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地球物理学报 2014

频率域航空电磁数据的加权横向约束反演

DOI: 10.6038/cjg20140324, PP. 953-960

蔡晶,齐彦福,殷长春

Keywords: 航空电磁,频率域,正演,横向加权约束反演

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Abstract:

传统的一维反演技术已经被广泛应用于航空电磁数据解释中.然而，利用单点水平层状介质模型模拟地下复杂地电结构有时会遇到困难.突出表现在反演参数的横向不连续性，即使相邻测点的反演结果也会出现突变.本文针对航空电磁直升机吊舱系统可进行密集采样，相邻测点地下电性结构应具有某种程度连续性的特点，研究航空电磁数据横向约束反演理论，并提出参数加权约束方法.首先阐述频率域航空电磁正演和加权横向约束反演理论，着重介绍这种拟二维反演方法的基本原理和实施步骤，以及将该方法成功应用于频率域航空电磁数据反演处理的方法技术.最后，通过对理论和实测数据反演处理，并与传统的一维反演结果进行对比，验证加权横向约束反演方法的有效性.

References

[1]	Lei D, Hu X Y, Zhang S F. 2006. Development status of Airborne Electromagnetic. Contributions to Geology and Mineral Resources Research, 21(1): 40-44, 53.
[2]	Macnae, J, Smith R, Polzer B, et al. 1991. Conductivity-depth imaging of airborne electromagnetic step-response data. Geophysics, 56(1): 102-114.
[3]	Auken E, Christiansen A V. 2004. Layered and laterally constrained 2D inversion of resistivity data. Geophysics, 69(3): 752-761.
[4]	Auken E, Christiansen A V, Jacobsen Bo H, et al. 2005. Piecewise 1D laterally constrained inversion of resistivity data. Geophysics, 53(4): 497-506.
[5]	Auken E, Christiansen A V, Jacobsen L H, et al. 2008. A resolution study of buried valleys using Laterally constrained inversion of TEM data. Journal of Applied Geophysics, 65(1): 10-20, doi: 10.1016/j.jappgeo.2008.03.003.
[6]	Auken E, Srensen K I, Thomsen P. 2000. Lateral constrained inversion (LCI) of profile oriented data—the resistivity case. Proceedings of the EEGS-ES, Bochum, Germany, EL06.
[7]	Christiansen A V, Auken E. 2004. Optimizing a layered and laterally constrained 2D inversion of resistivity data using Broyden''s update and 1D derivatives. Journal of Applied Geophysics, 56(4): 247-261, doi: 10.1016/j.jappgeo.2004.07.004.
[8]	Constable S C, Parker R L, Constable C G. 1987. Occam''s inversion: A practical algorithm for generating smooth models from electromagnetic sounding data. Geophysics, 52(3): 289-300.
[9]	Huang H P, Fraser D C. 1996. The differential parameter method for multifrequency airborne resistivity mapping. Geophysics, 61(1): 100-109.
[10]	Santos F A M. 2004. 1-D laterally constrained inversion of EM34 profiling data. Journal of Applied Geophysics, 56(2): 123-134, doi:10.1016/j.jappgeo.2004.04005.
[11]	Sengpiel K P. 1988. Approximate inversion of airborne EM data from a multilayered ground. Geophysical Prospecting, 36(4): 446-459.
[12]	Siemon B, Auken E, Christiansen A V. 2009. Laterally constrained inversion of helicopter-borne frequency-domain electromagnetic data. Journal of Applied Geophysics, 67(3): 259-268, doi: 10.1016/j.jappgeo.2007.11.003.
[13]	Triantafilis J, Santos F A M. 2010. Resolving the spatial distribution of the true electrical conductivity with depth using EM38 and EM31 signal data and a laterally constrained inversion model. Australian Journal of Soil Research, 48(5): 434-446, doi:10.1071/SR09149.
[14]	Wang W P. 2011. Application and Prospect of the Research about Frequency Domain Airborne Electromagnetic Method. Twenty-seventh Annual Meeting Proceedings of the Chinese Geophysical Society, 675-676.
[15]	Yin C C. 2000. Geoelectrical inversion for a one-dimensional anisotropic model and inherent non-uniqueness. Geophys. J. Int., 140(1): 11-23.
[16]	Yin C C, Hodges G. 2007. Simulated annealing for airborne EMinversion. Geophysics, 72(4): F189-F196.
[17]	Zhou D Q, Tan L, Tan H D, et al. 2010. Inversion of frequency domain helicopter-borne electromagnetic data with Marquardt''s method. Chinese J. Geophys. (in Chinese), 53(2): 421-427, doi: 10.3969/j.issn.0001-5733.2010.02.020.

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