一种用于在线三维测量的五步非等步相移算法

提出了一种五步非等步相移算法,并成功应用于在线三维测量中。仅投影一固定正弦光栅条纹到物体上,通过物体在线运动产生等效相移,在一个条纹周期范围内任意采集五帧变形条纹图,通过像素匹配使各帧条纹图中的物点一一对应并计算出相应的等效相移量。采用所提出的五步非等步相移算法,即可重构物体。计算机模拟与实验验证了该方法的可行性和有效...     

一种改进型Stoilov算法相位测量轮廓术

提出了一种采用主动控制相移量的改进型Stoilov算法,按主动设定的相移量事先设计好五幅完全等相移正弦光栅图,由计算机编程控制数字投影仪依次投影该五幅光栅至待测物体表面,并对应采集五帧变形条纹,用所设定的相移量直接替代Stoilov算法中由变形条纹图解算的相移量,提高了相位提取和三维重构准确度.实验结果表明,平均绝对误差优于0.07,均方差优于0.07.     

一种基于PMP的圆型流水线上工件的三维在线检测方法

提出了一种基于PMP原理的对圆形流水线上工件面形进行在线检测的方法。利用DLP将一环形正弦光栅图投射在圆型流水线上某一区域，使用相移器在物体运动方向的垂直方向上进行相移，实现了圆周运动物体各物点相移一致性，同时由于相移方向与物体移动方向垂直，工件移动不会影响相移量，相移量可以较精确地控制。通过采用参考标记和图像旋转恢复可实现N帧变形条纹图像的像素匹配，从而提取三维物体的截断相位，经过相位展开，得到连续相位，并由相位最后解调出物体的高度信息。通过计算机仿真验证了方法的可行性。该方法具有在线、快速，非接触性等特点。     

一种无需标记的在线三维测量方法

提出了一种无需标记的物体在线三维面形测量方法。将一固定的正弦条纹投影到待测运动物体上,借助物体运动产生等效的相移变形条纹。基于傅里叶变换轮廓术的调制度对各帧变形条纹计算,提取其具有某一特定分布的特征区域,采用相关度最大法,检测各帧变形条纹对应的调制度特征区域的位移量来检测出物体的移动,从而实现像素匹配,得到一组像素坐标完全一一对应的等效相移变形条纹图。利用Stoilov相移算法得到物体的截断相位,利用位相展开算法展开位相,通过位相和高度映射即可实现在线移动物体的面形测量。通过计算机仿真验证了该方法的可行性。     

基于相位预测的在线三维测量像素匹配方法

物体的运动使变形条纹图中物体像素点不对应,因此需要对物体做像素匹配。提出了一种基于相位预测的在线三维测量像素匹配方法。仅投一帧正弦光栅条纹到在线运动的物体上,CCD同步采集相同步距时刻受物体调制的变形条纹图。采用傅里叶变换轮廓术(FTP)方法对采集的变形条纹预测物体不同位置的相位信息,并以该相位信息的特征做像素匹配,实现了物体在各帧条纹图中的像素一一对应,同时匹配后的变形条纹产生等效的等步相移,进而采用等步长相移算法来重构在线运动物体的三维面形。计算机模拟与实验验证了该方法的有效性和可行性。同时,与在线FTP方法进行比较,在线FTP方法和本文方法的均方根误差分别为1.013mm和0.024mm,表明该方法对在线三维测量具有较高的测量精度。     

一种无需滤波的复合光栅投影的在线三维测量方法

针对流水线上在线运动的刚性物体,投影复合光栅可以解决像素匹配和相位展开对条纹频率不同需求的矛盾,但在相位计算时,需对复合光栅进行滤波,该过程会降低重构精度。基于Stoilov算法,提出一种无需滤波的复合光栅投影的在线三维测量方法,设计复合条纹使低频条纹相移方向与被测物体的运动方向平行,像素匹配后被测物体的运动被转化为低频条纹的相移;高频条纹相移方向与被测物体运动方向垂直,像素匹配后各帧变形条纹图中高频条纹的光强分布完全一致,可直接进行相位计算,避开了因滤波造成的精度损失。同时在复合光栅中高频条纹的强度远低于低频条纹,故可将其看作微弱的背景光,保证了在线三维测量的精度。通过仿真与实验验证了该方法的有效性。     

相移阴影莫尔条纹正交化解调技术

提出一种基于克莱姆正则化分析法的三帧自标定相移阴影莫尔三维轮廓技术.该技术首先采用移动光栅的方法获得相移条纹图,然后通过不同帧相移条纹图相减去除条纹图背景,进而结合克莱姆正交化法和最小二乘法,发展了一种相位解调方法,提取了测量相位.以五步Harlharan算法为参考,用不同算法对同一物体表面进行测量.结果表明,相对于典型的三步相移法和主量分析方法,提出的方法测量得到的相位误差最小(0.5rad),且简化了测量过程.     

基于SURF算法的在线三维测量方法

提出了一种采用加速鲁棒特征算法匹配运动物体的特征点,实现在线三维测量的方法.该方法只需投影一固定的正弦光栅到在线运动中的被测物体表面上,使投影光栅线垂直运动方向,当物体每移动相同的距离,由CCD采集到相应的变形条纹图,从中提出对应的背景光场,借助SURF算法对各帧背景光场的物体进行特征匹配,即可获得一组具有等步相移量的等效相移条纹图,从而采用等步相移算法可重构出在线运动物体的三维面形.实验验证了该方法的有效性和可行性,并与在线FTP方法进行了比较,所提方法的平均绝对误差小于在线FTP方法的二分之一,均方根误差小于在线FTP方法的四分之一.     

一种快速获取物体三维形貌和纹理信息的算法

提出了一种新的快速获取物体三维形貌和纹理信息的方法。利用数字投影仪将2幅彩色编码的正弦相移光栅图投影到被测物体表面,彩色相机捕捉经物体调制后的变形条纹图。提取RGB三基色,可获得包含物体高度信息及纹理信息的条纹图和背景光。对包含物体高度信息的条纹图用改进的2+1相移算法重构物体的三维形貌。物体纹理信息则通过对背景光进行彩色编码获得,利用纹理映射技术恢复物体纹理。计算机模拟和实验结果验证了该方法的有效性和可行性。     

基于调制度层析的在线三维测量方法

调制度反映相位展开可靠性的程度,与物体本身灰度和形状有着紧密的关系,因此可作为测量的特征标记。提出了一种采用调制度层析实现在线三维测量的方法。通过投影一固定的正弦条纹到待测运动物体上,借助物体运动可产生等效的相移变形条纹。利用基于傅里叶变换轮廓术调制度模型计算各帧等效的相移变形条纹的调制度,并采用层析方法从各帧调制度分离出反映待测物体的调制度层析特征,以该层析信息作为特征模板,实现像素匹配,从而获取各帧具有一致像素坐标的等效相移变形条纹,实现在线移动物体的三维面形测量。实验证明了该方法的可行性和实用性。     

A three dimensional on-line measurement method based on five unequal steps phase shifting

A three-dimensional on-line measurement method based on five unequal steps phase-shifting with phase measuring profilometry is presented. While only one sinusoidal grating pattern is projected onto the measured object moving with the pipe-line, five arbitrary deformed patterns are captured by CCD as the measured object moves within a duty cycle of the grating pattern. The modulation distribution based on Fourier transform profilometry is introduced to realize pixel matching so as to calculate the corresponding equivalent shifted phase on the deformed patterns. A five unequal steps phase shifting algorithm is developed, which is suitable for non-uniform motion of the pipeline. The experiments verify its feasibility and validity.     

A composite-structured-light 3D measurement method based on fringe parameter calibration

This paper proposes a novel method for reducing measurement error caused by spectrum overlapping in composite-structured-light 3D measurement systems. For a composite-structured-light 3D measurement system, spectrum overlapping causes parameters of each deformed phase-shifting fringe to change, and therefore leads to phase measurement errors. The proposed fringe parameter calibration method is based on the fact that variations in each deformed fringe's parameters are independent of height and reflectivity of the measured object. Three frames of composite grating are projected on the reference plane, and each carrier channel includes the information of three phase-shifting sinusoidal gratings used in Phase Measuring Profilometry (PMP). With the parameter calculation formulas of PMP, the parameters of fringes demodulated from the same carrier channel can be calculated, and therefore parameter relation coefficients between fringes demodulated from different carrier channels may be obtained. When an object is measured, these relation coefficients can be used to calibrate the parameters of the deformed phase-shifting fringes. A new 3D measurement mathematical model is established to reconstruct the shape of the object. Experimental data proved that the proposed method can effectively restrain the effect of spectrum overlapping and improve measurement accuracy by more than three times.     

Shifted-phase calibration for a 3-D shape measurement system based on orthogonal composite grating projection

This paper proposes a novel method for reducing measurement error caused by spectrum overlapping in orthogonal-composite-grating-based 3-D measurement method. For 3-D measurement systems based on orthogonal composite grating projection, spectrum overlapping causes phase of each deformed phase-shifting fringe changed differently, which violates the principle that the shifted phases between adjacent deformed fringes must be equivalent to 2π/3, and therefore results in phase measurement error. The proposed shifted-phase calibration method is based on that phase variation of each deformed fringe is independent of height and reflectivity of the measured object. Three composite gratings are projected on the reference plane, and each carrier channel includes three phase-shifting gratings needed in phase measuring profilometry (PMP). Because the adjacent phase-shifting fringes demodulated from the same carrier channel have the phase difference of 2π/3, we can respectively calculate the reference plane's phases of three carrier channels by the phase algorithm of PMP method, and the shifted phases between them are obtained. When an object is measured, the shifted phases between deformed phase-shifting fringes can be calibrated. A new 3-D measurement mathematical model is set to reconstruct object. Our experiments prove that the proposed method can effectively restrain the effect of spectrum overlapping and improve measurement accuracy almost one times.     

On-line phase measuring profilometry based on phase matching

On-line phase measuring profilometry based on phase matching is proposed. While just one fixed sinusoidal fringe is projected on a measured object moving with the pipeline, deformed patterns modulated by the object moving at the same distance moment are captured synchronously by the CCD camera. The phase information of the object in those captured deformed patterns can be predicted using FTP method to assist the pixel matching so as to realize the point-to-point correspondence of the object in the captured deformed patterns. Meanwhile, the equivalent phase-shifting deformed patterns can be extracted. So the three dimensional shape of the object can be reconstructed successfully with an equal phase-shifting algorithm. Numerical simulation and experiments show feasibility and validity of the proposed method.     

A new pixel matching method using the entire modulation of the measured object in online PMP

A method using entire modulation information of the measured object itself for pixel matching is proposed in online phase measuring profilometry (PMP). Only one fixed sinusoidal grating is projected onto the moving measured object and then five deformed patterns are captured by the imaging system (CCD). Because the contrast of the sinusoidal grating is a constant, the modulation distribution of each deformed pattern reflecting the gray of the measured region can be extracted. The entire modulation of the object cut from one of them is regarded as a template, and then the distance of the measured object's movement between each two adjacent deformed pattern can be calculated by the correlation operation so that we can cut the corresponding parts containing the measured object's information from five deformed patterns. Then the discrete phase can be calculated with Stoilov algorithm. By the phase unwrapping and the mapping algorithm, the object can be reconstructed exactly. A series of simulations and experiments confirm its feasibility and validity.     

Surface profile measurement of moving objects by using an improved π phase-shifting Fourier transform profilometry

The π phase-shifting Fourier transform technique is introduced into the surface profile measurement of moving objects. A digital grating comprising two regions, which have a π phase shifting is projected onto the object. Two line-scan CCD cameras are used to capture two deformed fringe patterns with π phase shifting at the same time. As the object is moving, each point at the object surface can be captured twice. The digital correlation method is used to calibrate the experimental system. The zero-order component can be eliminated by subtracting intensities of the same surface point in two captured images. And then the phase can be extracted by Fourier transform without the disturbance of zero-order component. Experimental results demonstrate that this method is feasible for the moving surface profile detection and the measurable slope of height variation can be extended.     

A novel 3D measuring method for discontinuous object by non-integral twin-frequency grating

A new 3D shape measurement method based on non-integral twin-frequency grating projection is proposed. In this paper, the projected composite grating is composed of two sinusoidal gratings, and the quotient of whose frequencies is not an integer. By using appropriate phase-shifting algorithms, two wrapped phases can be obtained from sixteen frames of the distorted grating patterns. In aid of appropriate phase unwrapping method, the unwrapped phase of high frequency fringe is obtained only from the relation of the two wrapped phases by a pixel-to-pixel phase unwrapping technique. Therefore the unwrapped phase of high frequency fringe pattern is independent of the low frequency fringe pattern, different from traditional integral twin-frequency grating projection methods in which the phase unwrapping error of low frequency fringe pattern may be propagated onto the unwrapped phase of high frequency fringe pattern. The new theory proves that the proposed method is applicable to measure discontinuous object, and has considerable measurement accuracy.