A study of perfectly matched layers for joint multi-component reverse-time migration

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Abstract Reverse-time migration in finite space requires effective boundary processing technology to eliminate the artificial truncation boundary effect in the migration result. On the basis of the elastic velocity-stress equations in vertical transversely isotropic media and the idea of the conventional split perfectly matched layer (PML), the PML wave equations in reverse-time migration are derived in this paper and then the high order staggered grid discrete schemes are subsequently given. Aiming at the “reflections” from the boundary to the computational domain, as well as the effect of seismic event’s abrupt changes at the two ends of the seismic array, the PML arrangement in reverse-time migration is given. The synthetic and real elastic, prestack, multi-component, reverse-time depth migration results demonstrate that this method has much better absorbing effects than other methods and the joint migration produces good imaging results.

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	DU Qi-Zhen
	SUN Rui-Yan
	QIN Tong
	ZHU Yi-Tong
	BI Li-Fei

Key words： perfectly matched layer (PML) absorbing boundary reverse-time migration velocity-stress equation multi-component

Received: 2009-12-31;

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This work is supported by the 863 Program (Grant No. 2006AA06Z202), Open Fund of the Key Laboratory of Geophysical Exploration of CNPC (Grant No. GPKL0802), CNPC Young Innovation Fund (Grant No. 05E7028), and the Program for New Century Excellent Talents in University (Grant No. NCET-07-0845).

Cite this article:

DU Qi-Zhen,SUN Rui-Yan,QIN Tong et al. A study of perfectly matched layers for joint multi-component reverse-time migration[J]. APPLIED GEOPHYSICS, 2010, 7(2): 166-173.

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