王万银1,
熊盛青2,,
1. 长安大学重磁方法技术研究所, 长安大学地质工程与测绘学院, 长安大学西部矿产资源与地质工程教育部重点实验室, 西安 710054
2. 中国自然资源航空物探遥感中心, 自然资源部航空地球物理与遥感地质重点实验室, 北京 100083
基金项目: 国家重点研发计划项目(2017YFC0602200)之课题"航空地球物理综合处理解释方法研究及软件开发"(2017YFC0602202)和中央高校基本科研业务费专项资金-长安大学优秀博士学位论文培育资助项目、长安大学研究生科研创新实践项目联合资助
详细信息
作者简介: 张义蜜, 男, 1993年生, 陕西安康人, 博士研究生, 研究方向为重、磁方法理论及应用.E-mail:zhangyimee@163.com
通讯作者: 熊盛青, 男, 1963年生, 教授级高级工程师, 博士生导师.长期从事航空地球物理、遥感技术及其地学应用研究工作.E-mail:xsq@agrs.cn
中图分类号: P631收稿日期:2019-11-20
修回日期:2020-05-09
上线日期:2020-11-05
Research on the vertical recognition ability of gravity and magnetic data of point (line) source model with given survey accuracy
ZHANG YiMi1,,WANG WanYin1,
XIONG ShengQing2,,
1. Institute of Gravity and Magnetic Technology, School of Geology Engineering and Geomatics, Chang'an University, Key Laboratory of Western Mineral Resources and Geological Engineering, Ministry of Education, Chang'an University, Xi'an 710054, China
2. China Aero Geophysical Survey and Remote Sensing Center for Natural Resources, Key Laboratory of Airborne Geophysics and Remote Sensing Geology, Ministry of Natural Resources, Beijing 100083, China
More Information
Corresponding author: XIONG ShengQing,E-mail:xsq@agrs.cn
MSC: P631--> Received Date: 20 November 2019
Revised Date: 09 May 2020
Available Online: 05 November 2020
摘要
摘要:重、磁勘探具有效率高、成本低、工作范围广等优点,已在地球物理勘探中得到了广泛应用.前人大多在不考虑重、磁勘探观测精度的条件下进行了垂向识别能力的研究,但在考虑重、磁观测精度条件下,重力(重力异常、重力张量)与磁力(磁力异常、磁力三分量、磁力张量)对孤立异常的垂向识别能力如何则需要进行深入的理论研究.本文从重、磁场正演理论出发,以球体(点源模型)和无限延伸水平圆柱体(线源模型)为例,考虑给定观测精度条件下,以重力和磁力幅值大小与观测精度的关系来研究垂向识别能力,从而消除了背景场的影响,提高了研究结果的可靠度.通过研究表明,对于孤立异常,重力张量在浅部一定深度内比重力异常的垂向识别能力强,该深度与重力异常和重力张量观测精度的比值成正比;垂直磁化磁力张量在浅部一定深度内比化极磁力异常的垂向识别能力强,该深度与磁力异常与磁力张量观测精度的比值成正比;磁力在浅部一定深度内比重力的垂向识别能力强,该深度与地质体的磁化强度和剩余密度比值、重力观测精度和磁力观测精度比值成正比.通过重力和磁力垂向识别能力的研究将为重、磁勘探的实际应用起到指导作用.
关键词: 垂向识别能力/
重力异常/
重力张量/
化极磁力异常/
垂直磁化磁力张量
Abstract:Gravity and magnetic exploration have been widely used in geophysical exploration because of the advantages of high efficiency, low cost and wide working range. Most researches on the vertical recognition ability of gravity and magnetic data were considered without survey accuracy. Hence, theoretical research on gravity anomalies, magnetic anomalies and tensor vertical detection ability of isolated anomaly are still necessary with the given gravity and magnetic survey accuracy. The research on vertical recognition ability is based on forward theory of the gravity and magnetic field to study the relationship between amplitude and survey accuracy with given survey accuracy to eliminate the influence of the background field, which improves the reliability of the research results. The study shows that for isolated anomalies, the gravity tensor has a stronger vertical recognition ability than gravity anomalies at a certain shallow depth. This depth is proportional to the ratio of the gravity anomaly survey accuracy to the gravity tensor survey accuracy. The vertical magnetization magnetic tensor has a stronger vertical recognition ability than the polar magnetic anomalies at a certain shallow depth. This depth is proportional to the ratio of the polar magnetic anomalies survey accuracy to the vertical magnetization magnetic tensor survey accuracy. The magnetic field has a stronger vertical recognition ability than gravity at a certain shallow depth. This depth is proportional to the ratio of magnetization to residual density, gravity survey accuracy to magnetic survey accuracy. This result will guide the practical application of gravity and magnetic exploration.
Key words:Vertical recognition/
Gravity anomalies/
Gravity tensor/
Reduction to the pole (RTP) of magnetic anomalies/
Vertical magnetization magnetic tensor
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