Data fusion of 3D profiles measured by projected fringe profilometry

Hsu, Yi-Ling

08 July 2005

This paper presents a novel integration technique for segmented 3D profiles measured by projected fringe profilometry. Fringe patterns are projected to the inspected surface. The projected patterns fix their positions relative to the tested object during two segmented measurements. Thus, finding two matched surface points becomes a problem of searching for two identical phases in the fused data sets. This novel integration technique can match images successfully and achieve pixel-to-pixel registration easily even in the presence of geometric deformation, illumination changes, and severe occlusions. It is superior to the other methods because of its: (1) High matching accuracy; (2) Improved robustness; (3) Reduced computational time; (4) Capability of compensating distortions of the optical system at every pixel location; (5) Suitable for images rotating or scaling; and (6) Suitable for any other projected fringe measurement method. We also propose a method to design and fabricate a 2-D fringe pattern which can be applied to the integration technique for segmented 3D profiles. Campered with using 1-D fringe patterns for image registration, using a 2-D fringe pattern saves the measurement time and further proveds more tolerence to hand the shadow and noise problems. Tests of the system performance have been carried out that the accuracy of the registration scheme is 5.96% of image pixel size. Therefore, this technique can be extensively used in modern high technology industry. Especially when it requires higher resolution close-up images or overcomes the issue of not every inspected object can be fully expressed just by a single full-field measurement, it is necessary to use this integration technique.

data fusion

image registration

3D profile measurement

2D grating

Coupling between Ultra High-Power Laser Diodes and Fibers

Wang, Kuo-liang

11 July 2005

The width of an ultra high-power laser diode is greater than 50 £gm and more than 20 times of low-power laser diode.The core diameter of Erbium Doped Fiber Amplifier fiber (EDFA) is 4~6 £gm and it is a single-mode fiber (SMF).However¡Athe ultra high-power laser diode is multi-mode laser. Therefore¡Athe mismatch between high-power laser and SMF resulting in low coupling efficiency. We improve coupling efficiency by using a wedge-shaped graded-index fiber (GIF) tip spliced to a SMF then fused a fiber bragg grating (FBG) to form an external cavity laser. The GIF is a focusing action like a graded-index fiber. From near-field pattern (NFP)¡Awe find the best GIF length is 400 £gm. The coupling efficiency between ultra high-power laser diode and wedge-shape lensed fiber is only 5% .

ultra high-power laser

mode conversion

fiber grating

external cavity

Temperature and Polarization Dependence on Holographic Gratings and Its Applications Based on Polymer and Liquid Crystals

Huang, Shuan-Yu

20 July 2005

The study of the first-order diffraction efficiency and the mechanism of formation have been investigated on dye-doped liquid crystals (DDLC) and liquid crystals with azo-dye-doped polymer film. The thesis mainly contains three experimental parts by changing the temperature of sample and the polarizations of writing and probing beams. The first part includes the study of temporal profiles of diffraction efficiency for transient gratings and their temperature and polarization dependence in azo-dye-doped liquid crystals. The dynamics of molecular reorientation of transient gratings can be understood by analyzing the build-up time of the peak efficiency and the relaxation decay of the first-order diffraction. The study of the polarization and temperature dependence allows us to understand the underlying mechanism of laser-induced transient gratings. The second part is concentrated in the diffusion process of photoexcited dye in a planar liquid crystal host. The experiment result reveals that the diffusion coefficient is larger for the molecular director along the grating vector than the perpendicular case and the diffusion will be faster as temperature increases. The third part is focused on the mechanism of formation and the temperature dependence of holographic grating for the liquid crystals with azo-dye-doped polymer film. The temporal profile of the first-order diffraction intensity shows a dip at the temperatures of nematic phase. The dip of the first-order diffraction intensity is temperature dependent and can be explained to be the light scattering due to the photothermal effect. The transient behavior in the dip of transmitted probe beam is also temperature dependent. The surface modulation has been measured by using atomic force microscope (AFM). The depth of surface relief grating of liquid crystals with azo-dye-doped polymer film is deeper than that of azo-dye-doped polymer film and the first-order diffraction efficiency is also larger for the liquid crystals with polymer film.

diffusion

first-order diffraction

liquid crystals

holographic grating

The Design of Fiber Optic Vibration Sensors

Lin, Yung-Li

05 August 2005

Structural born vibration is the most concern issue for industry. Traditionally, the accelerometer is usually used as the major monitoring device for vibration. As the mechanism getting more and more complexity, more compact, tinier and more lighting, the traditional accelerometers are suffered from the loading effect. Its accuracy of measurement is suspected and cannot match the modern measurement requirement. Hence, the studies of fiber optic vibration sensors become an urgent issue in this era. The reflection wavelength of a fiber Bragg grating¡]FBG¡^is sensitive to the variation of the strain and temperature. Our sensor configuration is made of an interferometer and fiber Bragg grating. The vibration induces a strain of the fiber Bragg grating, and it makes a phase difference between those two light beams in the interferometer. A demodulation circuit is needed to detect the phase difference caused by the vibration. In this project, the aim is focused on the vibration measurement for some complicated rotational machines or structures. A fiber optic accelerometer will be designed and studied as a vibration monitor for the other subprojects. In this the thesis, two kinds of vibration sensor head are designed and studied, the first is a bending loss sensor head and the other is an optic fiber Bragg grating sensor head. The results are narrated as follows¡G¡]1¡^ The dynamic range of the bending loss sensing head is about 50 dB.¡]2¡^The dynamic range of the optic fiber Bragg grating sensing head is 38 dB with test frequency range between 100 ~ 400 Hz, the noise level is around 1.95 ¡Ñ 10-2 rad.

Interferometer

Fiber optical Sensors

Vibration Sensors

Fiber Bragg Grating

Projected Fringe Profilometry using Diffractive Elements

Chen, Wei-jen

26 June 2006

A technique using diffractive elements for finding the absolute shape of a large-scale object is proposed. An accurate projected fringe profilometry can be built by applying the holographic technique in this system. The advantages of using the presented technique for projected fringe profilemetry are : (1) a large depth of field ; (2) very low fringe distortion ; (3) a compact design for the measurement system ; (4) high accuracy ; (5) fast measurement speed.

sinusoidal grating

projected fringe

diffractive element

3D profile

hologram

PROJECTED FRINGE PROFILOMETRY USING A SUPERCONTINUUM LIGHT ILLUMINATION FOR MICRO-SCALE MEASUREMENT

Huang, chia-jeng

26 June 2006

Abstract A projected fringe profilomertry ¡]PFP¡^ using a supercontinuum light illumination for micro-scale measurement is proposed. The supercontinuum light is generated by launching ultra short laser into a highly nonlinear photonic crystal fibers. The supercontinuum light with the following advantage¡G ¡]1¡^ Depth of the field is very large in the projected system. ¡]2¡^No speckle noise in the illumination system. Experiment results has shown that using supercontinuum light is superior to other illumination system This study indicates that the proposed measurement scheme could be applied to 3D shape measurements with large depth variation, especially for semi-conductor devices¡Bmicro electro-mechanical devices and biomedical species.

photonic crystal fiber

3D profile

sinusoidal grating

projected fringe

Projected Fringe Profilometry for dynamic micro-scale measurements

Huang, Jun-shan

19 July 2007

A novel technique using projected fringe profilometry with pulsed illuminations for finding the absolute shape of a dynamic object, which is vibrating with high frequency, is proposed. The proposed method can accurately describe the observed 3D shape at a sequence of time. Even though the tested object vibrates up to 10K-Hz, the proposed method can accurately describe the observed 3D shape at any specific time. Depth accuracy better than one part in ten thousandths of the field of view can be achieved even with excessive image noises. Furthermore, the light source is temporally incoherent and spatially coherent, providing a speckle-free and a large depth-of-focus illumination. Thus, a highly accurate, non-scanning projected fringe profilometer with large depth measuring range for dynamic measurements can be realized.

phase

profilometry

fringe

vibration

project

measurement

profile

dynamic

grating

The Study of Laser-Induced Holographic Grating Relaxation in Azo Dye-Doped Liquid Crystal Samples

Tu, Che-Chuan

11 July 2002

In this study, a high power Q-switch pulse laser has been used as the writing beams. The laser-induced holographic gratings in the DR1-doped liquid crystal samples and the DR1-PMMA polymer thin films were investigated by changing the temperature of samples and the angles of two writing beams. The He-Ne cw laser has been used as a real-time probe beam to detect the first order diffraction signals. Without external field, the gratings are the results of concentrations and diffusions of azo dye isomers. The diffusion model has been utilized to analyze the first order diffraction signals in order to understand the mechanics of gratings and the effect of temperature and angle.

diffusion

holographic grating

nematic liquid crystal

azo dye

The Design of Fiber Bragg Grating Vibration Sensors

Chen, Chien-Cheng

14 July 2003

The reflection wavelength of Fiber Bragg Grating is sensitive to the strain and the temperature¡¦s variation. We use Fiber Bragg Grating to be the sensor head and measure the vibration frequency in constant temperature environment. The vibration of object can make the sinusoidal strain to Fiber Bragg Grating, and it will make a little phase difference to the light of the fiber. Using the interferometer and demodulation system, we can measure the phase difference and vibration frequency. Our sensor configuration is made up of imbalance Mach-Zehnder interferometer and Fiber Bragg Grating. The two light of different path need different time to pass through the vibration source, so they make phase difference. We use the demodulation circuit to measure the phase difference causing by vibration and get the vibration frequency. Our experiment structure is a novel configuration of Fiber Bragg Grating vibration sensor. Its intensity of signal is larger than the intensity of original sensor configuration, about 4dB.The novel sensor configuration is easier spread than traditional accelerometer and it is designed of all fiber. The accuracy for measuring low frequency vibration is 99.971%. The Dynamic range of the system is more than 45dB. It is larger than the dynamic range of original sensor configuration, about 9dB. The smallest signal that can be measured is about 0.0075rad.

demodulation

imbalance Mach-Zehnder interferometer

Fiber Bragg Grating

vibration sensor

The Design of the Interferometric Fiber¡VOptic Microphone with FBG

LU, CHIEN-LI

17 July 2003

Abstract The electrical microphone has came to maturity, which has some restrictions on high electromagnetic and wet environments¡CFiber-Optic sensor can improve the problems, because it has better characters in electromagnetic interference and wet environment than the traditional microphone. The structure of Sagnac interferometer is circulator, so the design of head to a sensor has to wind fiber around. Because the minimum radius of winded fiber has a threshold, we can not miniaturize the sensor-head. A typical Mach-Zehnder interferometer has to use high-coherence light source and the length of two arms in equality without any interference, so it is difficult in fabrication. If we make a microphone by FBG and Mach-Zehnder interferometer, and the advantage is that we can use low-coherence light source, and shorten the length of two arms in interferometer. By using the structure, the minimum measured pressure of sound is 0.6 Pa, and the dynamic range is 30dB.

Mach-Zehnder Interferometer

Fiber Bragg Grating

Fiber Sensor