A novel method for determining the anisotropy of geophysical parameters: unit range variation increment (URVI)

Abstract
References
Similar articles

Download: PDF (688 KB) HTML ( KB) Export: BibTeX | EndNote (RIS) Supporting Info

Abstract Geometric anisotropy is commonly assumed in the investigation of the spatial variations of geophysical parameters. However, this assumption is not always satisfied in practice. We propose a novel method to determine the anisotropy of geophysical parameters. In the proposed method, the variograms are first normalized in all directions. Then, the normalized samples are fitted by the unit range variation increment (URVI) function to estimate the intensities of the variograms in each direction, from which the anisotropy can be finally determined. The performance of the proposed method is validated using InSAR atmospheric delay measurements over the Shanghai region. The results show that the deviation of the method is 6.4%, and that of the geometric anisotropy-based method is 21.2%. In addition, the computational efficiency of the new method is much higher. Subsequently, the URVI- and the geometric anisotropy-based methods are cross-validated in the cross-validation experiments by using Kriging interpolation. The results demonstrate that the structure functions generated with the proposed method are more accurate and can better reflect the spatial characteristics of the random field. Therefore, the proposed method, which is more accurate and efficient to determine the anisotropy than the conventional geometry anisotropy-based method, provides a better foundation to estimate the geophysical parameters of interest.

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	CAO Yun-Meng
	LI Zhi-Wei
	WEI Jian-Chao
	ZHAN Wen-Jun
	ZHU Jian-Jun
	WANG Chang-Cheng

Key words： Anisotropy semivariogram InSAR atmospheric delay kriging interpolation

Received: 2013-10-15;

Fund:

This research is sponsored jointly by the National Hi-tech Research and Development Program of China (No. 2012AA121301), National Basic Research Program of China (No. 2012CB719903), the National Natural Science Foundation of China (Nos. 41222027, 41474007, and 41404013), and Hunan Provincial Natural Science Foundation of China (No. 13JJ1006).

Cite this article:

CAO Yun-Meng,LI Zhi-Wei,WEI Jian-Chao et al. A novel method for determining the anisotropy of geophysical parameters: unit range variation increment (URVI)[J]. APPLIED GEOPHYSICS, 2014, 11(3): 340-349.

[1]	Chorti, A., Hristopulos, D. T., 2008, Nonparametric identification of anisotropic (Elliptic) correlations in spatially distributed data sets: IEEE Translations on Signal Processing, 56, 4738-4751.
[2]	Chilès, J. P., and Delfiner, P., 1999, Geostatistics: Modeling Spatial Uncertainty: A Wiley-Interscience Publication.
[3]	Delfiner, P., 1999, Geostatistics: modeling spatial uncertainty: A Wiley-Interscience Publication.
[4]	Ecker, M. D., and Gelfand, A. E., 1999, Bayesian modeling and inference for geometrically anisotropic spatial data: Math Geology, 32(1),67-82.
[5]	Elogne, S. N., Hristopulos, D. T., Varouchakis, E., 2008, An application of spartan spatial random fields in environmental mapping: Focus on automatic mapping capabilities: Stochastic Environmental Research Risk Assessment, 22(5), 633-646.
[6]	Gao, Y. and Teng, J. W., 2005, Studies on seismic anisotropy in the crust and mantle on Chinese mainland: Progress in Geophysics, 20(1),180-185.
[7]	Goovaerts, P., 1997, Geostatistics for Natural Resources Evaluation: Oxford University Press, London.
[8]	Hou, J. R., and Huang, J. X., 1982, Geostatistics and the application in mineral reserves: Geological Publishing House, Beijing.
[9]	Igúzquiza, E. P., 1998, Maximum likelihood estimation of spatial covariance Parameters: Math Geology, 30(1),95-108.
[10]	Jin, Y., Zheng, D. S., Pan, M., et al, 2011, 3D Geological Modeling of Anisotropic Mineralization and Its Application in Reserves Estimation: Acta Geological Sinica, 85(9), 1519-1527.
[11]	Journel, A. G., and Huijbregts, C. J., 1987, Mining Geostatistics: Academic Press, London
[12]	Jupp, D. L. B., Strahler, A. H., and Woodcock, C. E., 1998, Autocorrelation and regularization in digital images. I. Basic theory: Geoscience and Remote Sensing, 26(4), 463-473.
[13]	Kazuo, O., 2013, Recent Trend and Advance of Synthetic Aperture Radar with Selected Topics: Remote Sensing, 5(2), 716-807.
[14]	Kitanidis, P. K., 1983, Statistical estimation of polynomial generalized covariance functions and hydrologic applications: Water Resources Res, 19(2), 909-921.
[15]	Kitanidis, P. K., 1987, Parametric estimation of covariances of regionalized Variables: Water Resources Res, 23(4), 671-680.
[16]	Li, D. H., 2012, Anisotropic Wave field simulation and characteristic analysis of coal reservoirs: Ph. D. thesis, China University of Mining and Technology, Xuzhou.
[17]	Li, Z. W., 2005, Modeling atmospheric effects on repeat-pass InSAR measurements, Ph.D. thesis, The Hong Kong Polytechnic University, Hong Kong.
[18]	Li, Z. W., Xu, W. B., Feng, G. C., et al, 2012, Correcting atmospheric effects on InSAR with MERIS water vapor data and elevation-dependent interpolation model: Geophysical Journal International, 189, 898-910.
[19]	Li, Z. W., Ding, X. L., Huang, C., et al, 2007, Atmospheric effects on repeat-pass InSAR measurements over Shanghai region: Journal of Atmospheric and Solar-Terrestrial Physics, 69(12), 1344-1356.
[20]	Liao, M. S., and Lin, H., 2003, Synthetic aperture radar interferometry: principle and signal processing (in Chinese): Publishing House of Surveying and Mapping, Beijing.
[21]	Mateus, P., Nico, G., Tome, R., et al, 2013, Experimental Study on the Atmospheric Delay Based on GPS, SAR Interferometry, and Numerical Weather Model Data: IEEE Transactions on Geoscience and Remote Sensing, 51(1), 6-11.
[22]	Ouchi, K., 2013, Recent Trend and Advance of Synthetic aperture radar with selected topics: Remote Sensing, 5(2), 716-807.
[23]	Ramon, F. H., 2002, Radar interferometry data interpretation and error analysis: Kluwer Academic Publishers, Dordrecht.
[24]	Rose, P. A., Hensley, S., Joughin, I. R., et al., 2000, Synthetic aperture radar interferometry: Proceedings of the IEEE, 88(3), 333-382.
[25]	Swerling, P.,1962, Statistical properties of the contours of random surfaces: IRE Transactions on Information Theory, 8(4), 315-321.
[26]	Wackernagel, H., 1997, Multivariate geostatistics. Springer-Verlag, Berlin, Germany.
[27]	Wu, J., Gao, Y., Chen, Y. T., et al, 2007, Seismic anisotropy in the crust in northwestern capital area of China: Chinese Journal of Geophysics, 50(1), 209-220.
[28]	Zhang, H. Q., 1990, Principles and application of geostatistics: China University of Mining and Technology Press, Xuzhou.

[1]	. Seismic prediction method of multiscale fractured reservoir[J]. APPLIED GEOPHYSICS, 2018, 15(2): 240-252.
[2]	Guo Gui-Hong, Yan Jian-Ping, Zhang Zhi, José Badal, Cheng Jian-Wu, Shi Shuang-Hu, and Ma Ya-Wei. Numerical analysis of seismic wave propagation in fluid-saturated porous multifractured media[J]. APPLIED GEOPHYSICS, 2018, 15(2): 311-317.
[3]	Yan Li-Li, Cheng Bing-Jie, Xu Tian-Ji, Jiang Ying-Ying, Ma Zhao-Jun, Tang Jian-Ming. Study and application of PS-wave pre-stack migration in HTI media and an anisotropic correction method[J]. APPLIED GEOPHYSICS, 2018, 15(1): 57-68.
[4]	Wang Tao, Wang Kun-Peng, Tan Han-Dong. Forward modeling and inversion of tensor CSAMT in 3D anisotropic media[J]. APPLIED GEOPHYSICS, 2017, 14(4): 590-605.
[5]	Qian Ke-Ran, He Zhi-Liang, Chen Ye-Quan, Liu Xi-Wu, Li Xiang-Yang. Prediction of brittleness based on anisotropic rock physics model for kerogen-rich shale[J]. APPLIED GEOPHYSICS, 2017, 14(4): 463-480.
[6]	Huang Wei, Ben Fang, Yin Chang-Chun, Meng Qing-Min, Li Wen-Jie, Liao Gui-Xiang, Wu Shan, Xi Yong-Zai. Three-dimensional arbitrarily anisotropic modeling for time-domain airborne electromagnetic surveys[J]. APPLIED GEOPHYSICS, 2017, 14(3): 431-440.
[7]	Huang Xin, Yin Chang-Chun, Cao Xiao-Yue, Liu Yun-He, Zhang Bo, Cai Jing. 3D anisotropic modeling and identification for airborne EM systems based on the spectral-element method[J]. APPLIED GEOPHYSICS, 2017, 14(3): 419-430.
[8]	Su Ben-Yu and Yue Jian-Hua. Research of the electrical anisotropic characteristics of water-conducting fractured zones in coal seams[J]. APPLIED GEOPHYSICS, 2017, 14(2): 216-224.
[9]	Fang Gang, Ba Jing, Liu Xin-Xin, Zhu Kun, Liu Guo-Chang. Seismic wavefield modeling based on time-domain symplectic and Fourier finite-difference method[J]. APPLIED GEOPHYSICS, 2017, 14(2): 258-269.
[10]	Song Lian-Teng, Liu Zhong-Hua, Zhou Can-Can, Yu Jun, Xiu Li-Jun, Sun Zhong-Chun, Zhang Hai-Tao. Analysis of elastic anisotropy of tight sandstone and the influential factors[J]. APPLIED GEOPHYSICS, 2017, 14(1): 10-20.
[11]	Liu Xi-Wu, Guo Zhi-Qi, Liu Cai, Liu Yu-Wei. Anisotropy rock physics model for the Longmaxi shale gas reservoir, Sichuan Basin, China[J]. APPLIED GEOPHYSICS, 2017, 14(1): 21-30.
[12]	He Yi-Yuan, Hu Tian-Yue, He Chuan, Tan Yu-Yang. P-wave attenuation anisotropy in TI media and its application in fracture parameters inversion[J]. APPLIED GEOPHYSICS, 2016, 13(4): 649-657.
[13]	Sergey Yaskevich, Georgy Loginov, Anton Duchkov, Alexandr Serdukov. Pitfalls of microseismic data inversion in the case of strong anisotropy[J]. APPLIED GEOPHYSICS, 2016, 13(2): 326-332.
[14]	Guo Zhi-Qi, Liu Cai, Liu Xi-Wu, Dong Ning, and Liu Yu-Wei. Research on anisotropy of shale oil reservoir based on rock physics model[J]. APPLIED GEOPHYSICS, 2016, 13(2): 382-392.
[15]	Yin Chang-Chun, Zhang Ping, Cai Jing. Forward modeling of marine DC resistivity method for a layered anisotropic earth[J]. APPLIED GEOPHYSICS, 2016, 13(2): 279-287.