相位锁定循环投影技术及其应用

由一组规则栅线投影到物体表面的变形光栅,采用相位锁定循环解调算法解调出含有物体表面高度信息的相位.该技术的最大优势是不需传统的相位去包裹.利用该算法对二维栅线图扫描确定的相位.本文给出了一个典型试件的实验结果和分析.     

数字散斑干涉术和时空三维相位解包裹用于非连续表面动态变形测量（英文）

为解决传统相位解包裹法不能够用于非连续表面的动态变形测量的缺点,在详细阐述基于时空三维相位解包裹技术的数字散斑干涉术的工作原理和测量步骤基础上,应用数字散斑干涉术和时空三维相位解包裹测量非连续表面动态变形.实验证明,当采用每秒70帧的普通相机拍照时,可实现最快形变速率为25.12μm/s的非连续表面动态变形测量.本文所提方法扩展了数字散斑干涉术的测量范围,增强其应用能力.     

基于混合粒子群优化算法的ZnO镀膜光纤传感器的相位偏移

建立了氧化锌镀膜光纤传感器中传输光相位偏移的优化模型,采用混合粒子群优化算法对该模型进行优化。仿真结果表明,利用该算法可得到传输光相位偏移量的优化值。分析了光纤传感器相关参数对传输光相位偏移的影响;比较了优化后相位偏移的理论值与实验值,发现二者基本一致。     

水中微小波纹圆柱体声散射低频共振调控

塑料类高分子材料甲基丙烯酸甲酯-亚克力(PMMA)圆柱中亚音速Rayleigh波低频隧穿共振可引起反向散射增强,在低频标准散射体设计等领域具有重要应用价值.提出一种微弱形变的规则波纹表面结构,可实现水中PMMA圆柱反向散射低频共振频率的无源调控.利用微扰法推导了水中微弱形变规则波纹圆柱反向散射低频共振频率偏移的近似解,讨论了波纹微扰系数、周期对规则波纹圆柱共振频率偏移的影响规律.基于Rayleigh波相位匹配方法分析了低频共振频率偏移的机理.研究表明:微弱形变规则波纹圆柱中亚音速Rayleigh波沿微弱形变波纹表面传播,与光滑圆柱体相比,传播路径的改变引起Rayleigh波传播相位变化,导致了Rayleigh波低频共振频率发生偏移.最后开展了微弱形变规则波纹圆柱体声散射特性水池实验,获取了其反向散射共振频率,明显观察到了规则波纹圆柱共振频率偏移现象,与理论预报结果吻合较好.     

MEMS微变形镜测试技术及算法研究

介绍了基于计算机控制的频闪显微干涉测量技术,实现了对MEMS微变形镜的表面形貌、离面变形、静态电压-位移曲线和谐振频率的测量。采用频闪成像、计算机微视觉技术以及基于最小二乘曲面拟合法的亚像素定位技术实现了对平面内微位移的测量;利用频闪成像以及5步相移干涉技术实现了对干涉相位的提取,建立了适合于MEMS微变形镜特性测试的相位解缠算法,恢复了代表被测物体表面形貌的真实相位,实现了微变形镜静动态特性的测试。测试结果表明:频闪显微相移干涉测量技术具有测量速度快、精度高、易实现自动控制等特点。     

彩色栅线动态三维测量中自适应相关匹配技术

彩色栅线结构光三维测量可仅靠左右摄像机单幅图像完成像素级相位匹配,能够实现运动或者变形物体型面重构,但其测量精度有待进一步提高.在依据相位进行粗匹配的基础上,采用立体视觉数字相关技术在左右图像局部区域进行更细致的匹配.计算相关系数时,依据彩色栅线各个周期的色彩变化特性白适应调整不同颜色通道的权重,依据不同视点表面变形特性自适应调整左右相关窗口的尺寸.在极线方向上双线性插值进行亚像素匹配.实验结果证明自适应数字相关匹配技术在保证彩色栅线动态检测,分辨率高优点的同时,可有效改善测量精度至0.1 mm,扩大测量适用范围.     

基于结构光的光线追迹与波前重建方法

提出一种基于结构光条纹成像的光线追迹和波前重建方法.以结构光条纹相位为信息载体,采用相移技术精确地测量结构光条纹成像过程中相位的变化,实现高分辨的光线追迹,得到点列图.由于光线传播方向与波前垂直,凶此可以实现波前重建.将一个液晶显示器(LCD)置于点光源后,显示正弦灰度调制光栅图样以产生标准条纹光束.条纹光束通过被测光学元件后,发生变形.CCD记录下变形条纹图样,根据相移技术进行处理,计算后完成测量.由于调制光栅图样是由计算机产生的,所以光栅的周期和方向可以灵活设置,并可以实现精确的相移.实验验证了该方法的可行性.     

涡旋光束与相位全息光栅不对准时的衍射特性研究

研究了涡旋光束与相位全息光栅不对准时衍射光束的解析特性.利用理论推导的方法得出涡旋光束经相位全息光栅接收后一阶衍射光束的解析表达式.然后通过仿真分析分别得出在发生正常对准、横向偏移、角向倾斜及横向偏移和角向倾斜两者同时出现时衍射光束的质心偏移特性和中心强度变化特性.研究表明: 拉盖尔-高斯光束经相位全息光栅衍射后得到的光场表达式为合流超几何函数形式.光束与相位全息光栅间的不对准会引起衍射光束质心的偏移,而且光束质心的偏移量随入射光束偏移距离和偏离角的增加而增加,与入射光束的偏移方向和方位角无关.角向倾斜时 关键词： 拉盖尔-高斯光束 相位全息光栅 横向偏移 角向倾斜     

基于瞬态光栅频率分辨光学开关装置的阿秒延时相位控制

操控多路激光脉冲之间的相对延时（相对相位）对于亚周期相干合成技术意义重大.当周期量级脉冲之间的相对延时接近数十飞秒时,常见的飞秒脉冲测量手段已无法满足脉冲之间相对相位的精确调控需求.本文基于瞬态光栅频率分辨光学开关装置,精确反演出脉冲之间的相对相位.此方案不仅有助于直接产生亚周期（亚飞秒）脉冲,还可应用于时间隐身学和二维相干光谱学等相关领域.     

基于相位偏移干涉术的薄膜厚度测量方法

为解决薄膜厚度的高精度测量问题,提出一种基于相位偏移干涉术的薄膜厚度测量新方法,利用该方法对一个实际SiO₂薄膜样片进行测试,通过对所获取的干涉图进行相位解包及数据分析处理,实现对薄膜样片厚度的精确测试。结果表明：该方法具有非接触和测量精度高等优点,所测薄膜厚度的峰谷值为0.162μm,均方根值为0.043μm,为薄膜工艺的进一步研究提供了检测方法上的技术保障。     

数字三色条纹相移形貌投影栅线法

基于投影栅线的三色条纹相移算法与投影栅线法相结合,提出一种数字三色条纹相移形貌投影栅线法.此法是对时间相移法的改进,只需一幅三色条纹图,就可利用简单的三光强相移算法完成物体表面的形貌重建;不需要相移装置而误差较小,成本较低,简易实用,将有利于推广到动态实时分析.实验证明,此法是正确可行的.     

Novel quantitative non-destructive testing method for composite structures

A novel QNDT (quantitative non-destructive testing) method is developed that is combined with a phase-shifting shearing speckle and thermograph, and, it aims at the detection of faults such as cracks, voids, delamination and weak areas. The technique is immune to ambient noise and is suitable for measuring the in situ environment. Some different depth defects that would produce deformation differing from other positions could be found with shearing speckle when the sample is loaded, however, a thermograph based on the thermal resistance effect of a defect can detect only those varisized defects embedded deeply in the composite structure by measuring the surface temperature distribution. The resolution is examined for artificial delaminated defects in carbon-fiber composite structures using a phase-shifting shearing speckle and thermograph. The experimental results have demonstrated that the technique is effective for revealing defects in composite structures.     

Surface contouring by phase-shifting real-time holography using photorefractive sillenite crystals

This work proposes to obtain surface contouring by phase-shifting real-time holography using photorefractive sillenite crystals which provides the surface contouring from a change in phase of wavefront of the object illumination beam. The real-time holography using the photorefractive Bi₁₂SiO₂₀ crystal and the four-frame phase-shifting technique was used to obtain the phase map, this map was filtered by an anisotropic sin/cos filter and the unwrapping process used was the cellular-automata technique. We obtained experimental results of the surfaces of the large objects with real discontinuities, and these results agree with the dimensions of the object.     

Quantitative detection and compensation of phase-shifting error in two-step phase-shifting digital holography

Phase-shifting digital holographic technique is a powerful tool for the measurement of various physical parameters, such as object deformation and liquid or cell’s refractive index change. However, for an accurate measurement, phase-shifting error in the reference wave path is still a major issue. In this paper, three novel and simple algorithms are proposed to quantitatively detect and correct phase-shifting error for a pure phase object in two-step phase-shifting digital holography. Influence of phase-shifting error is illustrated, and the effectiveness of the proposed algorithms is demonstrated by numerical simulation results.     

Microscopic surface contouring by fringe projection method

This paper describes the use of optical fringe projection method for 3D surface profile and deformation measurement of micro-components. In this method, sinusoidal linear fringes are projected on a micro-component surface by a grating phase shifting projector and a long working distance microscope (LWDM). The image of the fringe pattern is captured by a high-resolution CCD camera and another LWDM and processed by phase-shifting technique. A simple procedure is described which enables calibration of the optical set-up for subsequent quantitative measurement of micro-components of unknown shapes. This method is relatively simple and accurate, and is capable of conducting fully automated measurements. In this paper, two micro-components, a micro-mirror (0.1 mm×0.1 mm) and a micro-electrode pad are used to demonstrate deformation measurement and microscopic surface contouring.     

基于PMD的反射镜面检测实验分析

将相位测量偏折术应用于非球面反射镜面形检测,并对实验检测结果的中高频误差进行了分析研究。计算机产生正弦性条纹图,并且显示在薄膜场效应晶体管显示屏上。摄像机通过被测反射镜观察并拍摄显示屏上的条纹图。利用相移技术和相位展开技术计算得到相位分布。以相位信息为载体对光线进行追迹,并根据反射定律得到面形梯度分布,由数值积分重建面形分布。最后使用泽尼克多项式拟合分析了其中高频误差。     

一种机械扫描式精密相移测长方法

以相移干涉测长为应用背景,提出了一种基于“机械扫描”的相移测长方法。利用超高弹性石英材料研制出了干涉测长所需的单体3路相移装置,并利用该相移装置建成了相移测长装置,成功地将位移传感器的量值在线溯源到光学频率标准,从而实现了对3路相移的准确测量。介绍了一种引入步长控制误差的“新五幅相移”实现相位解算方法,算法准确度达到0.01%。对不确定度的定量分析结果表明,基于该机械扫描式相移技术构建的绝对长度测量系统准确度可达0.5 nm。     

Profile measurement of a moving object using an improved projection grating phase-shifting profilometry

3-D profile measurement of a moving object using a novel phase-shifting technique is introduced. Digital gratings with two steps phase-shifting are projected periodically onto a measured object surface. The deformed fringe patterns are captured by a frame CCD camera within a short exposure time. By synchronizing the projector and the CCD camera accurately, there is an overlapping part which is the same part of the object among three neighbouring frames. The length of an overlapping part can be controlled as one third of a frame length. Hence the intensity values at the same surface point modulated by three neighbouring gratings can be obtained, and its phase value can be computed by an improved phase-extracting algorithm. The profile of a specimen is detected by the proposed method. Experimental results demonstrate that this method is effective for the profile measurement of a moving object.     

Spatial-carrier phase-shifting digital holography utilizing spatial frequency analysis for the correction of the phase-shift error

We propose a single-shot digital holography in which the complex amplitude distribution is obtained by spatial-carrier phase-shifting (SCPS) interferometry and the correction of the inherent phase-shift error occurred in this interferometry. The 0th order diffraction wave and the conjugate image are removed by phase-shifting interferometry and Fourier transform technique, respectively. The inherent error is corrected in the spatial frequency domain. The proposed technique does not require an iteration process to remove the unwanted images and has an advantage in the field of view in comparison to a conventional SCPS technique.     

Optical measurement on dynamic buckling behavior of stiffened composite panels under in-plane shear

The buckling behavior and failure mode of a composite panel stiffened by I-shaped stringers under in-plane shear is studied using digital fringe projection profilometry. The basic principles of the dynamic phase-shifting technique, multi-frequency phase-unwrapping technique and inverse-phase technique for nonlinear error compensation are introduced. Multi-frequency fringe projection profilometry was used to monitor and measure the change in the morphology of a discontinuous surface of the stiffened composite panel during in-plane shearing. Meanwhile, the strain history of multiple points on the skin was obtained using strain rosettes. The buckling mode and deflection of the panel at different moments were analyzed and compared with those obtained using the finite element method. The experimental results validated the FEM analysis.