運動之模擬,成大醫工所,2002年。 29. S. D. Yeo, C. H. Oh, “LCD Technologies foe the TV Application”, SID, pp.1738-1741, DIGEST 2005. 30. Mr. OH, “CCD VS CMOS”, http://oaunix.hlhs.hlc.edu.tw/mroh/index-oh2.htm, 2003 31. DC VIEW編輯部,http://www.dcview.com.tw/article/newreadarticle.asp?id=7039,2008。 32. Daigo Sasaki, Masao Imai, “Motion Picture Simulation for Designing High-Picture Quality Hold-Type Display”, SID, pp.926-929, DIGEST 2002 33. VESA, “FLAT PANEL DISPLAY MEASUREMENTS STANDARD Version 2.0”, June 1, 2001. 34. X. Zhang and J. E. Farrell, “Sequential color breakup measured with induced saccades”, SPIE, pp.210-217, 2003. 35. H. Yamakita, M. Sakai, Y. Taniguchi*, J. Asayama, and K. Adachi, “Field-Sequential Color LCD driven by Optimized Method for Color Breakup Reduction”, IDW/AD, pp.83-86, 2005. 36. Julien T., Khaled S. and Alain T., “Evaluation of Next-generation Color Wheels for Field Sequential Color Displays”, Image Quality and System Performance III, Proceedings of SPIE, Vol. 6059, 2006. 37. DuPont,http://www2.dupont.com/Teflon_Industrial/en_US/products/product_by_name/teflon_af/index.html. 38. http://beb.anyday.com.tw/forum/viewthread.php?tid=12925&extra=&page=5 39. 廖雪峰,背光模組產業展望, http://www.tisc.com.tw/new/newreport/special/upload/special20061103-2.pdf,2006 40. 郭俊偉,液晶顯示面板之自動化光學檢測系統,國立台灣科技大學,2006。 41. 羅國隆、鄭惟元,電濕潤顯示器(electrowetting display)技術之近況發展,工研院顯示中心,2008。 42. 張郁培/羅國隆/鄭惟元,低耗能顯示器需求殷 反射式顯示器展露鋒芒,新電子2009年3月號276期。 43. 胡一君,數位微流體實驗室晶片 儀科中心簡訊第69期,ITRC奈米技術組,2005。 44. B. H. W. Hendriks, S. Kuiper, M. A. J. Van As, C. A. Renders, and T. W. Tukker, "Electrowetting-based variable-focus lens for miniature systems," Optical Review 12, 255-259 (2005). 45. 彭孟超,液滴透鏡曲率調控機制之探討,國立中央大學,2008。 46. Varioptic, http://www.varioptic.com/en/index.php. 47. 呂柏璋,LCD面板之LED背光燈色序法與區域控制驅動系統,國立中正大學,2007。 48. K.-C. Lee, et al. , “Integrated Amorphous Silicon Color Sensor on TFT-LCD,” Proceedings of the IEEE Solid-State Sensors, Actuators and Microsystems Conf., 2005, pp. 1035-1038. 49. S. Muthu, F. J. Schuurmans and M. D. Pashley, “Red, Green, and Blue LEDBased White Light Generation: Issues and Control,” Proceedings of the IEEE Industry Applications Conf., 2002, pp. 327-333. 50. S. Muthu, F. J. Schuurmans and M. D. Pashley, “Red, Green, and Blue LEDs for White Light Illumination,” IEEE Trans. on Quantum Electronics, Vol. 8, No. 2, 2002, pp. 333-338. 51. S. Muthu and J. Gaines, “Red, Green, and Blue LED-based White Light Source: Implementation Challenges and Control Design,” Proceedings of the IEEE Industry Applications Conf., 2003, pp. 515-522. 52. aber,Sony Bravia HDTV新款XR1系列LED背光技術,LEDinsdie,2008 http://www.ledinside.com.tw/news_Sony_RGB%20LED%20TV_20080902。 53. Emma,奇美展示採用RGB LED背光的新一代變色龍技術(Hyperchameleon),http://www.ledinside.com.tw/news_Chimei_panel_20080520,LEDinsdie,2008。 54. Fang-Cheng Lin1, Yi-Pai Huang2, Ching-Ming Wei1, and Han-Ping D. Shieh2, “Stencil-FSC Method for Color Break-Up Suppression and Low Power Consumption in Field-Sequential LCDs”, SID 2008. 55. Shuyun Zhao1, Zhiguo Meng1,2, Yuetwing Li1, Man Wong1 and Hoi Sing Kwok, “A 3 inch Active Matrix for Color Sequential- Liquid Crystal Display(CS-LCD) Based on Metal Induced Continuous Zonal Domain (CZD) Polycrystalline Silicon Technology”, SID 2008. 56. 莫啟能,色序法技術發展及其在顯示器系統的光機自動化應用,中華映管公司 光電處處長,自動化 2007。 57. 德州儀器亞洲區DLP事業部門,DLP™技術概要,元件科技2003年9月號。 58. Masaki Ogata, Kazuhiko Ukai, and Takashi Kawai, “Visual Fatigue in Congenital Nystagmus Caused by Viewing Images of Color Sequential Projectors,” Journal of Display Technology, vol. 1, no.2, pp. 314-319, 2005. 59. 廖俊謙,色彩調效技術與顯示器構色原理之分析,國立中央大學,2006。 60. S. Paolini, G. Harbers and W. L. Snyder, “Backlight for a Color LCD,” U.S. Patent 6,791,636, Sep. 14, 2004. 61. pharos,噴印(Inkjet Printing)技術近況與發展,2006。http://tw.myblog.yahoo.com/jw!14DYPKeCGBaOMNOzG0kICw--/article?mid=66 62. 劉德雅,廣色域液晶顯示器色彩特性與色序優化之研究,世新大學,2007。 63. Chih-Cheng Chan, Guo-Feng Wei, Hui Chu-Ke, Sheng-Wen Cheng, Shih-Chang Chu, Ming-Sheng Lai, Arex Wang, “Development of Multi-Primary Color LCD”, AU Optronics. 64. 張友鴻,六原色液晶顯示器分色技術之研究,世新大學,2006。 65. Young-Chol Yang, Keunkyu Song, SooGuy Rho, Nam-Seok Rho, SungJin Hong, Kang Beo Deul, Munpyo Hong, and Kyuha Chung, ” Development of Six Primary-Color LCD”, SID 2005 Digest pp. 1210-1213.
摘要: 
電濕潤光閥(Electrowetting Light Valve)為近幾年來新發展出的顯示技術,電濕顯示器(Electrowetting Display)利用材料間表面張力(Surface tension)的差異,施以電壓以改變疏水材料之表面能,進而改變帶染料之油墨的佔空比,以達成顯示的目的。也因為電濕潤光閥其快速反應、廣視角、光利用率高等特性,而在黑色油墨若能繼續發展有可能取代TFT-LCD。而本研究中所使用的色序法背光模組則因本身具有的高解析度、廣色域且不需使用彩色濾光片,成為目前極具潛力的背光模組。
本研究中,首先先介紹所使用的電濕潤光閥製程方式與結構,再量測不同色序法背光的驅動波形,並針對各驅動波形所產生的色分裂現象進行分析,最後嘗試將色序法背光與電濕潤光閥做結合,並觀察色序法背光在電濕潤光閥下色彩變化的情形。

Electrowetting light valve(ELV) is a novel display technology developed in few years ago. For utilization surface tension between different materials .By applying voltage on the device, it makes the changes of the hydrophobic substrate surface energy and white area, and could be a display instrument. Electrowetting light valve because of its rapid response, wide viewing angle, higher utilization of optical properties, it should be a replacement of LCD if the oil black could be developed. In this thesis, we used the backlight of color sequential method is due to the high-resolution, wide color gamut without the color filters, the current potential of the backlight module.
In this thesis, first we introduced the electrowetting light valve process and structure. Then we measured the different drive waveform of color sequential backlight, and analyze that the driving waveforms that bring color breakup, finally we try to combine color sequential backlight and electrowetting light valve, and observe the color changing situation of color sequential backlight under the Electrowetting light valve.
URI: http://hdl.handle.net/11455/4228
其他識別: U0005-2008200915132800
Appears in Collections:精密工程研究所

Show full item record
 
TAIR Related Article

Google ScholarTM

Check


Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.