Numerical Solution of the Problem of Detecting Diffractors in a Complex Acoustic Media

机译：复杂声学介质中衍射器检测衍射器的数值解

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One of the most effective methods for detecting weak scattering objects (diffractors) associated with cracked-cavernous hydrocarbon reservoirs is the CSP (Common Scattering Point) method [1]. This method is the most effective for weakly inhomogeneous media. The CSP method can be supplemented by a preliminary continuation of the wave field to a certain depth for strongly inhomogeneous medium. In this paper we use Reverse Time Datuming (RTD) procedure for this purpose [2, 3, 4]. The new CSPRTD method is based on both CSP and RTD methods for determining deep-seated diffractors in complex acoustic medium. The results of numerical studies of CSP-RTD method for a complex acoustic model is presented. The comparison of CSP-RTD method and RTM method is also presented.

机译：检测与裂纹碳氢化合物储存器相关的弱散射物体（衍射器）的最有效方法之一是CSP（常见散射点）方法[1]。这种方法对于弱不均匀介质最有效。 CSP方法可以通过波场的初步延续来补充，对于强不均匀介质，波场的初步延续延续至一定深度。在本文中，我们使用反向时间基本（RTD）程序[2,3,4]。新的CSPRTD方法基于CSP和RTD方法，用于确定复杂声介质中的深层衍射器。介绍了复杂声学模型CSP-RTD方法的数值研究结果。还提出了CSP-RTD方法和RTM方法的比较。

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《International Conference on Mathematical Modeling》|2017年|1 v. (various pagings) :|共5页
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Alexander N. Danilin; Leonid N. Pestov;
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中图分类 O411.1-532;
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effective; weakly inhomogeneous; also presented;

机译：有效;弱不均匀;也提出了;

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Numerical Solution of the Problem of Detecting Diffractors in a Complex Acoustic Media

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