跳到主要內容

簡易檢索 / 詳目顯示

回結果列表
研究生: 徐英舜
YING-SHUN SYU
論文名稱: 汽車超大廣角於溫度-30C至70C消熱差與高相對照度之鏡頭設計
指導教授: 孫文信
Wen-Shing Sun
口試委員:
學位類別: 碩士
Master
系所名稱: 理學院 - 光電科學與工程學系
Department of Optics and Photonics
論文出版年: 2017
畢業學年度: 105
語文別: 中文
論文頁數: 142
中文關鍵詞: 汽車超大廣角消熱差汽車超大廣角高相對照度
外文關鍵詞: ultra-wide lens design, athermal
相關次數: 點閱:8下載:0
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

    • 本論文提出一五百萬畫素超大廣角鏡頭設計,由7片玻璃鏡片所組成,鏡頭焦距為1.649 mm,鏡頭長度23.235 mm,F/#為2.1,最大半視角為80,在鏡片優化中我們保持系統的焦距不變之條件下,同時消除色差與消熱差之設計。
    考量廣角鏡頭在大視角區域時其影像會有被嚴重壓縮之特性,將傳統的光學畸變評估方式成改以F-theta畸變作為檢視該光學系統的成像扭曲程度。並考量汽車使用之環境溫度範圍,與大視場角相對照度之控制。
    不同的鏡片材料有不同的熱膨脹係數,在室溫(T0)條件下鏡片的參數如曲率半徑R,厚度D,以及非球面係數a4、a6、a8,當環境溫度變化(T)時,會因鏡片材料熱膨脹係數影響與溫度改變(T=T-T0),而改變其鏡片參數如曲率半徑R,厚度D,以及非球面係數a4、a6、a8。故在光學系統在消熱差的條件方面,由光學系統所選擇的玻璃材料的溫度係數(dn/dT)與鏡片熱膨脹係數可推得溫度改變導致的屈光度變化,而當光學系統的屈光度變化不為零時,則可利用鏡筒材料的熱膨脹係數(β)或藉由改變鏡片材料達到消熱差。
    在室溫下(20C)單一溫度之鏡頭優化設計,可得鏡頭在空間頻率180 lp/mm 下之MTF至少大於0.57,但在溫度-30C至70C範圍其鏡頭MTF(180 lp/mm)降為0.423以上,而鏡頭MTF最低的位置在室溫70C的環境。最後針對-30C至70C做鏡頭優化設計,我們考量玻璃材料之熱膨脹係數,鏡筒熱膨脹係數,與7片鏡片材料,對於達成無熱化可以得到很好的效果。
    最終設計為7片玻璃鏡片,其中含2片非球面鏡片,其鏡頭成像品質在溫度範圍-30C至70C間,MTF(180 lp/mm)至少大於0.597,其MTF變化值在0.597至0.627範圍內。相對照度至少大於89.75%,其相對照度變化值在89.75%至90.53%範圍內。橫向色差至少小於0.851 m,其橫向色差的變化值在0.851 m至0.543 m範圍內。F-theta distortion至少小於0.90%,其F-theta distortion的變化值在0.90%至0.83%範圍內。

    This paper proposed a ultra-wide lens design, which has 5 Mega pixel, and compose of seven glass, the focal length of the lens is 1.649 mm, the total length is 23.235 mm, F/# is 2.1, the maximum of half field-of-view is 80 degree. In the lens optimization we maintain the system's focal length of the same conditions, While eliminating the design of chromatic aberration and athermal dissipation.
    Consider the wide-angle lens in the large viewing area of the image will be severely compressed features, The traditional optical distortion assessment method was changed to F-theta distortion as a view of the degree of imaging distortion of the optical system. And consider the use of the ambient temperature range of the car,and the control of the large field angle relative to the illumination.
    Different lens materials have different coefficients of thermal expansion,
    at room temperature(T0) conditions, such as the parameters of the lens radius of curvature(R), thickness(D), and aspheric coefficient (a4、a6、a8), when the ambient temperature changes, due to the thermal expansion coefficient of the lens material  and temperature changes(T=T-T0), and change the lens parameters. Therefore, in the optical system in the athermal conditions, Therefore, in the optical system in the athermal conditions,the temperature coefficient of the glass material selected by the optical system and the coefficient of thermal expansion of the lens can be used to estimate the diopter change due to the temperature change. And when the dioptric change of the optical system is not zero, you can use the lens barrel material thermal expansion coefficient(β) or change the lens material to achieve athermal.
    At room temperature(20C),the single temperature of the lens optimization design, you can get the lens at a spatial frequency of 180 lp / mm MTF at least greater than 0.57,but the lens MTF in the range of -30°C to 70°C is reduced to at least 0.423 ,while the lens MTF has the lowest position at room temperature of 70°C. Finally, for the temperature range of -30 ° C to 70 ° C lens optimization design, we consider the glass material thermal expansion coefficient, barrel thermal expansion coefficient, and 7 lens material, for the realization of athermalized can get very good results.
    The final design for the seven glass lenses, which contains two aspherical lenses, lens imaging quality MTF (180 lp / mm) is at least greater than 0.597 in the temperature range of -30°C to 70°C, MTF changes in the range of 0.597 to 0.627. The relative illuminance is at least greater than 89.89%,and the change in relative illuminance is in the range of 89.75% to 90.53%. Lateral chromatic aberration is at least less than 0.851 m, and the change in lateral chromatic aberration is in the range of 0.851 m to 0.543 m. F-theta distortion is at least less than 0.9%, and the change in F-theta distortion is in the range of 0.9% to 0.83%.

    摘要 I ABSTRACT III 致謝 V 目錄 VI 圖目錄 IX 表目錄 XV 第一章 緒論 1 1-1 前言 1 1-2 研究動機 1 1-3 文獻回顧 2 1-4 論文架構 11 第二章 理論 12 2-1 玻璃折射率與波長關係 12 2-2 玻璃折射率與溫度關係 13 2-3 溫度變化與熱膨脹係數對鏡片參數的影響關係式 15 2-4 折光度變化與dn/dt關係 17 2-5 相對照度定義 20 2-5-1 照度與相對照度 20 2-5-2 鏡片穿透率分析 22 2-5-3 立體角與投影立體角 23 2-5-4 立體角與投影立體角 28 2-6 Distortion (畸變) 30 2-6-1 光學畸變 30 2-6-2 F-theta畸變 32 2-7 光暈(Vignetting)對成像系統的影響 34 2-7-1 光暈定義 34 2-7-2 光暈係數與鏡面有效半徑之關係 35 第三章 設計流程 38 3-1 感測器規格與設計目標 38 3-2 設計起始值之選取 41 3-3 溫度範圍選取 43 3-4 材料優化範圍設定 44 3-5 在室溫下(20C)之鏡頭優化設計 45 3-6 環境溫度-30C至70C之參數值的設定 48 3-7 針對-30C至70C之鏡頭優化設計 57 3-7-1 在-30C、20C與70C之多重組態優化 57 3-7-2 改變材料之消熱差補償 60 第四章 設計結果 62 4-1 設計目標與設計結果比較 62 4-1-1設計結果之鏡組資料與相關參數 62 4-1-2設計結果之成像品質分析 65 4-2 公差分析 103 第五章 結論與未來展望 106 附錄一(不同玻璃之色散係數) 107 附錄二(溫度係數常數) 110 附錄三(10mm之鏡片內部穿透率) 113 附錄四(25mm之鏡片內部穿透率) 116 參考資料 119

    1. D. S. Grey, "Athermalization of Optical Systems," J. Opt. Soc. Am. 38, 542-546 (1948).
    2. M. J. Duggin, “Discrimination of targets from background of similartemperature, using two-channel data in the 3.5-4.1-um and 11–12-umregions,” Appl. Opt. 25(7), 1186–1195 (1986).
    3. M. H. Horman, “Temperature analysis from multispectral infrareddata,” Appl. Opt. 15(9), 2099–2104 (1976).
    4. L. Friedman, “Thermo-optical analysis of two long-focallengthaerial reconnaissance lenses,” Opt. Eng. 20, 161-165(1981).
    5. P. J. Rogers, “Athermalized FLIR optics,” Proc. SPIE 1354, 742-751 (1990).
    6. J. L. Rayces, L. Lebich, “Thermal compensation of infrared achromatic objectives with three optical materials,” Proc. SPIE 1354, 752-759 (1990).
    7. Y. Tamagawa, S. Wakabayashi, T. Tajime, and T. Hashimoto, “Multilens system design with an athermal chart,” Appl. Opt. 33, 8009-8013 (1994).
    8. Y. Tamagawa, T. Tajime, “Expansion of an athermal chart into a multilens system with thick lenses spaced apart,” Opt. Eng. 35, 3001-3006 (1996).
    9. T. H. Jamieson, "Thermal effects in optical systems," Opt.Eng. 20, 156-160 (1981).
    10. M. Roberts and P. J. Rogers, “Wide waveband infrared optics,” Proc.SPIE 1013, 84–91 (1988)
    11. T. H. Jamieson, “Ultrawide waveband optics,” Opt. Eng. 23(2), 111–116 (1984).
    12. Y. Tamagawa and T. Tajime, “Dual-band optical systems with a projectiveathermal chart: design,” Appl. Opt. 36(1), 297–301 (1997).
    13. V. Povey, Athermalization technique in infrared systems,Proc. SPIE, 655, 142–153 (1986).
    14. R. C. Simmons, ‘‘Stability of aberrations with temperature in fastthermal imaging zoom telescopes,’’ Proc. SPIE 916, 19–26 (1988).
    15. W. Shi, M. E. Couture, “Long wave infrared zoom projector thermal analysis and compensation,” Opt. Eng. 39, 2708-2714 (2000).
    16. C. W. Kuo, “Achromatic triplet and athermalized lens assembly for both midwave and longwave infrared spectra,” Opt. Eng. 53, 021102 (2014).
    17. C. W. Kuo, C. L. Lin, and C. Y. Han, “Dual field-of-view midwaveinfrared optical design and thermalization analysis,” Appl. Opt. 49(19), 3691–3700 (2010).
    18. D. W. Anderson, “M12 A2 tank commander’s independent thermalviewer optics: optics designperspective,”Proc. SPIE 1970, 128–138 (1993).
    19. M. Norland and A. Rodland,“Design of high performance IRsensor,”Proc. SPIE 2269, 462–471 (1994).
    20. C. W. Kuo, J. M. Miao, and C. H. Tai, “Midwave infrared optical zoomingdesign and kinoform degrading evaluation methods,” Appl. Opt. 50(18), 3043–3049 (2011).
    21. A. Goldberg, T. Fischer, and S. Kennerly, “Dual band QWIP MWIR/LWIR focal plane array test results,” Proc. SPIE 4028, 276–287 (2000).
    22. R. Simmons, P. A. Manning, and T. Chamberlain,“The designof passively athermalised narrow and wide field of view infraredobjectives for OBSERVER unmanned airvehicle,”Proc.SPIE 5612, 236–248 (2004).
    23. R. M. Hudyma, “Athermal MWIR Objectives,” Proc. SPIE 2540, 229-235 (1995).
    24. G. P. Behrmann and John P. Bowen, “Influence of temperature on diffractive lens performance,” Appl. Opt. 32, 2483-2489 (1993).
    25. M. Bayar, Ő. F. Farsakoğlu, “Mechanically active athermalization of a forward looking infrared system,” Infrared Physics & Technology 43, 91-99 (2002).
    26. R. Q. Wu, K. Huang, H. Yang, J. Wang, Y. Liu, “Analysis of athermalizing performance of thermal infrared optical system with Cassegrain antenna,” Optik 121, 1904-1907 (2010).
    27. O. V. Ponin and A. A. Sharov, “Apochromatic thermally nonmisadjustable objectives for wide-range multispectral space imaging,” J. Opt. Technol. 80, 230-232 (2013).
    28. Y. J. Kim, Y. S. Kim, and S. C. Park, “Simple graphical selection of optical materials for an athermal and achromatic design using equivalent Abbe number and thermal glass constant,” Journal of the optical society of Korea 19, 182-187 (2015).
    29. B. N. Walker, R. H. James, D. Calogero, and L. K. Liev, “Impact of environmental temperature on optical power properties of intraocular lenses, “Appl. Opt. 53, 453-457 (2014).
    30. Gao Ming, Chen Yang, Liu Jun, Lv Hong, “Design of dual-band shared-aperture Co-zoom optical system, “ Infrared Physics & Technology 64, 40-46 (2014).
    31. Schott, Optical Glass Catalogue Excel (Schott Inc., Germany, March, 2017).
    http://www.us.schott.com/advanced_optics/english/download/index.html
    32. Schott, “TIE-19: Temperature coefficient of the refractive index,” in Proc. Schott Technical information (Schott Inc., Germany, July 2008).
    https://lightmachinery.com/media/1552/schott_tie-19_temperature_coefficient_of_refractive_index.pdf
    33. Schott, “TIE-29: Refractive index and dispersion,” in Proc. Schott Technical information (Schott Inc., Germany, 2015).
    http://www.schott.com/d/advanced_optics/fa6ad229-516d-42e0-8921-498eb00c1742/1.0/schott_tie-29_refractive_index_and_dispersion_eng.pdf
    34. Solid Angle, https://zh.wikipedia.org/wiki/%E7%AB%8B%E9%AB%94%E8%A7%92
    35. Y. Bai, T. W. Xing, W. M. Lin and W. M. Xie, “Athermalization of middle infrared optical system,” J. Appl. Opt. 33(1),181-185 (2012).
    36. S. Thibault, J. Gauvin, M. Doucet and M. Wang, “Enhanced optical design by distortion control,” Proc. SPIE 5962, 596211 (2005).
    37. W. S. Sun, C. L. Tien, Y. H. Chen, P. Y. Chu, “Ultra-wide angle lens design with relative illumination analysis,” J. Eur. Opt. Soc. –Rapid 11, 16001 (2016).
    38. https://zh.wikipedia.org/wiki/%E7%95%B8%E8%AE%8A

    QR CODE
    :::