Least-squares reverse-time migration (LSRTM) provides image of reflectivity with high resolution and compensated amplitude, but the computational cost is extremely high. One way to improve efficiency is to encode all of shot gathers into one or several super-shot gathers with designed encoding functions so as to solve a smaller number of wave-equations at each iteration. Another way is to use different kinds of preconditioners to accelerate the convergent rate of iterations. In this abstract, we combine these two methods together and extend them into prestack imaging, which we call extended reverse-time migration (ERTM). The sparsity of reflectivity is used as prior information and preconditioning guided gradient (PGG) method is developed to suppress crosstalk introduced by phase encoding and improve resolution of the extended image in the subsurface offset domain. Numerical tests on SEG/EAGE salt model show that our proposed method can provide a more reliable extended image with almost the same cost of ERTM, which makes the method valuable in migration velocity analysis and AVO/AVA analysis.
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机译:最小二乘反面迁移(LSRTM)提供具有高分辨率和补偿幅度的反射率的图像,但计算成本非常高。提高效率的一种方法是将所有镜头编码成一个或多个超级射击聚集,具有设计的编码功能,以便在每个迭代中求解较少数量的波浪方程。另一种方法是使用不同种类的预处理器来加速迭代的收敛速度。在此摘要中,我们将这两种方法组合在一起,并将它们扩展为Prestack成像,我们调用扩展的反向时间迁移(ERTM)。反射率的稀疏性用作先前信息,并且开发了预处理引导梯度(PGG)方法以抑制由相位编码引入的串扰,并改善了地下偏移域中的扩展图像的分辨率。 SEG / EAGE SATE模型的数值测试表明,我们所提出的方法可以提供更可靠的扩展图像,具有几乎相同的ERTM成本,这使得该方法在迁移速度分析和AVO / AVA分析中有价值。
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