數位Moiré運用在光學振動測試分析

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姓名

劉昱銘(Yu-Ming LIU) 查詢紙本館藏

畢業系所

光電科學與工程學系

論文名稱

數位Moiré運用在光學振動測試分析
(Research and Analysis of Digital Moiré Application in Optical Vibration)

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摘要(中)

疊紋光學量測 Moiré 方法具有非接觸、非破壞性、成本較低等特
點，同時利用 Moiré條紋計算分析物體表面振動或尺寸細微變化之方法，
比傳統的數位影像處理的方法速度與檢測效率更快更精準。
現階段的 Moiré都是使用投影機投射光柵，有兩項影響量測品質的
重要因子，(1)因為攝影機取樣頻率與投影機投射頻率不匹配，錄製的
影像就會因為投影機幻燈片的閃爍造成雜訊，讓最後數據分析產生偏
差，(2)投影機與攝影機的夾角並沒有達到適合的角度，使錄製畫面無
法產生 Moiré等高線現象，未達到影像特徵值強調效果。
本研究優化針對以上缺點依實驗進行優化，(1)將攝影機幀數由
30fps 改為與投影機相同的 60fps。(2)擺設位置採光柵側投影，攝影機
正面拍方式。(3)光柵焦距在物體前 0~5cm 處。
結果顯示硬體位置調配的改善過去 Moiré沒有等高線輪廓缺點，另
外用喇叭輸出固定頻率去驗證此系統的精確度；在 7Hz 振動頻率時，
有等高線影像所量測出來的數據，能有效強調待測物之特徵值，優化前
的數據在 7Hz 處強度只有在 7.5，並且有 0.6Hz 和 8Hz 的相對值誤差，
而優化後的數據顯示 7Hz 處有明顯的波峰，強度甚至快到 17 左右，相
當於過去系統的兩倍以上，雜訊減少且整體訊號強度從低於 2 明顯增
ii
加到高於 4，真正達到 Moiré強化影像之效果，成為量測震動的可靠工
具之一。

摘要(英)

Moiré optical measurement is non-contact, non-destructive, low cost,
etc. At the same time, the method of using Moiré fringes to calculate and
analyze the surface vibration or subtle changes in object size is faster and
more efficient than traditional digital image processing methods.
At this stage, digital Moiré uses projectors to project gratings. There
are two important factors that affect the measurement quality. (1) Because
the sampling frequency of the camera does not match the projection
frequency of the projector, the recorded image will be affected by the
projector slide. Light flicker causes noise, which cause the result to have
image bias during the final data analysis. (2) The angle between the projector
and the camera does not reach a suitable angle, so that the Moiré contour line
phenomenon cannot be generated in the recording image, diminishing the
image feature value emphasis effect.
The optimization of this study is based on the experiments according
to the above shortcomings. (1) The frame rate of the camera is changed from
30fps to 60fps, which is the same as the projector’s fps. (2) The installation
position adopts the grating side projection, and the camera shoots from the
front. (3) The focal length of the grating is 0~5cm in front of the object.
The results show that the hardware position adjustment has been improved.
In the past, the digital Moiré did not have the shortcomings of contour lines.
In addition, the speaker output fixed frequency to verify the accuracy of the
system. At 7Hz vibration frequency, the data measured by the contour image
iv
can effectively emphasize the waiting period. For the characteristic value of
the measured object, the intensity of the data before optimization is only 7.5
at 7 Hz, and there is a relative value error of 0.6 Hz and 8 Hz. While the
optimized data shows that there is a clear peak at 7 Hz, and the intensity
increased to 17 Hz, which is quite More than twice the size of the previous
system. The noise is reduced and the overall signal strength is significantly
increased from less than 2 to more than 4, which truly achieves the effect of
Moiré′s enhanced image and becomes one of the reliable tools for measuring
vibration.

關鍵字(中)

★ 疊紋
★ 頻率
★ 強化影像
★ 等高線輪廓
★ 攝影機幀數
★ 非接觸

關鍵字(英)

★ Moiré
★ frequency
★ enhanced image
★ project gratings
★ The frame rate of the camera
★ non-contact

論文目次

摘要 ………………………………………………………………………...i
Abstract…..……………………………………………………………….iii
誌謝……….………………………………………………………………. v
目錄 ………………………………………………………………………..vi
圖目 ………………………………………………………………………..ix
表 ………………………………………………………………………..xii
第一章序論 1
1-1 研究背景 1
1-2 文獻回顧 2
1-3 研究目的 4
1-4 本論文之貢獻 5
1-5 研究方法 8
1-5-1 實驗一:Moiré架設 8
1-5-2 實驗二:喇叭振動測試 8
1-6 論文架構 9
第二章研究原理 10
2-1 Moiré疊紋之起源和概念 10
2-2 疊紋干涉近似表示法 11
2-3 陰影疊紋法 13
2-4 疊紋表面與位移量測原理 16
2-5 疊紋簡化法 18
2-6 傅立葉轉換 19
2-7 疊紋數位影像處理 21
第三章研究設備與軟體介紹 22
3-1 系統架構 22
3-2 軟/硬體設備介紹 22
3-2-1 投影機規格 23
3-2-2 攝影機規格 24
3-2-3 Matlab 26
3-3 光柵 28
3-4 體感振動器 29
第四章實驗與結果分析 30
4-1 實驗設計 30
4-2 實驗總流程 31
4-3 實驗一流程與結果 32
4-4 實驗二流程與結果 39
4-4-1 操作前置作業流程 39
4-4-2 實驗二後端影像處理流程 39
4-4-3 後端影像分析流程 42
4-4-4 實驗結果 43
4-5 實驗結論 45
第五章結論與未來展望 46
5-1 研究結論 46
5-2 未來展望 47
參考文獻 ………………………………………………………………48
附件:預投稿論文 50

參考文獻

[1] J. Guild, “The Interference System of Crossed Diffraction Gratings: Theory of Moirè Fringes,” Oxford at the Clarendon Press, 1956.
[2] B. Han, and D. Post, “Moiré interferometry for engineering mechanics: current practices and future developments,” The Journal of Strain Analysis for Engineering Design, Vol.36. p.101-117, (2001)
[3] Lord Rayleigh, “On the manufacture and theory of diffraction grating,” Phil. Mag. Series4, pp. 81-93, 1874.
[4] Daniel Post, Bongtae Han, and Peter G. Ifju, “Moiré Methods for Engineering and Science - Moiré Interferometry and Shadow Moiré,” Topics in Applied Physics, Volume 77, p.151, 2000.
[5] R. Weller and B.M. Shepard, “Displacement Measurements by Mechanical Interferometry,” Proc. SESA, 6(1), p35-38, 1948.
[6] H. Takasaki, “Moiré Topography,” Applied Optics, Vol.9, No.6, pp.1467~1472, 1970.
[7] R. P. Khetan, “Theory and Applications of Projection Moiré Method,” State University of New York at Stony Brook, Ph.D. Dissertation, 1975.
[8] M. Ldesawa, T. Yatagai, and T. Sorma, “Scanning Moiré Method and Automatic Measurement of 3-D Shapes,” Applied Optics, Vol.16, No.8, pp.2125 -2162, 1977.
[9] J. E.A. Liao, and A.S. Voloshin, “Enhancement of the Shadow-Moiré Method Through Digital Image Processing,” Experimental Mechanics, Volume33, p59-63, 1993.
[10] Inokuchi Y, et al. “Evaluation of Facial Palsy by Moiré Topography,” Proc SPIE, 1429, p.258-265, 1995.
[11] Ivnitsky A, and Voloshin A. “Measurement of the Face’s Topography by Digitally Digitally Enhanced Shadow Moiré,” Proc SPIE, 1395 p.1043-1049, 1996.
[12] F. P. Chiang, “Moiré Methods of Strain Analysis,” Experimental Mechanics, pp. 290~308, 1979.
[13] Voloshin, A. S., Burger, C. P., Rowlands, R.E., “Composites Analysis, by Fractional Moiré Fringe System,” J.Comp. Mat. 19, p513-524,1985.
[14] Katherine Creath, “Phase-shifting speckle interferometry,” Applied Optics, Vol.24, No.18, September 1985.
[15] J. L. Sullivan, “Phase—Stepped Fractional Moiré,” Experimental Mechanics, Volume31, p373- 381, 1991.
[16] Otsu, N. (1979). “A Threshold Selection Method from Gray- Level Histograms,” IEEE Transactions on Systems, Man, and Cybernetics, 9(1), 62–66.
[17] J. N. Kapur, P. K. Sahoo, and A. K. C. Wong, “A new method for gray-level picture thresholding using the entropy of the histogram,” Graph. Models Image Process. 29, 273–285 ~1985.
[18] T. W. Ridler and S. Calvard, “Picture thresholding using an iterative selection method,” IEEE Trans. Syst. Man Cybern. SMC-8, 630–632 ~1978.
[19] N. E. Huang, Z. Shen, S. R. Long, M. C. Wu, H. H. Shih, Q. Zheng, N. C. Yen, C. C. Tung, and H. H. Liu, “The empirical mode decomposition and the Hilbert spectrum for nonlinear and non-stationary time series analysis,” Proc. R. Soc. Lond. A, Math. Phys. Sci., vol. 454, pp. 903-995, 1998.
[20] Alex Krizhevsky, Ilya Sutskever, and Geoffrey E. Hinton, “ImageNet classification with deep convolutional neural networks,” in NIPS, 2012.
[21] C.Lu and S.Inokuchi, “Intensity-Modulated Moire Topography,” Applied Optics,Vol.38,No19,pp.4019~4029,1999
[22] P.S.Huang, F.Jin, and F.P.Chiang, “Quantitative Evaluation of Corrosion by A Digital Fringe Projection Technique,” Optics and Lasers in Engineering,Vol.31,pp.371-380,1999
[23] Y. LeCun, Y. Bengio, and G. Hinton. “Deep learning,” Nature 521, 436–444, 2015.
[24] Alan V. Oppenheim and Ronald W. Schafer: Discrete-Time Signal Processing, Prentice Hall Signal Processing Series
[25] Boaz Porat: A Course in Digital Signal Processing, pp. 27-29, pp. 104-105, John Wiley and Sons
[26] Sophocles J. Orfanidis: Introduction to Signal Processing, Prentice Hall International

指導教授

張榮森(Chang Rong Seng)

審核日期

2022-7-21

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