共查询到17条相似文献,搜索用时 187 毫秒
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通过模型磁异常分解,结合功率谱分析及异常振幅计算场源深度并判断场源分布平面位置,表明小波多尺度分析在位场分离中的有效性.将该方法应用于北衙铁金矿区磁异常分析解释,通过功率谱分析估算了各阶细节及四阶逼近的场源深度,结合不同深度异常振幅推断了磁源空间展布关系特征.分析表明,区内北部和西部强磁异常主要由矿体引起,且矿体在中深部产状发生改变;而东部大范围磁异常区主要为二叠系玄武岩所致. 相似文献
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《物探化探计算技术》1980,(1)
前言最近文献中刊载了一种快速计算任意形状物体重磁异常的富氏变换法,其基本原理如下: 具有均匀密度或均匀磁化强度分布的任意形状物体的重力与磁力异常均可表示为场源几何形状函数与格林函数的褶积。因此,它们的频谱可以表示为这两个函数的富氏变换的乘积。要计算物体引起的重磁异常,关键在于给出格林函数与场源几何形状的富氏变换,然后再对这两个函数的富氏变换的乘积作反富氏变换。场源几何形状由描述物体形状的解析式给出,格林函数则仅与观测点的位置和磁化强度矢量或密度有关,而与场源的几何形状无关。所以,对于某种场位来说,只要一次 相似文献
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本文所研究的是一种在地下场源分布未知的情况下,突出预定深度场源重、磁异常的滤波方法.文中介绍了基本原理,给出了有确定物理意义的滤波算子,并列举了在理论模型场和实测重力场上进行滤波计算的结果.方法原理位于(ξ,η,z)处的球体的磁场强度沿某一方向的分量,用函数f(x,y)表示,其谱函数用F(ων)表示,式中代ω,ν表圆频率.则 相似文献
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基于重磁场特征的松辽盆地基底岩性研究 总被引:2,自引:0,他引:2
盆地的基底埋藏深度、岩性和断裂分布与地热资源的形成、分布和开发利用密切相关。本文基于重磁方法的特点和松辽盆地的重磁场异常,利用最佳向上延拓的方法进行场源分离,提取了基底重磁异常信息;依据不同岩石物理属性(密度和磁性)和重磁异常对应分析的结果,对松辽盆地的基底岩性分布进行了划分,其结果对盆地地热资源远景评价和开发利用有重要参考价值。 相似文献
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复小波变换反演重力异常 总被引:6,自引:2,他引:6
对国外最新研究位场连续复小波变换理论的一系列文章进行了系统归纳、推导与总结,推出了板状体重力场的小波变换系数解析式.对齐次场源形成的重力场进行柯西小波变换,等效于重力场向上延拓和求导两种运算相结合,并服从小波变换双尺度定律.利用小波变换系数模沿极值轴线的变化特征同时反演重力场源的几何形状、埋深、倾角.独立编写了所有程序,并对不同理论模型进行了大量计算,对所有结果进行了分析与讨论.此法为重力场反演提供了一条新的途径,实用于重磁资料自动化处理、反演与解释. 相似文献
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甘肃白银厂铜多金属硫化物矿田是受陆缘弧环境火山机构及其同生断裂控制的典型火山岩赋矿块状硫化物矿床(VHMS)。为了进一步探讨该矿床重磁场特征及与构造和矿床的关系,通过对区内的重磁场异常数据进行位场分离、小波分析和基于张量数据的三维欧拉反褶积自动确定地质体位置和埋藏深度的定量反演计算。结果表明,研究区布格重力场具有西部高、东部低的特征,其磁场可划分为4个磁场区;局部异常按一定分布规律呈圆形或似圆形正负相间分布,不同尺度的重磁细节异常图在一定程度上反映出引起重磁异常的地质异常体具有一定的延深且分布稳定,而且这些地质异常体具有向深部复合的趋势。经位场分离后正负相间的剩余重磁异常分布范围和分布特征大致反映了白银厂奥陶纪中酸性火山岩建造构造为一个继承性的火山穹窿构造,东、西部不同的重磁异常特征说明东西部的火山喷发具有不同的基底、源区和喷发方式。发育NW向、NE向、近NS向、NEE向等4组断裂构造,近NS向断裂F3、F4、F5、F6、F7形成时间稍晚于NEE向断裂,其与NEE向断裂F1、F2共同形成了研究区棋盘网格状的构造分布特征,这两组断裂为研究区内主要的控岩、控矿断裂。火山机构的分布明显受断裂构造控制,火山口集中分布在深大断裂、大断裂或两组断裂的交汇处。矿田内各矿床及成矿有利地段均处于研究区中部低缓重磁异常场内正负磁异常变化的梯度带内。本次研究为控矿要素研究和开展找矿预测工作提供了丰富、翔实的地球物理资料。 相似文献
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基于小波分析的磁测数据处理流程及解释方法 总被引:3,自引:1,他引:2
对某地区高精度磁测数据,为了有效分析地下场源的异常特征,作者采用小波分析方法对磁异常进行多尺度分析,获取不同深度层次的场源信息,结合平面、剖面资料的反演处理解释,利用2.5维模型反演建立了地下场源的地球物理模型.通过分析,认为小波多尺度分析可以更好的揭示深部场源的赋存信息,计算精度可靠,较传统的延拓、滤波等方法有更高的分辨率. 相似文献
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场源中心位置的计算是重磁数据反演的主要任务之一,现主要通过异常与场源位置之间的数学物理方程来估算地质体的位置.为了快速、准确获得地质体的位置信息,提出基于重磁梯度比值的深度学习技术实现场源位置的获取;其利用深度学习技术所建立的重磁梯度比值水平分布与地质体埋深、构造指数的关系,快速实现异常场源位置计算,且提出利用多个值的相互关系来更加准确、稳定地计算出地质体的信息.该方法可以计算复杂地质体的中心位置,且避免了以往线性方程反演方法需对结果进行筛选的复杂过程,对于存在剩磁的磁异常则采用解析信号的深度学习方法来进行位置反演.理论模型试验证明利用梯度比值的深度学习方法可以准确获得地质体的深度,且通过对比更多点的深度学习计算结果发现,采用多个不同比例极值点可以减弱噪声带来的干扰,从而得到更加准确的位置.最后将该方法应用于实测磁异常的反演工作,获得了地下磁性物体的中心位置,且计算结果与欧拉反褶积法相接近,因此该方法具有良好的实用性. 相似文献
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Pamancalan is located in Lebak Regency, Province of Banten. This area is located in the western part of Java Island, Indonesia. The geothermal manifestation in this area is in the form of hot spring in Cipamancalan River. But, how the structure of the geothermal system, the reservoir depth, and the thermal source in the Pancamalan area has not been studied much. Therefore, there is a need to conduct a geophysics study by surveying the gravity and magnetic field. A study, which used magnetic and gravity data to discover reservoir, has been conducted in the Pamancalan geothermal area in Lebak, Banten. Topographic map for total magnetic and earth gravity anomaly shows that the anomaly is located in the center and southern part of the presumed reservoir. 2.5-D section model of magnetic anomaly shows that there is a rock formation which shaped the geothermal system in Pamancalan. The thermal source is diorite which is a by-product of Hanjawar Mountain; the reservoir rocks consist of sandstone, limestone, and breccia; and the cap rock is in the form of clay and tuff. It is predicted that there is an intrusive body which functions as thermal source in the depth between 1650 and 4000 m, the reservoir depth is around 700 m, and the depth of clay cap is around 0 to 700 m. The geothermal manifestation in Pamancalan area is controlled by Cigeledug fault from the southwest and Cipamancalan fault from the north and south. 相似文献
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M. Mohammadzadeh Moghaddam S. Mirzaei J. Nouraliee S. Porkhial 《Arabian Journal of Geosciences》2016,9(7):506
The Delijan region of Central Iran is a popular tourist spot due to the occurrence of hot springs and having the greatest geothermal fields in Iran. In the years 2011 and 2012, an integrated geophysical investigation, using magnetic and gravity methods, was conducted over the hot springs in order to characterize geophysical anomaly sources corresponding to the geothermal resources. The results of the geophysical investigations revealed the heat source and the reservoir of the Delijan geothermal system (DGS). Based on results of Euler depth estimation and 3D inversion of magnetic and gravity data, the depths and extension of the discovered structures were determined with a good correlation with the geological information. The results of magnetic interpretation show that the main source (heat source) of the geothermal system is located NE of the Delijan-Abgarm fault (DAf) zone at depths of 2500 to 5000 m, and the results of gravity interpretation show that the reservoir of the geothermal system is located along the DAf zone at depths of 1000 to 4000 m. Also, the horizontal gradients of gravity data reveal complex fault systems which are acting as the preferential paths to circulate the hydrothermal fluids. 相似文献
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The Rapid Inversion of 3-D Potential Field and Program Design 总被引:1,自引:0,他引:1
The application of three-dimensional inversion of gravity and magnetic fields is very important not only in geophysical researches, but also in the study of geological structures. A formula of potential field in frequency-domain, developed by Parker in 1973, can be used as a rapid and effective algorithm in gravity and magnetic inversion. The technique has been improved then by Oldenburg, Sprenke, Feng and others.In addition to a brief introduction of Parker's algorithm and its applications, this paper includes the following five parts: basic computational techniques, inversion of single layer, convergence and constraints, simultaneous inversion for density and topography as well as inversion of multilayers. The authors present relevant practical iterative formulas and its varieties when density distribution varies with depth in linear or exponential relation. In order to maintain computation stability and speed up iteration convergence, some approaches are taken in the program design, for instance shifting lower interface of the studied layer, inverting corrections of topography, reducing grid boundary effects and utilizing low-pass filter. With the consideration of the nonuniqueness of the inversion, a method of using seismic data to constrain the range ofpossible models is discussed. It is pointed out that the density variation generates less effects than those of topography on the spectrum of gravity anomaly in second order. Therefore density contrast and topography can be inverted simultaneously by an alternative weighting iteration. By analogy, the inversion of multilayer model can be done in the above procedure. An approach of model decomposition is useful in the computation of multilayer model. The techniques discussed in the present paper for gravitational field are also valid for magnetic field. 相似文献
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Pramod Kumar Yadav P K Adhikari Shalivahan Srivastava Ved P Maurya Anurag Tripathi Shailendra Singh Roshan K Singh Ashish K Bage 《Journal of Earth System Science》2018,127(2):17
Dalma volcanics (DVs) has intruded the older Singhbhum Group of Metapelites. Despite DVs being rich in mineralisation, its boundaries are not clearly demarcated. Gravity and magnetic surveys have been attempted for mapping the boundaries in DVs. These surveys were made in the northern fringe of the DVs over an area of \(\sim \)0.70 \(\hbox {km}^{2}\) along 13 parallel lines at 50 m spacing. The data was acquired at \(\sim \)25 \(\hbox {m}\) spacing. The surveys were taken for determination of lithological boundaries, depths and nature of causative source using Euler depth solutions and radially averaged power spectrum (RAPS). Residual anomaly maps of gravity and magnetic intensity show the same trend as that of Bouguer gravity anomaly and total magnetic intensity anomaly map indicating towards shallow sources. The magnetic map in general follows the same pattern as that of gravity anomaly maps. The map shows coincident high gravity and magnetic anomalies. These anomalies together with resistivity signatures confirm that the northern fringe of DVs hosts volcanogenic massive sulphide settings. The Euler depth solution delineated the lateral boundaries and nature of the source. It seems that the source is of spherical nature lying within a depth range of 25–40 m. The obtained lithological (vertical) units from RAPS are between Lower DVs, Upper DVs and Singhbhum Group Metapelites at depths of \(\sim \)15, \(~\sim \)25 and \(\sim \)40 \(\hbox {m}\), respectively. The metallogeny is associated with the Upper DVs and the corresponding delineated lithological (vertical) unit is indicative of the top of the ore body. Good agreement is observed with the geological succession from the drilling data and resistivity data. The findings suggest that the northern fringe of DVs could be a preferred target for drilling. 相似文献
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The Cambro-Ordovician Jaibaras Rift is a NE–SW trending elongated feature, controlled by the Transbrasiliano lineament, locally known as Sobral-Pedro II shear zone (SPIISZ). An integrated study of geophysical data (gammaspectrometry, magnetometry and gravimetry) was undertaken in the Jaibaras Rift area, between Ceará Central (CCD) and Médio Coreaú domains (MCD), northwest Borborema Province. Geophysical data were interpreted qualitatively and quantitatively in order to understand the tectono-magmatic relations and rift formation based on the main geophysical lineaments, source geometry and depth, and separation of geophysical domains. In addition, a 2D gravity model was generated. The results show a structural partition characterized by NE–SW lineaments and E–W inflexions, where CCD presents a relatively mild magnetic field, whilst the MCD field is more disturbed. The Jaibaras Rift is characterized by positive magnetic and gravity anomalies. The SPIISZ, which corresponds to the SE fault edge of the Jaibaras Rift, is marked by strong magnetic dipoles and strong gravity gradients in the profile, showing the deep character of the Transbrasiliano lineament in the region. The Café-Ipueiras fault, at the NW edge of the rift, is well marked in gravity profiles, but displays low contrast of the magnetic field. Interpretation of the gravimetric anomaly map allowed to recognizing the main NE–SW axis, with alternation of maxima and minima in MCD. A regional gravity gradient reveals significant lateral density variation between the MCD and CCD perpendicular to the SPIISZ, emphasizing it as a main continental suture zone between crustal blocks. 相似文献