Laser feedback stress measurement system based on fourier transform phase extraction method

被引：1

作者：

Niu H.-S. ^{[1
]}

Zhu L.-Q. ^{[1
]}

Liu N. ^{[2
]}

机构：

[1] Institute of Instrument Science and Photoelectric Engineering, Beijing Information Science and Technology University, Beijing

[2] Institute of Instrument Science and Photoelectric Engineering, Beihang University, Beijing

来源：

Zhu, Lian-Qing (zhulianqing@sina.com) | 1954年 / Chinese Academy of Sciences卷 / 26期

关键词：

Laser feedback; Phase extraction; Precision measurement; Stress measurement;

D O I：

10.3788/OPE.20182608.1954

中图分类号：

学科分类号：

摘要：

Accurate measurement of the internal stress in high-end glass relates to the safety and reliability of the system in which it is used. This paper proposes a stress measurement method based on the laser feedback effect. The laser feedback system consists of a laser and an external mirror. The sample to be measured is placed in the external cavity of the feedback system, and the polarization flipping of the laser induced by the gain modulation of feedback light is used to extract stress information. First, the relationship between the phase of the orthogonally polarized modes of the laser and the birefringence of the external cavity was theoretically analyzed. Next, the phase information of the orthogonally polarized tuning curve was obtained by Fourier transform. Then, the precision of the system and algorithm was tested using a standard quarter-wave plate. Finally, the laser feedback system was used to measure the internal stress in various aircraft cockpit plexiglass samples and measurement results are given. The experimental results show that the measurement accuracy of the system for fringe number is better than 8.3×10-4, which meets the stress detection requirements of high-end glass. © 2018, Science Press. All right reserved.

引用

页码：1954 / 1959

页数：5

共 15 条

[1] Tomozawa M., Lezzi P.J., Hepburn R.W., Et al., Surface stress relaxation and resulting residual stress in glass fibers: A new mechanical strengthening mechanism of glasses, Journal of Non-Crystalline Solids, 358, 18-19, pp. 2650-2662, (2012)
[2] Findlay S.J., Harrison N.D., Why aircraft fail, Mater. Today, 5, 11, pp. 18-25, (2002)
[3] Norrby S., Imaging quality of intraocular lenses, Journal of Cataract & Refractive Surgery, 32, 4, pp. 545-546, (2006)
[4] Wu Y., Zhang S.L., Li Y., The intra-cavity phase anisotropy and the polarization flipping in HeNe laser, Optics Express, 21, 11, pp. 13684-13690, (2013)
[5] Chupakhin S., Kashaev N., Huber N., Effect of elasto-plastic material behaviour on determination of residual stress profiles using the hole drilling method, The Journal of Strain Analysis for Engineering Design, 51, 8, pp. 572-581, (2016)
[6] Vourna P., Hervoches C., Vrana M., Et al., Correlation of magnetic properties and residual stress distribution monitored by X-ray and neutron diffraction in welded AISI 1008 steel sheets, IEEE Transactions on Magnetics, 51, 1, pp. 1-4, (2015)
[7] Okoro C., Nondestructive measurement of the residual stresses in copper through-silicon vias using synchrotron-based microbeam X-ray diffraction, IEEE Transactions on Electron Devices, 61, 7, pp. 2473-2479, (2014)
[8] Montalto L., Paone N., Rinaldi D., Et al., Inspection of birefringent media by photoelasticity from diffuse light polariscope to laser conoscopic technique, Opt. Eng., 54, 8, (2015)
[9] Tang Y.G., He M., Cui J.C., Et al., Senamont based measuring method for birefringence of infrared crystal, Opt. Precision Eng., 20, 10, pp. 2176-2183, (2012)
[10] Nagib N.N., Bahrawi M.S., Ismail L.Z., Et al., Evaluation of a photometric method for retardance measurement of a quarterwave phase plate, Opt. Laser Technol., 69, pp. 77-79, (2015)

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