簡易檢索 / 詳目顯示

回結果列表
研究生: 曾韋傑
Wei-Chieh Tseng
論文名稱: 基於全內反射透鏡的全景透鏡之設計與實作
The Design and Fabrication of Omnidirectional Lens Based on Total Internal Reflection Lens
指導教授: 黃忠偉
Jong-Woei Whang 
口試委員: 林宗翰
Tzung-Han Lin
孫沛立
Pei-Li Sun
趙涵
Han-Chieh Chao
學位類別: 碩士
Master
系所名稱: 應用科技學院 - 色彩與照明科技研究所
Graduate Institute of Color and Illumination Technology
論文出版年: 2016
畢業學年度: 104
語文別: 中文
論文頁數: 55
中文關鍵詞: 全內反射全景鏡頭成像設計光學設計影像解析
外文關鍵詞: Total internal reflection, Omnidirectional lens, the image design, optical design, image parsing
相關次數: 點閱:301下載:3
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報
  •  上一筆

    • 近年來資訊科技發展迅速,全景影像的應用越來越廣泛,包含了一般攝影、監控等領域,其中以監控所佔的產值及其比重均為最高。本研究以進行全內反射全景透鏡為主軸的全方位影像成像透鏡;從概念發展、全內反射全景透鏡設計到全內反射全景透鏡樣品製作。

    Based on Technology approaching, panorama image is applied widely, inclusive of general photography as well as monitor, to name but a few. Among the applications, monitor is the most valuable and most part of them. The main idea of this study is designed an omnidirectional lens which is using total internal reflection, from idea developing to design and implement included.

    中文摘要 i 英文摘要 ii 誌謝 iii 目次 iv 圖次 vi 表次 viii 第一章 緒論 1 1.1 研究背景 1 1.2 研究動機 1 1.3 內容概述 2 第二章 文獻探討 3 2.1 折射式全景系統(Dioptric Omnidirectional System) 3 2.2 折反射式全景系統(Catadioptric Omnidirectional System) 7 第三章 光學基礎理論 14 3.1 基本照明單位量 14 3.1.1 光通量 (Luminous Flux, Φ): 14 3.1.2 照度(Illuminance, E): 14 3.1.3 單位立體角 15 3.1.4 光強度(Luminous Intensity, I) 15 3.1.5 輝度(Luminance, L): 16 3.2 費馬定理 17 3.3 司乃爾定律 (Snell’s Law) 17 3.4 全反射 (Total internal reflection) 18 3.5 Fresnel Equation 19 3.6 光展量 20 第四章 全內反射式光學透鏡設計與分析 22 4.1 全內反射式光學透鏡光學架構之概念與介紹 22 4.2 全內反射全景光學元件設計方法 24 4.2.1 Model 1.0 25 4.2.2 Model 1.1 28 4.3 全內反射鏡頭成品之實現 31 4.3.1 光固化3D印表機 31 4.3.2 3D 列印後處理 36 4.3.2.1 砂紙拋光(Sanding) 37 4.3.2.2 珠光處理(Bead Blasting) 37 4.3.2.3 蒸汽平滑(Vapor Smoothing) 38 第五章 結果與討論 42 第六章 結論與未來展望 45 參考文獻 46

    [1] Adorni, G., Cagnoni, S., Mordonini, M., & Sgorbissa, A. (2003). Omnidirectional stereo systems for robot navigation. Paper presented at the Computer Vision and Pattern Recognition Workshop, Madison, Wisconsin, USA.
    [2] Chan, C., Li, L., Lee, W., & Wong, H. (2016). Use of nano-droplet-enriched cutting fluid (NDCF) in ultra-precision machining. The International Journal of Advanced Manufacturing Technology, 84(9-12), 2047-2054.
    [3] Cheng, D., Gong, C., Xu, C., & Wang, Y. (2016). Design of an ultrawide angle catadioptric lens with an annularly stitched aspherical surface. Optics Express. doi:10.1364/OE.24.002664
    [4] Corporation, Z. D. (2004). ZEMAX光學設計程式使用手冊 (訊技科技有限公司, Trans.).
    [5] Goodman, J. w. (2004). Introduction to Fourier Optics (3rd ed.). United States: Ben Roberts.
    [6] Hecht, E. (2002). Optics: Addison-Wesley.
    [7] Huang, F., Klette, R., & Scheibe, K. (2008). Panoramic Image: sensor-line cameras and laser range-finders. United Kingdom: John Wieley & Sons Ltd.
    [8] Ito, S., Iijima, D., Hayashi, A., Aoyama, H., & Yamanaka, M. (2002). Micro Turning System: A Super Small CNC Precision Lathe for Microfactories. Proceedings of ASPE’s, 16, 295-298.
    [9] Junior, V. G., & Junior, J. O. (2006). Development of an Omnidirectional
    [10] Vision System. Journal of the Brazilian Society of Mechanical Sciences and Engineering.
    [11] Krishnan, G., & Nayar, S. K. (2009). Cata-Fisheye Camera for Panoramic Imaging. Paper presented at the Applications of Computer Vision, Copper Mountain, CO.
    [12] Mahajan, V. N. (2014). 像差光學概論 (馬仕信, 陳志宏, 李宣皓, 羅翊戩, 林哲巨, 鄭智元, 蔡直佑, & 孫慶成, Trans. 初版 ed.). 台北市: 五南圖書出版股份有限公司.
    [13] Malacra-Hernandez, D., & Malacara-Hernandez, Z. (2012). Handbook of optical design (3th ed.): CRC Press.
    [14] Martin, C. B. (2004). Design issues of a hyper-field fisheye lens. Paper presented at the SPIE Conference Proceedings.
    [15] Navigation. (2013). OCamCalib: Omnidirectional Camera Calibration Toolbox for Matlab. Retrieved from https://sites.google.com/site/scarabotix/ocamcalib-toolbox
    [16] Pernechele, C. (2016). Hyper hemispheric lens. OPTICS EXPRESS. doi:0.1364/OE.24.005014
    [17] Scaramuzza, D. (2014). Omnidirectional Camera. In K. Ikeuchi (Ed.), in Computer Vision: A Reference Guide.
    [18] spaeck, L. (2007, Friday, 16-Mar-2007 14:32:20 GMT). Omnidirectional Vision. Retrieved from http://cswww.essex.ac.uk/mv/images.html
    [19] Stratasys. (2016). PolyJet Materials Data Sheet.
    [20] Tisse, C.-L. (2005). Low-cost miniature wide-angle imaging for self-motion estimation. OPTICS EXPRESS. doi:10.1364/OPEX.13.006061
    [21] Wang, J., Liang, Y., & Xu, M. (2015). Design of panoramic lens based on ogive and aspheric surface. Optics Express. doi:10.1364/OE.23.019489
    [22] Winston, R., Miñano, J. C., & & Benitez, P. (2005). Nonimaging optics. Academic Press.
    [23] 王民良. (2011). 反射折射式攝影機於地方辨識和三維場景重建之研究. (博士), 國立中正大學.
    [24] 王尊信. (2011, 2011/01/03). 光通量(Luminous flux). Retrieved from http://highscope.ch.ntu.edu.tw/wordpress/?p=18821
    [25] 訊技科技有限公司. (2005). ZEMAX葵花寶典 - 快速學習手冊: 訊技科技有限公司.
    [26] 張宛如. (2014). 顛覆傳統的製造革命–3D列印. Retrieved from https://scitechvista.nat.gov.tw/zh-tw/feature/c/0/14/10/81/1436.htm
    [27] 張榮森. (2011). 幾合光學:光學原理與設計應用: 五南圖書出版股份有限公司.

    QR CODE