基于小波熵的探地雷达频率波数偏移成像在地下管线探测中的应用

本研究提出了一种基于小波熵的探地雷达频率波数偏移成像方法,以提高地下管线探测的准确性和可靠性,通过时域有限差分法进行正演模拟,设计了单排管和双排管的地电模型,并通过实验验证了不同频率天线的探测效果。结果显示,400 MHz频率天线在探测埋深较浅、管径较小的管线时效果显著优于200 MHz天线,且小波熵结合频率波数偏移成像方法能够有效抑制噪声和干扰,提高成像质量。此方法在复杂地下环境中表现出良好的适用性,为地下管线探测提供了一种新的技术手段和方法。通过实验验证,本研究方法能够在实际应用中准确识别和定位地下管线,减少多次波干扰,增强深部反射信号,提升地下管线探测的准确性和可靠性,为城市地下管线管理和维护提供了有力支持。

基于DCT的探地雷达频率波数偏移优化算法

目前探地雷达频率波数偏移算法中插值运算涉及复数运算,且对所有频率波数域内的数据进行运算,易引起复数寄生量和计算量大的问题。由此在分析离散余弦变换特点的基础上,引入离散余弦变换代替傅里叶变换用于频率波数偏移算法,以实变换代替复数变换,解决复数寄生量的问题;利用离散余弦变换能量集中的性质,仅对部分主要的离散余弦分量对应的数据进行插值偏移处理,减少计算复杂度以实现插值算法优化。实测数据表明,该文所提的优化方法效果明显。

基于小波熵的地下管线探地雷达频率波数偏移成像研究

地下管线实际形状与准确位置的确定是探地雷达图谱解释的主要内容之一.制约管线探地雷达反射归位精度最主要的因素是电磁波在地层中的传播速度,如何准确确定电磁波传播速度是探地雷达偏移处理能否成功的关键.为便于对探地雷达图谱特征进行定量解释,开展了不同大小、埋深与重叠等情况管线的正演模拟与模型实验.结合小波熵理论与频率波数偏移成像方法,提出了一种基于小波熵的探地雷达频率波数偏移成像方法,将其应用于地下管线正演模拟与模型实验探地雷达信号偏移处理.研究结果表明:探地雷达图像经基于小波熵的频率波数偏移处理后,电磁波速度的估计值与真实值误差可控制在2%以内;随着管线管径大小与埋置深度的增加,绕射双曲线的开口弧度不断增大,管与管之间绕射波交叉干扰越严重;探地雷达信号经基于小波熵的频率波数偏移处理后可大大提高图像的分辨率,压制了多次波的干扰,使绕射双曲线更收敛,能量更聚焦,从而有利于地下管线实际形状与具体位置的准确提取.研究结果对城市地下管线探地雷达图谱解译工作提供技术支持.

基于频率-波数域偏移方法的板结构损伤实时识别

借鉴在地球物理学等领域成功应用的偏移技术,提出了一种应用散射Lamb波对板结构中多部位损伤进行实时识别的方法。基于Mindlin板理论,首次推导了板结构中弥散性弯曲波频率-波数域的快速偏移方法。结合爆炸成像原理,采用零炮检距散射波信号对损伤进行成像识别。数值仿真研究表明本文提出方法不仅能够识别多部位损伤的位置,还具有识别损伤程度的潜力,其快速计算的优点满足在线结构健康监测系统对实时性的要求。

基于F-K偏移及最小熵技术的探地雷达成像法

地下目标位置和形状的确定是探地雷达实际工程应用中需要解决的主要问题之一,地震信号处理技术中的偏移方法是比较有效的地下目标图像归位方法,介质中的波速度是影响目标图像归位精度的最主要因素。该文在利用图像最小熵方法对介质中波速度进行估计基础上,借助于频率-波数域偏移技术对探地雷达图像进行了处理。分别通过数值模拟图像和探地雷达系统实际探测图像验证了该文方法的有效性。

基于Mindlin板理论的偏移损伤成像数值仿真研究

提出了一种应用散射Lamb波的偏移技术对板结构中多部位损伤进行实时识别.基于Mindlin板理论,推导了板结构中弥散性弯曲波频率-波数域的快速偏移方法.首先对由线性传感器阵列激励和接收到的入射和散射波场在波数-频率域分别进行延拓,然后根据Huygens原理,结合波场延拓的时间一致性原理施加成像条件,对损伤进行成像识别.数值仿真研究采用基于Mindlin板理论的有限差分法模拟结构中含不同形状及尺寸损伤时的散射波场.对模拟散射波场进行偏移成像的结果表明该方法不仅能够识别多部位损伤的位置,还具有识别损伤程度的能力,其快速计算的优点满足在线结构健康监测系统对实时性的要求.

傅里叶变换红外光谱研究拉伸过程中应压木主要化学组分的响应规律

应压木的适应性生长导致了针叶树木材化学性质发生变化,其中微纤丝角的变大主要引起木材主要化学组分变形机制发生了变化,影响其力学性质。以马尾松应压木和正常材为研究对象,通过傅里叶变换红外光谱对比研究应压木和正常材在拉伸过程中木材主要化学组分官能团的变化规律差异,对研究应压木力学性能变化的分子响应机制具有重要意义。结果表明:应压木的微纤丝角为35.17°±2.30°,而正常材为15.15°±1.61°;应压木和正常材的顺纹抗拉强度分别为(45.37±3.41)和(109.75±11.87) MPa,弹性模量分别为(18.10±0.76)和(70.95±6.60) MPa,但应压木的屈服变形大于正常材,破坏点的应变值约为正常材的3倍。傅里叶变换红外光谱结果表明:应压木和正常材纤维素中糖苷键C-O-C(1 161 cm^-1)和纤维素分子内氢键O(3)H…O(5)(3 348 cm^-1)的红外吸收特征峰波数都随拉伸应变发生线性变化。其中,应压木中纤维素的糖苷键C-O-C向低波数偏移量为-1.52 cm^-1·dε^-1,而正常材的苷键偏移量为-2.15 cm^-1·dε^-1;应压木中纤维素分子链内氢键O(3)H…O(5)的波数向高波数偏移量为4.62 cm^-1·dε^-1,而正常材纤维素分子链内氢键偏移量为2.76 cm^-1·dε^-1。应压木纤维素的糖苷键向低波数的偏移量、纤维素分子链内氢键向高波数的偏移量均小于正常材,但两者木质素和半纤维素特征官能团的红外吸收特征峰波数没有明显偏移。根据应压木和正常材拉伸过程中的主要化学组分响应规律,纤维素依然作为应压木在拉伸过程中的承载物质,而基体的主要作用是应力传递;但微纤丝排列重新取向;与正常材相比,应压木中较大的微纤丝角会导致纤维素分子链长度方向的变形较小,但微纤丝与基体之间的剪切变形会较大。这也导致了应压木在拉伸过程中会发生较大的屈服变形,破坏点的应变大于正常材。

钢筋混凝土缺陷的探地雷达检测模拟与成像效果

采用时域有限差分方法模拟钢筋混凝土缺陷体的雷达检测,并利用频率域-波数域偏移(F-K)方法进行数据处理。通过F-K偏移削弱钢筋网强干扰信号对缺陷体信号的影响,使钢筋网及缺陷体的反射电磁波信号聚焦归位,从而突出缺陷体及分布范围。研究表明,F-K偏移能很好地把将钢筋网及缺陷体的绕射波聚集归位,有效分离目标体,提高纵向分辨率能力,利于准确解释缺陷体及形态特征。

基于频率-波数域偏移的损伤被动成像识别研究

提出了一种应用Lamb波对板结构中多部位损伤源进行被动成像识别的方法.基于Mindlin板理论,推导了板结构中弥散性Lamb波频率-波数域的快速偏移方法,结合爆炸成像原理,对损伤源发出的Lamb波信号进行回传成像.由于损伤源的发生时刻未知,将使用不同假设发生时刻(即不同长度)的Lamb波信号生成一系列图像,通过最小熵原理从中确定最优图像,识别出损伤源的位置和发生时刻.进行了数值仿真研究来表明所提出方法的有效性.

雷达近场成像中SVM的目标识别方法

雷达近场成像中,在精确定位的基础上,为解决目标形状识别问题,提出了利用支持向量机(SVM)预测目标信息的方法。根据时域算法——后向投影(BP)算法和频域算法——频率波数域(F-K)偏移算法得到的场强值作为SVM的特征数据,并利用时域有限差分法(FDTD)进行仿真。仿真结果表明,基于BP算法的SVM识别方法具有特征数据提取时间长、SVM预测时间短、多目标时目标信息全和虚警较多等特征,基于F-K算法的SVM识别方法具有特征数据提取时间非常短、SVM预测时间非常短、多目标时目标漏检的特征;两者都能较好地识别目标的形状,且前者的识别能力高于后者,而后者更适合实时成像。

High-order generalized screen propagator migration based on particle swarm optimization

Various migration methods have been proposed to image high-angle geological structures and media with strong lateral velocity variations; however, the problems of low precision and high computational cost remain unresolved. To describe the seismic wave propagation in media with lateral velocity variations and to image high-angle structures, we propose the generalized screen propagator based on particle swarm optimization （PSO-GSP）, for the precise fitting of the single-square-root operator. We use the 2D SEG/EAGE salt model to test the proposed PSO-GSP migration method to image the faults beneath the salt dome and compare the results to those of the conventional high-order generalized screen propagator （GSP） migration and split-step Fourier （SSF） migration. Moreover, we use 2D marine data from the South China Sea to show that the PSO-GSP migration can better image strong reflectors than conventional imaging methods.

True-amplitude wavefield separation using staggered-grid interpolation in the wavenumber domain

Wavefield separation of multicomponent seismic data to image subsurface structures can be realized in either the space domain or the wavenumber domain. However, as the particle velocity components used in the wavenumber-domain wavefield separation are not defined at the same grid point with the staggered-grid finite-difference method for elastic wavefield simulation, we propose the wavenumber-domain interpolation method to estimate the required values at the common grid points prior to the wavenumber-domain true-amplitude wavefield separation. Moreover, numerical experiments show that the wavenumber-domain interpolation method has high interpolation accuracy and the trueamplitude wavefield separation method shows good amplitude preservation. The application of the proposed methodology to elastic reverse-time migration can obtain good amplitudepreserved images even in the case of some velocity error.

E^2KF Based Joint Multiple CFOs and Channel Estimate for MIMO-OFDM Systems over High Mobility Scenarios

An enhanced extended Kalman filtering （E2KF） algorithm is proposed in this paper to cope with the joint multiple carrier frequency offsets （CFOs） and time-variant channel estimate for MIMO-OFDM systems over high mobility scenarios. It is unveiled that, the auto-regressive （AR） model not only provides an effective method to capture the dynamics of the channel parameters, which enables the prediction capability in the EKF algorithm, but also suggests an method to incorporate multiple successive pilot symbols for the improved measurement update.

Suppress numerical dispersion in reversetime migration of acoustic wave equation using optimal nearly analytic discrete method

Using staggered-grid finite difference method to solve seismic wave equation,large spatial grid and high dominant frequency of source cause numerical dispersion,staggeredgrid finite difference method,which can reduce the step spatial size and increase the order of difference,will multiply the calculation amount and reduce the efficiency of solving wave equation.The optimal nearly analytic discrete(ONAD)method can accurately solve the wave equation by using the combination of displacement and gradient of spatial nodes to approach the spatial partial derivative under rough grid and high-frequency condition.In this study,the ONAD method is introduced into the field of reverse-time migration(RTM)for performing forward-and reverse-time extrapolation of a two-dimensional acoustic equation,and the RTM based on ONAD method is realized via normalized cross-correlation imaging condition,effectively suppressed the numerical dispersion and improved the imaging accuracy.Using ONAD method to image the groove model and SEG/EAGE salt dome model by RTM,and comparing with the migration sections obtained by staggered-grid finite difference method with the same time order 2 nd and space order 4 th,results show that the RTM based on ONAD method can effectively suppress numerical dispersion caused by the high frequency components in source and shot records,and archive accurate imaging of complex geological structures especially the fine structure,and the migration sections of the measured data show that ONAD method has practical application value.

The Goos-Hnchen shift of wide-angle seismic reflection wave

The partial derivative equations of Zoeppritz equations are established and the derivatives of each matrix entry with respect to wave vectors are derived in this paper.By solving the partial derivative equations we obtained the partial derivatives of seismic wave reflection coefficients with respect to wave vectors,and computed the Goos-Hnchen shift for reflected P-and VS-waves.By plotting the curves of Goos-Hnchen shift,we gained some new insight into the lateral shift of seismic reflection wave.The lateral shifts are very large for glancing wave or the wave of the incidence angle near the critical angle,meaning that the seismic wave propagates a long distance along the reflection interface before returning to the first medium.For the reflection waves of incidence angles away from the critical angle,the lateral shift is in the same order of magnitude as the wavelength.The lateral shift varies significantly with different reflection interfaces.For example,the reflected P-wave has a negative shift at the reflection interface between mudstone and sandstone.The reflected VS-wave has a large lateral shift at or near the critical angle.The lateral shift of the reflected VS-wave tends to be zero when the incidence angle approaches 90°.These observations suggest that Goos-Hnchen effect has a great influence on the reflection wave of wide-angles.The correction for the error caused by Goos-Hnchen effect,therefore,should be made before seismic data processing,such as the depth migration and the normal-moveout correction.With the theoretical foundation established in this paper,we can further study the correction of Goos-Hnchen effect for the reflection wave of large incidence angle.