|
|
REGION CONTROL METHOD APPLIED TO AIRBORNE ELECTROMAGNETIC DATA |
GUO Tao, KONG Xiang-li, WANG Zi-dong |
Jilin Communications Planning and Design Institute, Changchun 130021, China |
|
|
Abstract There are stripe errors in airborne electromagnetic data, which impart data quality. To remove this kind of errors, the general method is to separate the true field values and noise combining various window filters. Presently, the challenge for this method is the selection of window parameters and the problem that the data processors need more trails and errors to get appropriate parameters. In addition, the processing period is comparatively long. The region control method is put forward in this paper. Utilizing 2D-DDL (data dependent nonlinear) filters, the method takes the entire gridded airborne electromagnetic data matrix as a window, and obtains the background of the whole region. As the control points of entire region, the background of the whole region is used to adjust the local background obtained by small window 2D-DDNL filtering, which is called automatic window parameter adjustment. As a result, the local background is adjusted to suit the control point of the entire region background. The differences between the backgrounds and raw data are middle variables composed of local geological anomalies and stripe errors. The adapted median filter is used to separate stripe errors, and the leveling results finally come out. This method can automatically adjust the size of window, reduce the human interference, and preserve useful geological information comparatively.
|
Received: 24 February 2012
Published: 10 April 2013
|
|
|
|
|
[1] |
WU Yan-Min, PENG Zheng-Hui, YUAN Yong-Hu, ZHU Jin-Xiang, LIU Chuang, GE Wei, LING Guo-Ping. An EMI array sensor based on differential reception[J]. Geophysical and Geochemical Exploration, 2022, 46(1): 214-220. |
[2] |
PEI Xiao-Ming, FENG Guo-Rui, QI Ting-Ye. Physical simulation experiment for detecting water-filled goaf of coal mine under complex conditions bases on transient electromagnetic method[J]. Geophysical and Geochemical Exploration, 2021, 45(4): 1055-1063. |
|
|
|
|