以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：7

、訪客IP：3.17.6.75

姓名	江家宇(Chia-Yu Chiang)  查詢紙本館藏	畢業系所	機械工程學系
論文名稱	基於全反射共光程偏振干涉術之折射率量測技術 (Refractive index measurement based on total internal reflection with common-path polarization interferometry)
相關論文	★ 外差光學式光柵干涉儀之研究 ★ 以二維影像重建三維彩色模型之色彩紋理貼圖技術與三維模型重建系統發展 ★ 雷射干涉儀於共焦顯微系統之軸向定位控制 ★ 偏振干涉術使用在量測旋光效應及葡萄糖濃度 ★ 準共光程干涉術之新式大尺度定位平台之研究 ★ 波長調制外差散斑干涉術應用於角度量測之研究 ★ 全場光強差動式表面電漿共振偵測技術 ★ 基於全內反射波長調制外差干涉術小角度測量 ★ 新型波長調制外差光源應用於位移量測 ★ 疊紋式自動準直儀系統 ★ 雙影像多視角結構光轉三維點資料技術發展 ★ 偏振式駐波干涉儀應用於位移量測 ★ 雙共焦顯微鏡用於物體厚度量測 ★ 以電漿診斷工具進行太陽電池用矽薄膜製程開發 ★ 點繞射干涉儀應用於透鏡之像差量測 ★ Gioia 和 Chakraborty 紊流摩擦係數模型之研究
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]   [檢視]  [下載] 本電子論文使用權限為同意立即開放。 已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。 請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。
摘要(中)	本研究開發一種「基於全反射共光程偏振干涉術之折射率量測技術」，能夠精準的量測不規則形狀物體折射率，且改善現階段量測固體折射率所遇到的問題。本技術是基於待測物與空氣之間的全反射現象進行折射率量測，不需額外的混和匹配液體做輔助即可完成。在全反射現象發生時，反射光的偏振態(垂直偏振與水平偏振)會引進不同的相位延遲。透過本研究提出的偏振干涉解相法可計算出反射光的相位差，並運用相位差極大值與折射率的量測方程式，即可推算不規則形狀物體的折射率。 本技術架構結合位移平台與偏振相機形成一共光程系統，不僅能快速調整待測物的全反射現象，也能夠降低架構的複雜性且達到快速擷取不同偏振態的光強度訊號。在共光程系統中，藉由光束聚焦與偏振干涉解相法，能在特定角度範圍的反射光中快速找到相位差極大值。另一方面，本技術的折射率量測方程式僅與單一參數(相位差極大值)有關。相較於其它量測方程式，不受焦距、曲率及精確入射角度等多參數的影響，適合用於量測不規則形狀物體的折射率。 本研究宗旨為開發折射率量測技術應用於不規則形狀的物體。本研究技術透過提出的偏振干涉解相技術與偏振相機做結合，分析出垂直與水平偏振的相位差極大值，再利用量測方程式計算不規則形狀物體的折射率。在量測實驗中，不規則形狀物體分別是不同材料的稜鏡、非球面透鏡及柱狀透鏡。運用這三種不規則形狀物體的量測，驗證本技術的性能及系統的解析度可達 1.6e-3 RIU (Refractive Index Unit)。
摘要(英)	This study develops a refractive index measurement based on total internal reflection with common-path polarization interferometry. The measurement can accurately obtain the refractive index of irregularly shaped samples and improve problems encountered in the measurement of solids currently. Based on the total internal reflection between samples and the air, this measurement can be used for the refractive index of samples without any additional matching liquids. When the total internal reflection occurs, the polarization states of the reflected light (vertical polarization and horizontal polarization) will introduce different phase shifts. The phase difference of the reflected light can be found by the polarization interference method proposed in this study. Then, the refractive index of samples can be obtained by the measurement equation which is the relationship between the maximum phase difference and the refractive index. The system of this measurement combines the displacement platform and the polarization camera to form a common optical path system, which can not only quickly adjust the total internal reflection, but also reduce the complication of the architecture and rapidly capture different polarization light intensity. In the common-path, by means of focused beam and polarization interference, the maximum phase difference can be quickly found in the reflected light with a range of incident angle. On the other hand, the refractive index measurement equation of this study is only related to the single parameter (the maximum phase difference). Compared with other measurement equations, it is not affected by multiple parameters such as focal length, curvature and precise incident angle, and is suitable for measuring the refractive index of irregularly shaped samples. The purpose of this study is to develop the refractive index measurement applied to irregularly shaped samples. By the proposed polarization interference with a polarization camera to analyze the maximum value of the phase difference between vertical and horizontal polarization, the system can use the measurement equation to obtain the refractive index of samples. In this study, the irregularly shaped samples include different materials of prisms, aspherical lens and cylindrical lens. By means of the measurement of these irregularly shaped samples, we demonstrate the feasibility of the proposed measurement and its system resolution of refractive index can be achieved to 1.6e-3 RIU (Refractive Index Unit).
關鍵字(中)	★ 折射率量測 ★ 相位差極大值 ★ 偏振干涉解相技術 ★ 偏振相機	關鍵字(英)	★ refractive index measurement ★ the maximum phase difference ★ polarization interference ★ polarization camera
論文目次	摘要 ............................................................................................................................................. I Abstract ...................................................................................................................................... II 致謝 .......................................................................................................................................... IV 圖目錄 .................................................................................................................................... VII 表目錄 ...................................................................................................................................... XI 第一章 緒論 .............................................................................................................................. 1 1-1 研究背景 ..................................................................................................................... 1 1-2 文獻回顧 ..................................................................................................................... 2 1-2-1 幾何式量測 ..................................................................................................... 2 1-2-2 液體浸沒法 ..................................................................................................... 3 1-2-3 干涉儀 ............................................................................................................. 6 1-3 研究動機、目的與方法 ........................................................................................... 11 1-4 論文架構 ................................................................................................................... 12 第二章 實驗原理 .................................................................................................................... 13 2-1 全反射原理 ............................................................................................................... 13 2-1-1 全反射現象 ................................................................................................... 13 2-1-2 全反射引入相位差 ....................................................................................... 17 2-1-3 相位差極大值與折射率關係 ....................................................................... 20 2-2 偏振干涉解相法 ....................................................................................................... 22 2-3 相位差分布 ............................................................................................................... 24 2-4 小結 ........................................................................................................................... 29 第三章 系統架構 .................................................................................................................... 30 3-1 系統設計 ................................................................................................................... 30 3-1-1 光學系統設計 ............................................................................................... 30 3-1-2 偏振相機 ....................................................................................................... 34 3-2 量測訊號處理 ........................................................................................................... 37 3-3 小結 ........................................................................................................................... 41 第四章 實驗結果與討論 ........................................................................................................ 42 4-1 全場相位差分布量測 ............................................................................................... 42 4-2 不規則形狀物體的量測 ........................................................................................... 45 4-2-1 重複性量測 ................................................................................................... 45 4-2-2 折射率分佈量測 ........................................................................................... 53 4-3 系統解析度 ............................................................................................................... 56 4-4 小結 ........................................................................................................................... 58 第五章 誤差分析 .................................................................................................................... 59 5-1 系統誤差 ................................................................................................................... 59 5-1-1偏振角度與消光比的影響 ............................................................................ 59 5-1-2 四分之一波片角度與延遲量的影響 ........................................................... 63 5-2 隨機誤差 ................................................................................................................... 67 5-2-1 環境光源 ....................................................................................................... 68 5-2-2 表面污點 ....................................................................................................... 69 5-3 小結 ........................................................................................................................... 70 第六章 結論與未來展望 ........................................................................................................ 71 6-1 結論 ........................................................................................................................... 71 6-2 未來展望 ................................................................................................................... 71 參考文獻 .................................................................................................................................. 72
參考文獻	[1] 科技部產學合作計畫(開發型) , “全反射偏振干涉術之開發與折射率量測應用,” 國立中央大學機械工程學系(計畫編號：109-2622-E-008-009-CC2). [2] L. Su, Y. Chen, A. Y. Yi, F. Klocke, and G. Pongs, “Refractive index variation in compression molding of precision glass optical components,” Appl. Opt. 47(10), 1662-1667 (2008). [3] S. Liu, Z. Deng, J. Li, J. Wang, N. Huang, R. Cui, Q. Zhang, J. Mei, W. Zhou, C. Zhang, Q. Ye, and J. Tian, “Measurement of the refractive index of whole blood and its components for a continuous spectral region,” J. Biomed. Opt. 24(3), 035003 (2019). [4] J. James, A. B. Unni, K. Taleb, J. P. Chapel, N. Kalarikkal, S. Varghese, G. Vignaud, and Y. Grohens, “Surface engineering of polystyrene–cerium oxide nanocomposite thin films for refractive index enhancement,” Nano-Struct. Nano-Obj. 17(1), 34-42 (2019). [5] D. Tentori and J. R. Lerma, “Refractometry by minimum deviation: accuracy analysis,” Opt. Eng. 29(2), 160-168 (1990). [6] G. Smith, “Liquid immersion method for the measurement of the refractive index of a simple lens,” Appl. Opt. 21(5), 755-757 (1982). [7] R. S. Kasana, A. Goswami, and K. Soni, “Non-destructive multiple beam interferometric technique for measuring the refractive indices of lenses,” Opt. Commun. 236(4-6), 289-294 (2004). [8] K. Soni and R. S. Kasana, “The use of defocussed position of a Ronchi grating for evaluating the refractive index of lens,” Opt. Laser Technol. 39(7), 1334-1338 (2007). [9] K. Soni and R. S. Kasana, “The role of an acousto-optic grating in determining the refractive index of a lens,” Meas. Sci. Technol. 18(5), 1667-1671 (2007). [10] C. Yang, L. Su, C. Huang, H. X. Huang, J. M. Castro, and A. Y. Yi, “Effect of packing pressure on refractive index variation in injection molding of precision plastic optical lens,”Adv. Polym. Technol. 30(1), 51-61 (2011). [11] M. H. Chiu, J. Y. Lee, and D. C. Su, “Refractive-index measurement based on the effects of total internal reflection and the uses of heterodyne interferometry,” Appl. Opt. 36(13), 2936-2939 (1997). [12] K. Chhaniwal, A. Anand, and C. S. Narayanamurthy, “Determination of refractive indices of biconvex lenses by use of a Michelson interferometer,” Appl. Opt. 45(17), 3985-3990 (2006). [13] E. A. Barbosa and S. C. dos Santos, “Refractive and geometric lens characterization through multi-wavelength digital speckle pattern interferometry,” Opt. Commun. 281(5), 1022-1029 (2008). [14] S. T. Lin and T. L. Lin, “Refractive index and thickness determinations using a dual-path Mach-Zehnder interferometer,” Key Eng. Mater. 381-382(1), 97-100 (2008). [15] L. Chen, X. Guo, and J. Hao, “Lens refractive index measurement based on fiber point-diffraction longitudinal interferometry,” Opt. Express 21(19), 22389-22399 (2013). [16] E. Hecht, “OPTICS,” Addison-Wesley, 4th Edition (2002). [17] G. H. Meeten, “Refractive index errors in the critical-angle and the Brewster-angle methods applied to absorbing and heterogeneous materials,” Meas. Sci. Technol. 8(7), 728 (1997). [18] T. Das and K. Bhattacharya, “Refractive index profilometry using the total internally reflected light field,” Appl. Opt. 56(33), 9241-9246 (2017). [19] J. Rheims, J. Köser and T. Wriedt, “Refractive-index measurements in the near-IR using an Abbe refractometer,” Meas. Sci. Technol. 8(1), 601-605 (1997). [20] R. M. A. Azzam, “Phase shifts that accompany total internal reflection at a dielectric-dielectric interface,” J. Opt. Soc. Am. A, 21(8), 1559-1563 (2004). [21] S. Patskovsky, M. Meunier, and A. V. Kabashin, “Phase-sensitive silicon-based total internal reflection sensor,” Opt. Express 15(19), 12523-12528 (2007). [22] M. H. Chiu, W. C. Chen, and C. T. Tan, “Small displacement measurements based on an angular-deviation amplifier and interferometric phase detection,” Appl. Opt. 54(10), 2885-2890 (2015). [23] J. Y. Lee, T. K. Chou, and H. C. Shih, “Polarization-interferometric surface-plasmon-resonance imaging system,” Opt. Lett. 33(5), 434-436 (2008). [24] Polarized Color Camera BFS-U3-51S5PC-C USB 3.1 Blackfly, https://www.edmundoptics.com/p/bfs-u3-51s5pc-c-usb3-blackflyr-s-polarized-color-camera/41901/ [25] Polymer Zero-Order四分之一波片, https://www.thorlabs.com/newgrouppage9.cfm?objectgroup_id=8635 [26] K. H. Chen, Y. H. Wang, J. H. Chen, and C. H. Lin, “Full-field refractive index measurement using absolute-phase total internal reflection heterodyne interferometry,” Appl. Phys. B 126(1), 109 (2020). [27] K. Creath, “Calibration of numerical aperture effects in interferometric microscope objectives,” Appl. Opt. 28(16), 3333-3338 (1989). [28] 偏振相機光傳感元件說明書(Polarization Image Sensor-Sony IMX250MYR), https://www.sony-Semicon.co.jp/products/common/pdf/IMX250_253MZR_ MYR_Flyer_en.pdf [29] National Instruments Corporation, “LabVIEW Machine Vision and Image Processing Course Manual,” April Edition (2008). [30] 一般稜鏡規格, https://www.edmundoptics.com/c/right-angle-image-reflection-prisms/668/ [31] 高折射率稜鏡規格, https://www.edmundoptics.com/f/n-sf11-right-angle-prisms/12466/ [32] 材料折射率數值資料, https://refractiveindex.info/ [33] 材料折射率數據庫, https://www.filmetrics.com/refractive-index-database [34] 非球面透鏡規格柱狀透鏡規格, https://www.thorlabs.com/navigation.cfm?guide_id=2087 [35] B. S. Lin, M. J. Su, P. H. Cheng, P. J. Tseng, and S. J. Chen, “Temporal and Spatial Denoising of Depth Maps,” Sens. 15(8), 18506-18525 (2015). [36] M. Camplani, T. Mantecón, and L. Salgado, “Depth-Color Fusion Strategy for 3-D Scene Modeling With Kinect,” IEEE Trans. Cybern. 43(6), 1560-1571 (2013). [37] R. J. Moffat, “Describing the uncertainties in experimental results,” Exp. Therm. Fluid Sci. 1(1), 3-17 (1988). [38] H. L. Hsieh, J. Y. Lee, L. Y. Chen, and Y. Yang, “Development of an angular displacement measurement technique through birefringence heterodyne interferometry,” Opt. Express 24(7), 6802-6813 (2016). [39] 偏振片特性, https://www.edmundoptics.com/knowledge-center/application-notes/optics/polarizer-selection-guide/ [40] C. M. Morris, R. V. Aguilar, A. V. Stier, and N. P. Armitage, “Polarization modulation time-domain terahertz polarimetry,” Opt. Express. 20(11), 12303-12317 (2012).
指導教授	李朱育(Ju-Yi Lee)	審核日期	2021-7-19
推文	facebook   plurk   twitter   funp   google   live   udn   HD   myshare   reddit   netvibes   friend   youpush   delicious   baidu
網路書籤	Google bookmarks   del.icio.us   hemidemi   myshare