Qamar Yasin, Yan Ding, Qizhen Du, Hung Vo Thanh, Bo Liu
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This study employed four supervised machine learning techniques (multilayer perceptron (MLP), random forests (RF), extreme gradient boosting (XGBoost), and support vector regression (SVR)) to identify fractures in geothermal carbonate reservoirs in the sub-basins of East China. The models were trained and tested on a diverse well-logging dataset collected at the field scale. A comparison of the predicted results revealed that XGBoost with optimized hyperparameters and data division achieved the best performance than RF, MLP, and SVR with RMSE = 0.02 and R<sup>2</sup> = 0.92. The Q-learning algorithm outperformed grid search, Bayesian, and ant colony optimizations. The blind well test demonstrates that it is possible to accurately identify fractures by applying machine learning algorithms to standard well logs. 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引用次数: 0
摘要
地热能源是一种可持续能源,可满足化石燃料燃烧造成的气候危机和全球变暖的需求。地热资源分布在复杂的地质环境中,断层和相互连接的断裂网络是流体循环的通道。识别断层和裂缝是开发地热资源的重要组成部分。然而,在没有高分辨率地球物理测井记录(如图像测井记录)和井心样本的情况下,准确预测裂缝具有挑战性。机器学习等软计算技术使绘制分辨率更高的断裂网络图成为可能。本研究采用了四种有监督的机器学习技术(多层感知器(MLP)、随机森林(RF)、极梯度提升(XGBoost)和支持向量回归(SVR))来识别华东分盆地地热碳酸盐岩储层中的裂缝。这些模型在现场采集的各种测井数据集上进行了训练和测试。对预测结果进行比较后发现,与 RF、MLP 和 SVR 相比,优化了超参数和数据分割的 XGBoost 性能最佳,RMSE = 0.02,R2 = 0.92。Q-learning 算法的性能优于网格搜索、贝叶斯和蚁群优化。盲井测试表明,在标准测井记录中应用机器学习算法可以准确识别裂缝。此外,对比分析表明,XGBoost 能够处理输入参数(如 DTP > RD > DEN > GR > CAL > RS > U > CNL)与地质复杂的地热碳酸盐岩储层裂缝之间的复杂关系。此外,XGBoost 模型与之前的研究相比,在训练和测试方面都更胜一筹。这项研究表明,基于 Q-learning 优化超参数和数据划分的 XGBoost 是一种合适的算法,可用于利用井记录数据识别断裂,以探索碳酸盐岩中的复杂地热系统。
Fault and fracture network characterization using soft computing techniques: application to geologically complex and deeply-buried geothermal reservoirs
Geothermal energy is a sustainable energy source that meets the needs of the climate crisis and global warming caused by fossil fuel burning. Geothermal resources are found in complex geological settings, with faults and interconnected networks of fractures acting as pathways for fluid circulation. Identifying faults and fractures is an essential component of exploiting geothermal resources. However, accurately predicting fractures without high-resolution geophysical logs (e.g., image logs) and well-core samples is challenging. Soft computing techniques, such as machine learning, make it possible to map fracture networks at a finer resolution. This study employed four supervised machine learning techniques (multilayer perceptron (MLP), random forests (RF), extreme gradient boosting (XGBoost), and support vector regression (SVR)) to identify fractures in geothermal carbonate reservoirs in the sub-basins of East China. The models were trained and tested on a diverse well-logging dataset collected at the field scale. A comparison of the predicted results revealed that XGBoost with optimized hyperparameters and data division achieved the best performance than RF, MLP, and SVR with RMSE = 0.02 and R2 = 0.92. The Q-learning algorithm outperformed grid search, Bayesian, and ant colony optimizations. The blind well test demonstrates that it is possible to accurately identify fractures by applying machine learning algorithms to standard well logs. In addition, the comparative analysis indicates that XGBoost was able to handle the complex relationship between input parameters (e.g., DTP > RD > DEN > GR > CAL > RS > U > CNL) and fracture in geologically complex geothermal carbonate reservoirs. Furthermore, comparing the XGBoost model with previous studies proved superior in training and testing. This study suggests that XGBoost with Q-learning-based optimized hyperparameters and data division is a suitable algorithm for identifying fractures using well-log data to explore complex geothermal systems in carbonate rocks.
期刊介绍:
This journal offers original research, new developments, and case studies in geomechanics and geophysics, focused on energy and resources in Earth’s subsurface. Covers theory, experimental results, numerical methods, modeling, engineering, technology and more.
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