High-Resolution Cooperate Density-Integrated Inversion Method of Airborne Gravity and Its Gradient Data

Ma, Guoqing; Gao, Tong; Liu, Lili; Wang, Taihan; Niu, Runxin; Li, Xinwei

doi:10.3390/rs13204157

Cited by 2 publications

(2 citation statements)

References 55 publications

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“…Depending on whether the physical models corresponding to different observations are the same and relevant, there are two groups of joint inversion. The first group is the joint inversion of different geophysical data corresponding to the same physical model, such as gravity and gravity gradient data joint inversion for density structure [16][17][18][19][20]. It can recover high-resolution models at different depths by exploiting the fact that the gradient data are more sensitive to shallow sources, and field data emphasize the response of deep sources.…”

Section: Of 17mentioning

confidence: 99%

Power-Type Structural Self-Constrained Inversion Methods of Gravity and Magnetic Data

Ming,

Ma,

Wang

et al. 2024

Remote Sensing

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The inversion of gravity and magnetic data can obtain the density and magnetic structure of underground space, which provide important information for resource exploration and geological structure division. The most commonly used inversion method is smooth inversion in which the objective function is built with L2-norm, which has good stability, but it produces non-focused results that make subsequent interpretation difficult. The power-type structural self-constrained inversion (PTSS) method with L2-norm is proposed to improve the resolution of smooth inversion. A self-constraint term based on the power gradient of the results is introduced, which takes advantage of the structural feature that the power gradient can better focus on the model boundary to improve the resolution. For the joint inversion of gravity and magnetic data, the power-type mutual-constrained term between different physical structures and the self-constrained term can be simultaneously used to obtain higher-resolution results. The modeling tests demonstrated that the PTSS method can produce converged high-resolution results with good noise immunity in both the respective inversions and the joint inversion. Then, the PTSS joint inversion was applied to the airborne gravity and magnetic data of the iron ore district in Shandong, revealing the shape and location of the mineralized rock mass, which are crucial information for subsequent detailed exploration.

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Section: Of 17mentioning

confidence: 99%

Power-Type Structural Self-Constrained Inversion Methods of Gravity and Magnetic Data

Ming,

Ma,

Wang

et al. 2024

Remote Sensing

Self Cite

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“…The gravitational field and fluctuations underneath and beyond Earth's surface are detected by gravity sensors acquired from watercraft, boreholes, aircraft, and spacecraft as a combination of time and location [50,51]. Presently, the gravity anomaly of a region is commonly acquired by gravity measurements from satellites [52]. In 2000, gravity satellite missions were launched and focused on gathering data on a wide range, with a high spatial resolution and a large observation area.…”

Section: Satellite Gravity Datamentioning

confidence: 99%

The 2022 Mw 6.1 Pasaman Barat, Indonesia Earthquake, Confirmed the Existence of the Talamau Segment Fault Based on Teleseismic and Satellite Gravity Data

et al. 2022

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A Mw 6.1 earthquake on 25 February 2022, at around 8:39 a.m. local time, struck Pasaman Barat Regency, West Sumatra, Indonesia, and was felt in Singapore and Malaysia. The hypocenter of this earthquake was 12 km deep and preceded by an Mw 4.9 foreshock a few minutes earlier. The earthquakes originated on a blind fault and triggered a landslide at Mount Talamau. Herein, the slip distribution and asperities along the plane fault during the earthquake were examined by teleseismic inversion and the fault location was identified by Global Gravity Model plus (GGMPlus) satellite gravity data. The slip distribution was calculated from the source parameters (strike: 136°; dip: 70°; rake: 174°) by inversion techniques based on teleseismic data. Based on the slip distribution, the earthquake was generated by stress from the Sianok fault that spread to the north and reached the uncertain fault segment in the Talamau area. In addition, the results of the First Horizontal Derivative and Second Vertical Derivative from the GGMplus data revealed a straight Simple Bouguer Anomaly pattern, confirming the existence of the uncertain Talamau fault as part of the Great Sumatra Fault. This work shows the potential application of the combination of teleseismic and gravity observation for delineating the fault structure that caused the 2022 Mw 6.1 Pasaman earthquake, which can also be applied to other locations of similar geological backgrounds.

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High-Resolution Cooperate Density-Integrated Inversion Method of Airborne Gravity and Its Gradient Data

Cited by 2 publications

References 55 publications

Power-Type Structural Self-Constrained Inversion Methods of Gravity and Magnetic Data

Power-Type Structural Self-Constrained Inversion Methods of Gravity and Magnetic Data

The 2022 Mw 6.1 Pasaman Barat, Indonesia Earthquake, Confirmed the Existence of the Talamau Segment Fault Based on Teleseismic and Satellite Gravity Data

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