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。     

基于二值化调制度层析的快速在线三维测量算法

提出了一种基于二值化调制度层析的快速在线三维测量算法.对物体调制度信息进行层析分析,有效提取反映物体形状特征的层析信息,并将该双准确度层析信息进行二值化,以该二值化层析信息为模板,进行像素匹配,可实现快速在线三维测量.为验证该算法的可行性和有效性,进行了实物测试实验,该算法与提取调制度特征区域实现像素匹配的方法进行对比测试.实验表明,该算法具有很好的测量准确度,有效地调高了测量速度.     

基于二值化调制度层析的快速在线三维测量算法

提出了一种基于二值化调制度层析的快速在线三维测量算法.对物体调制度信息进行层析分析,有效提取反映物体形状特征的层析信息,并将该双准确度层析信息进行二值化,以该二值化层析信息为模板,进行像素匹配,可实现快速在线三维测量.为验证该算法的可行性和有效性,进行了实物测试实验,该算法与提取调制度特征区域实现像素匹配的方法进行对比测试.实验表明,该算法具有很好的测量准确度,有效地调高了测量速度.     

一种新的叠栅层析迭代算法

利用叠栅层析具有的测量动态范围大,对震动环境不敏感的特点,从其偏折原理的本质出发,提出一种利用代数迭代法来重建三维流场的叠栅层析重建算法。在此基础上进行了双峰函数的模拟实验,分别进行了6方向,12方向以及叠加高斯噪声的12方向的数值重建,并在相同条件下与滤波反投影方法和对偏折投影数据积分的代数迭代算法这两种已有的叠栅层析重建算法进行了比较,同时用该新算法结合属性矩阵对包含遮挡物的模拟场进行重建。对比重建结果,本算法具有较强的抗噪声能力,并且对非完全数据下的层析重建也有较好的处理效果。     

光学相干层析成像的图像重建

层析成像技术－光学相干层析术是基于光学低相干反射测量发展而来的。介绍了用图像恢复的基本原理在光学相干层析术图像增强方面的工作。通过实验测量行到了解卷积所必需的点扩展函数。重建后的膜层结构图像的深度分辨率提高了一个数量级,图像也取得了了的锐化、去噪的效果。     

使用叠栅层析技术测量超音速风洞中的非对称复杂密度场

使用叠栅层析技术解决超音速风洞中复杂密度场的测量难题。应用高灵敏度叠栅偏折仪和间隔角度旋转模型的方法获取超音速风洞中流场的多方向叠栅条纹图。层析计算中使用一种新的偏折角修正迭代的叠栅层析算法,该方法可以实现对有限角采样和包含遮挡物的非完全数据重建,迭代过程中结合内边界平滑滤波提高重建精度。实验中获取了马赫数为2.52的超音速风洞中9幅不同采样角的条纹图,经过50次迭代计算后重建出膨胀波区非对称密度场的截面分布,并对测量结果和误差进行了分析和讨论。使用计算流体力学技术对该密度场进行建模和计算,验证了叠栅层析重建结果的正确性,证实了该技术在测量复杂流场领域的重要价值。     

X射线衍射层析术图像重构的若干影响因素研究

三维X射线衍射层析术(3DXRD)是一种快速的、无损的结构表征技术,用于研究毫米尺度的多晶样品中晶粒(亚晶粒)的空间分布。基于上海光源成像线站BL13W1建立了三维X射线衍射层析术实验方法,并对图像重构中的若干影响因素进行了研究。通过椒盐噪声消除、对比度增强,有效提高了寻峰精度;利用德拜-谢勒环粗校与优值方程循环迭代细校相结合的方法,实现了衍射数据的精确校准,进一步采用并行运算,校准效率提高了4.5倍。实验结果表明,该方法可同时实现近场和远场衍射信息探测,从而获取样品中晶粒的尺寸、质心位置、晶体学取向等信息,并能够给出晶粒形变程度的定量信息。     

一种大视场相位测量轮廓术系统标定方法

在进行大视场相位测量轮廓术系统参量标定时需要大的标定平面和精密移动台,由于携带不方便,不易进行现场标定。提出了一种用于相位测量轮廓术系统参量的高精度、现场标定方法,采用一块较小的平面标定靶在有效测量体积内不同位置多次摆放,以获取密集的数据点。先标定出摄像机的内参量和外参量,再指定一个全局参考平面和若干辅助参考平面,然后在图像平面上分区计算出每个位置标定靶上每点相对辅助参考平面的高度差和相位差,最后应用极大似然估计法估计出相位高度映射参量。实验中平面高度测量的标准偏差达到0.0433 mm。这种方法只需要较小的平面标定靶,标定过程方便、精度高,完全适合大视场三维测量相位测量轮廓术系统现场标定要求。     

硅V型槽表面形貌的OCT可视化测量

介绍了一种硅V型槽表面形貌测量的可视化方法,分析了谱域OCT的测量原理。利用谱域OCT实验测量系统进行了硅V型槽的成像实验,得到了硅V型槽的二维层析图像;通过分析二维层析图像,获取了硅V型槽的结构尺寸,实现了硅V型槽表面形貌的高精度可视化测量。     

光学相干层析图像层状结构的增强与定量测量

光学相干层析(OCT)成像技术对于眼底等层状组织的定量测量有赖于光学相干层析图像中层状结构的提取。为了对原始光学相干层析图像进行预处理以有效地去除图像中的噪声及散斑、增强图中的层状结构,并更好地保护图像中的层状结构,进而更准确地定量测量图像中有重要意义的层状结构的光程信息,提出在相干增强各向异性扩散(CED)算法中引入二阶导数项以控制沿相干方向的扩散强度,并将引入二阶导数项的相干增强各向异性扩散算法应用于不同样品的光学相干层析图像。结合在预处理后图像中层状结构位置的查找结果与样品的折射率信息,实现了对光学相干层析图像中有重要意义的层状结构厚度的定量测量。实验结果表明,使用引入二阶导数项的相干增强各向异性扩散算法对光学相干层析图像预处理有利于对图中重要层状结构的更准确测量。     

Superresolution ultrasound imaging using back-projected reconstruction

An ultrasound technique for imaging objects significantly smaller than the source wavelength is investigated. Signals from a focused beam are recorded over an image plane in the acoustic farfield and backprojected in the wave-vector domain to the focal plane. A superresolution image recovery method is then used to analyze the Fourier spatial frequency spectrum of the signal in an attempt to deduce the location and size of objects in this plane. The physical foundation for the method is rooted in the fact that high spatial frequencies introduced by the object in fact affect the lower (nonevanescent) spatial frequencies of the overall signal. The technique achieves this by using a priori measurements of the ultrasound focus in water, which gives full spectral information about the image source. A guess is then made regarding the size and location of the object that distorted the field, and this is convolved with the a priori measurement, thus creating a candidate image. A large number of candidates are generated and the one whose spectrum best matches the uncorrected image is accepted. The method is demonstrated using 0.34- and 0.60-mm wires with a focused 1.05-MHz ultrasound signal and then a human hair (approximately 0.03 mm) with a 4.7-MHz signal.     

Matched field processing with data-derived modes

The authors demonstrate MFP using data-derived modes and the sound speed profile, using no a priori bottom information. Mode shapes can be estimated directly from vertical line array data, without a priori knowledge of the environment and without using numerical wave field models. However, it is difficult to make much headway with data-derived modes alone, without wave numbers, since only a few modes at a few frequencies may be captured, and only at depths sampled by the array. Using a measured sound speed profile, the authors derive self-consistent, complete sets of modes, wave numbers, and bottom parameters from data-derived modes. Bottom parameters enable modes to be calculated at all frequencies, not just those at which modes were derived from data. This process is demonstrated on SWellEx-96 experiment data. Modes, wave numbers, and bottom parameters are derived from one track and MFP based on this information is demonstrated on another track.     

复谱频域OCT成像的研究

采用频域技术的OCT系统，深度扫描信息由背向散射光谱的傅立叶反变换获得，简化了轴向扫描过程，从而使快速OCT成像成为可能．为了实现复杂生物组织的OCT快速成像，消除谱频域OCT的“混叠”现象、重建样品的真实层析结构，本文引入了相移干涉技术，构建了一套满量程复谱频域OCT实验系统，并为系统设计了特殊的分束镜和移相器，为最终实现复杂生物组织的OCT快速成像提供了条件．     

Spectroscopic spectral-domain optical coherence microscopy

The spectroscopic content within optical coherence tomography (OCT) data can provide a wealth of information. Spectroscopic OCT methods are frequently limited by time-frequency trade-offs that limit high spectral and spatial resolution simultaneously. We present spectroscopic spectral-domain optical coherence microscopy performed with a multimodality microscope. Restricting the spatial extent of the signal by using high-numerical-aperture optics makes high-resolution spectroscopic information accessible, facilitated with spectral-domain detection. Simultaneous acquisition of multiphoton microscopy images is used to validate tissue structure and localization of nuclei within individual cells.     

多尺度条件卷积的OCT视网膜图像降噪研究

散斑噪声存在于光学相干层析成像(OCT)中,影响OCT图像质量.在使用OCT设备诊断各种常见眼科疾病时,高质量的OCT图像是极为重要的.利用深度神经网络对OCT图像进行降噪处理,使图像在保留空间结构细节的基础上能展示更多的信息.提出了一种基于残差学习网络的新型OCT图像降噪网络-CMCNN,其具有多尺度、多权重和多层次...     

Simulation of basic characteristics of single-shot full-field optical coherence tomography using spatially phase-modulated reference light

For the single-shot full-field optical coherence tomography (OCT) using spatially phase-modulated reference light, the basic characteristics have been simulated. At low spatial frequencies, the OCT signal intensity is enhanced twofold owing to subtractions, and with increasing the spatial frequency, the OCT signal intensity decreases 0.636 times at half the Nyquist frequency. OCT signal intensities also depend on orientations in images. Residual noninterference components of signal intensities between adjacent uniform areas increase background noise and reduce the system sensitivity. In the reference light, the optimum phase difference between adjacent uniform areas is 180 deg. Deviations from 180 deg reduce subtracted interference components. It is important that interference intensity, noninterference components and phases between adjacent uniform areas be approximately the same to obtain the OCT image with the reduction of background noise stably.     

Fourier domain optical coherence tomography using optical demultiplexers imaging at 60,000,000 lines/s

We describe high-speed Fourier domain optical coherence tomography (OCT) using optical demultiplexers (ODs) for spectral dispersion. The OD enables separation of a narrow spectral band of 14 GHz (0.11 nm) from a broadband incident light at 256 different frequencies in 25.0 GHz intervals centered at 192.2 THz (1559.8 nm). OCT imaging of 60,000,000 axial scans per second was achieved through parallel signal acquisition using 256 balanced photoreceivers to simultaneously detect all the output signals from the ODs in a Fourier domain OCT system. OCT imaging at a 16 kHz frame rate, 1100 A-lines per frame, 3 mm depth range, and 23 microm resolution was demonstrated using a resonant scanner for lateral scanning.     

Linear optical coherence tomography system with extended measurement range

Optical coherence tomography (OCT) sensors traditionally use scanning optical delay lines with moving parts and a single detector. OCT systems with a linear detector array (linear OCT or L-OCT) are simple and robust, but a detector with approximately 10,000 pixels is needed for an imaging depth of 2mm, which is necessary for most biomedical applications. We present a new optical setup for L-OCT with an increased measurement range. An additional grating performs a reduction of the spatial frequencies of the fringe pattern on the detector without loss in the signal-to-noise ratio, so the signal can be sampled with a minimal number of pixels. The theory for this approach is addressed and the first measurements are presented.     

Fermions obstruct dimensional reduction in hot QCD

A nonparametric Bayesian approach is developed to determine quantum potentials from empirical data for quantum systems at finite temperature. The approach combines the likelihood model of quantum mechanics with a priori information on potentials implemented in the form of stochastic processes. Its specific advantages are the possibilities to deal with heterogeneous data and to express a priori information explicitly in terms of the potential of interest. A numerical solution in maximum a posteriori approximation is obtained for one-dimensional problems. As nonparametric estimates, the results depend strongly on the implemented a priori information.     

Three‐Dimensional,Time‐Resolved Profiling of Ferroelectric Domain Wall Dynamics by Spectral‐Domain Optical Coherence Tomography

We apply here spectral‐domain optical coherence tomography (SD‐OCT) for the precise detection and temporal tracking of ferroelectric domain walls (DWs) in magnesium‐doped periodically poled lithium niobate (Mg:PPLN). We reproducibly map static DWs at an axial (depth) resolution down to ～ 0.6 μm, being located up to 0.5 mm well inside the single crystalline Mg:PPLN sample. We show that a full 3‐dimensional (3D) reconstruction of the DW geometry is possible from the collected data, when applying a special algorithm that accounts for the nonlinear optical dispersion of the material. Our OCT investigation provides valuable reference information on the DWs’ polarization charge distribution, which is known to be the key to the electrical conductivity of ferroelectric DWs in such systems. Hence, we carefully analyze the SD‐OCT signal dependence both when varying the direction of incident polarization, and when applying electrical fields along the polar axis. Surprisingly, the large backreflection intensities recorded under extraordinary polarization are not affected by any electrical field, at least for field strengths below the switching threshold, while no significant signals above noise floor are detected under ordinary polarization. Finally, we employed the high‐speed SD‐OCT setup for the real‐time DW tracking upon ferroelectric domain switching under high external fields.