Exploring for Wolfcamp Reservoirs, Eastern Shelf of the Permian Basin, USA, Using a Machine Learning Approach

Day 1 Mon, November 12, 2018 Pub Date : 2018-11-12 DOI:10.2118/193002-ms

B. D. Ribet, Peter K. H. Wang, M. Meers, H. Renick, R. Creath, R. McKee

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Abstract

The objective was to leverage prestack and poststack seismic data in order to reconstruct 3D images of thin, discontinuous, oil-filled packstone pay facies of the Upper and Lower Wolfcamp formation (Sakmarian time: 293-296 Ma). The well-to-seismic tie was carefully established using synthetic seismograms, which enabled the facies log to be properly associated with the corresponding seismic samples. The seismic data were all resampled from 2 ms to 0.5 ms in anticipation of being able to recover facies thicknesses on the order of 2 m. Six neural networks with diverse learning strategies were trained to recognize the nine facies classes in the high-resolution seismic stack: Instantaneous Frequency, Instantaneous Q Factor, Inversion (P-Impedance), Semblance, Dominant Frequency, Most Negative Curvature, and eight Angle Stacks, using a two-stage learning and voting process. At the wells, the nine facies were reconstructed from seismic at a 97% accuracy rate. The bootstrap classification rate, a proxy for blind well testing, was over 80%, which indicates a high-quality modeling process. The pay facies was described with no false positives or false negatives. In the 3D seismic volume between the wells, the procedure produced a Most Likely Facies volume (unsmoothed and smoothed), and nine individual Facies Probability volumes. The pay facies was visualized in a 3D voxel visualization canvas using opacity, and also in a two-way time thickness map. The usable vertical and horizontal resolution was much greater than that of the original seismic. Based on these classification results, additional drilling locations were chosen to further target the oil-filled packstones. The classification results were created by neural networks, which can be used as a substitute for traditional AVO, inversion and cross-plotting techniques for seismic reservoir characterization. The time need to create the Machine Learning results for this small dataset was on the order of ten minutes.

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使用机器学习方法勘探美国二叠纪盆地东部陆架Wolfcamp油藏

目的是利用叠前和叠后地震数据，重建Wolfcamp上下地层(Sakmarian时间:293-296 Ma)薄层、不连续、含油的包岩产层相的3D图像。利用合成地震图仔细地建立了井震联系，使相测井与相应的地震样品正确地联系起来。地震数据在2ms到0.5 ms之间进行了重新采样，预计能够恢复到2m级的相厚度。采用两阶段学习和投票过程，训练了6个具有不同学习策略的神经网络，以识别高分辨率地震叠加中的9个相类:瞬时频率、瞬时Q因子、反演(p -阻抗)、相似度、主导频率、最负曲率和8个角度叠加。在井中，对9个相进行了地震重建，准确率为97%。自举分类率(盲测的代表)超过80%，表明建模过程质量高。储层相描述无假阳性或假阴性。在井间的三维地震体积中，该程序生成了一个最可能相体积(未平滑和平滑)，以及9个单独的相概率体积。储层相使用不透明度和双向时间厚度图在3D体素可视化画布中可视化。可用的垂直和水平分辨率远高于原始地震的分辨率。根据这些分类结果，选择额外的钻井位置以进一步瞄准充油包岩。分类结果由神经网络生成，可替代传统的AVO、反演和交叉绘图技术进行地震储层表征。为这个小数据集创建机器学习结果所需的时间大约是十分钟。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Day 1 Mon, November 12, 2018

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