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| An observation device based on asymmetric design for high-density resistivity imaging |
PANG Yong-Hao( ), SHEN Zhao-Ang, CHANG Zhi-Xi, LI Guang-Chang, CHEN Mei, XIE Zhi-Wei, WANG Wei() |
| Zhejiang Huadong Geotechnical Investigation & Design Institute Co., Ltd., Hangzhou 310030, China |
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Abstract For the high-density resistivity method, favorable grounding conditions are required to ensure the establishment and measurement of the geoelectric field. Otherwise, unfavorable grounding conditions, like rigid pavement, will prevent some electrodes from being inserted into the ground, leading to the loss of valid data from standard observation devices and reducing the imaging quality. Therefore, this study proposed a method for the fast observation device design. This method supplemented data using an asymmetric quadrupole electrode array according to the spatial positions of missing data's recording points. Numerical simulations show that the method proposed in this study significantly improved the imaging effects of Wenner, Schlumberger, and dipole-dipole arrays, with a second-scale design time. In this study, an observation device based on asymmetric design for high-density resistivity imaging was successfully applied to the embankment detection in Ningbo, reducing the influence of motor lanes on data quality and accurately locating the embankment position.
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Received: 19 October 2023
Published: 27 June 2024
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Standard electrode array and recording point position
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Supplementary electrode array diagram
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Data distribution of Wenner array before and after replenishment
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Sensitivity distribution of Wenner array
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Data distribution of the Schlumberger array before and after replenishment
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Sensitivity distribution of Schlumberger array
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Data distribution of the Dipole-dipole array before and after replenishment
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Sensitivity distribution of Dipole-dipole array
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Comparison of experiment result before and after Wenner array optimization
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Comparison of experiment result before and after Schlumberger array optimization
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Comparison of experiment result before and after dipole-dipole array optimization
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Work scenario
a—electrode arrangement; b—electrode vacancies caused by asphalt pavement
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High density resistivity inversion cross-section before and after optimization
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Geological conditions revealed by excavation
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| [3] |
Zhou J B, Luo R H, He C K, et al. New geophysical evidence for Karst water-bearing seepage pathways in the Xiaohewei Reservoir,Wenshan City[J]. Geophysical and Geochemical Exploration, 2023, 47(3):707-717.
|
| [4] |
Li S C, Xu S, Nie L C, et al. Assessment of electrical resistivity imaging for pre-tunneling geological characterization:A case study of the Qingdao R3 metro line tunnel[J]. Journal of Applied Geophysics, 2018,153:38-46.
|
| [5] |
Guo Q, Pang Y H, Liu R T, et al. Integrated investigation for geological detection and grouting assessment:A case study in Qingdao subway tunnel,China[J]. Journal of Environmental and Engineering Geophysics, 2019, 24(4):629-639.
|
| [6] |
覃剑文, 姜晓腾, 谢贵城, 等. 基于高密度电法的城市复杂环境岩溶探查研究——以贵港市北环新村为例[J]. 物探与化探, 2023, 47(2):530-539.
|
| [6] |
Qin J W, Jiang X T, Xie G C, et al. Karst exploration in urban complex environments based on electrical resistivity tomography:A case study of Beihuan New Village in Guigang City[J]. Geophysical and Geochemical Exploration, 2023, 47(2):530-539.
|
| [7] |
Bauman P. 2D resistivity surveying for hydrocarbons--A primer[J]. CSEG Recorder, 2005, 30(4):25-33.
|
| [8] |
Legault J M, Carriere D, Petrie L. Synthetic model testing and distributed acquisition dc resistivity results over an unconformity uranium target from the Athabasca Basin,northern Saskatchewan[J]. The Leading Edge, 2008, 27(1):46-51.
|
| [9] |
Dahlin T, Zhou B. A numerical comparison of 2D resistivity imaging with 10 electrode arrays[J]. Geophysical Prospecting, 2004, 52(5):379-398.
|
| [10] |
Loke, Tutorial M H. 2D and 3D electrical imaging surveys[G]//Course Notes for USGS Workshop.2D and 3D Inversion and Modeling of Surface and Borehole Resistivity Data. 2001.
|
| [11] |
Furman A, Ferre T P A, Warrick A W. Optimization of ERT surveys for monitoring transient hydrological events using perturbation sensitivity and genetic algorithms[J]. Vadose Zone Journal, 2004, 3(4):1230-1239.
|
| [12] |
Nenna V, Pidlisecky A, Knight R. Informed experimental design for electrical resistivity imaging[J]. Near Surface Geophysics, 2011, 9(5):469-482.
|
| [13] |
Wilkinson P B, Meldrum P I, Chambers J E, et al. Improved strategies for the automatic selection of optimized sets of electrical resistivity tomography measurement configurations[J]. Geophysical Journal International, 2006, 167(3):1119-1126.
|
| [14] |
Wilkinson P B, Loke M H, Meldrum P I, et al. Practical aspects of applied optimized survey design for electrical resistivity tomography[J]. Geophysical Journal International, 2012, 189(1):428-440.
|
| [15] |
Wilkinson P B, Uhlemann S, Meldrum P I, et al. Adaptive time-lapse optimized survey design for electrical resistivity tomography monitoring[J]. Geophysical Journal International, 2015, 203(1):755-766.
|
| [16] |
Uhlemann S, Wilkinson P B, Maurer H, et al. Optimized survey design for electrical resistivity tomography:Combined optimization of measurement configuration and electrode placement[J]. Geophysical Journal International, 2018, 214(1):108-121.
|
| [17] |
Loke M H, Wilkinson P B, Chambers J E, et al. Optimized arrays for 2D resistivity survey lines with a large number of electrodes[J]. Journal of Applied Geophysics, 2015,112:136-146.
|
| [18] |
Qiang S Y, Shi X Q, Kang X Y, et al. Optimized arrays for electrical resistivity tomography survey using Bayesian experimental design[J]. Geophysics, 2022, 87(4):E189-E203.
|
| [19] |
Szalai S, Szarka L. On the classification of surface geoelectric arrays[J]. Geophysical Prospecting, 2008, 56(2):159-175.
|
| [1] |
Kim J H, Yi M J, Song Y, et al. Application of geophysical methods to the safety analysis of an earth dam[J]. Journal of Environmental and Engineering Geophysics, 2007, 12(2):221-235.
|
| [2] |
Bedrosian P A, Burton B L, Powers M H, et al. Geophysical investigations of geology and structure at the Martis Creek Dam,Truckee,California[J]. Journal of Applied Geophysics, 2012,77:7-20.
|
| [3] |
周建兵, 罗锐恒, 贺昌坤, 等. 文山小河尾水库岩溶含水渗漏通道的地球物理新证据[J]. 物探与化探, 2023, 47(3):707-717.
|
| [20] |
Sharma P V. Environmental and Engineering Geophysics[D]. Cambridge: Cambridge University Press,1997.
|
| [1] |
CHEN Yong-Ling, JIANG Shou-Jin, XIE Dan, WANG Jia, HE Zhi-Xiong, LIU Cheng. Application of comprehensive geophysical prospecting to groundwater exploration in Ritu County of the Ali area[J]. Geophysical and Geochemical Exploration, 2024, 48(3): 668-674. |
| [2] |
ZHAO Zi-Hao, LI Peng-Hui, LYU Hai-Jian, KANG Sen. An experimental study on the influence of step topographies in strip mines on the exploration performed using the high-density resistivity method[J]. Geophysical and Geochemical Exploration, 2024, 48(2): 565-572. |
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