Full Waveform Inversion for the Near Surface Characterization, Onshore UAE, Case Study

R. Dixit, P. Vasilyev, I. Mihaljević, M. Tham, D. Vígh, A. Zarkhidze, G. Cambois, M. Mahgoub
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Abstract

Full-waveform inversion (FWI) has become a well-established method for obtaining a detailed earth model suitable for improved imaging, near-surface characterization and pore-pressure prediction. FWI for onshore data has always been challenging and has seen limited application (Vigh et al, 2018). It requires a dedicated data processing approach related to the lower signal-to-noise ratio, accounting for variable topography and complex near-surface related effects. During the past few years, ADNOC has been acquiring and processing one of the world's largest combined 3D onshore and offshore seismic surveys in the Emirate of Abu Dhabi. The modern acquisition parameters that were implemented enabled the acquisition of broadband onshore seismic data rich in low frequencies that could benefit the initial stages of the FWI workflow. Sand dunes and sabkha layers at the surface, and high-velocity carbonate and dolomite layers in the subsurface pose a significant challenge for near-surface modeling in the UAE. The purpose of this work is to evaluate FWI application onshore UAE for near-surface characterization. We will compare the FWI results with conventional approaches for the near-surface model building that has been used routinely on land datasets in UAE, such as data-driven image-based statics (DIBS, Zarubov et al, 2019). One of the main challenges is data preconditioning, as onshore seismic data typically exhibits high levels of noise. It is imperative to denoise gathers sufficiently prior to the FWI process. A well sonic velocity function with large smoothing was used to build the starting velocity model for FWI. The process aims to minimize the least-squared difference between predicted and observed seismic responses by means of updating the model on which the prediction is based. As the predicted and seismic responses are functions of model parameters as well as source signature, a good estimate of the source wavelet is important for update and convergence in FWI. During this FWI work, source wavelet inversion was done as a separate step and used in subsequent FWI passes. FWI inversion started with adjustive FWI (Kun et al, 2015) on lower frequencies, moving to higher frequencies where both adjustive and least square objective functions were used. We will further show assessment of the anisotropy, initial conditions, usage of geological constraints, and comparisons to the conventional solutions. A comparison of results shows that FWI has successfully added velocity details to the near-surface model that follow the geological trend and conforms to well information while producing a plausible static solution. We have demonstrated the application of FWI onshore UAE for near-surface modeling. Although turnaround time (TAT) has increased compared to the conventional approach, the learning that was gained during this trial will decrease TAT for the future FWI work.
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近地表特征全波形反演,阿联酋陆上,案例研究
全波形反演(FWI)已成为一种获得详细地球模型的成熟方法,适用于改进成像、近地表表征和孔隙压力预测。陆上数据的FWI一直具有挑战性,并且应用有限(Vigh等人,2018)。它需要一种与较低信噪比相关的专用数据处理方法,考虑到多变的地形和复杂的近地表相关影响。在过去的几年中,ADNOC一直在阿布扎比酋长国收购和处理世界上最大的陆上和海上三维地震调查之一。采用现代采集参数,可以采集丰富的低频宽带陆上地震数据,有利于FWI工作流程的初始阶段。在阿联酋,地表的沙丘和sabkha层以及地下的高速碳酸盐和白云岩层对近地表建模构成了重大挑战。这项工作的目的是评估FWI在阿联酋陆上近地面的应用。我们将比较FWI结果与阿联酋陆地数据集常规使用的近地表模型构建的传统方法,如数据驱动的基于图像的静态(DIBS, Zarubov等,2019)。其中一个主要的挑战是数据预处理,因为陆上地震数据通常显示出高水平的噪声。在FWI处理之前,必须对采集信号进行充分的降噪。采用平滑度较大的声速函数建立了FWI启动速度模型。该过程旨在通过更新预测所依据的模型,使预测和观测地震反应之间的最小二乘差最小化。由于预测响应和地震响应是模型参数和震源特征的函数,因此良好的震源小波估计对FWI的更新和收敛具有重要意义。在FWI工作中,源小波反演作为一个单独的步骤进行,并用于后续的FWI工作。FWI反演从较低频率的可调FWI (Kun et al ., 2015)开始,移动到使用可调和最小二乘目标函数的较高频率。我们将进一步展示各向异性的评估、初始条件、地质约束的使用,以及与常规解决方案的比较。对比结果表明,FWI成功地将速度细节添加到近地表模型中,该模型遵循地质趋势,符合井信息,同时产生了合理的静态解决方案。我们已经展示了FWI在阿联酋陆上近地面建模中的应用。虽然与传统方法相比,周转时间(TAT)增加了,但在本次试验中获得的经验将减少未来FWI工作的TAT。
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