Physics Informed Machine Learning for Reservoir Connectivity Identification and Robust Production Forecasting

SPE Journal Pub Date : 2024-06-01 DOI:10.2118/219773-pa
Masahiro Nagao, A. Datta-Gupta, Tsubasa Onishi, S. Sankaran
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Abstract

Routine well-wise injection/production data contain significant information that can be used for closed-loop reservoir management and rapid field decision-making. Traditional physics-based numerical reservoir simulation can be computationally prohibitive for short-term decision cycles, and it requires a detailed geologic model. Reduced physics models provide an efficient simulator-free workflow but often have a limited range of applicability. Pure machine learning models lack physical interpretability and can have limited predictive power. To address these challenges, we propose hybrid models, combining machine learning and a physics-based approach, for rapid production forecasting and reservoir connectivity characterization using routine injection/production and pressure data. Our framework takes routine measurements, such as injection rate and pressure data, as inputs and multiphase production rates as outputs. We combine reduced physics models into a neural network architecture by utilizing two different approaches. In the first approach, the reduced physics model is used for preprocessing to obtain approximate solutions that feed it into a neural network as input. This physics-based input feature can reduce the model complexity and provide significant improvement in prediction performance. In the second approach, a physics-informed neural network (PINN) is applied. The residual terms are augmented in the neural network loss function as physics-based regularization that relies on the governing partial differential equations (PDE). Reduced physics models are used for the governing PDE to enable efficient neural network training. The regularization allows the model to avoid overfitting and provides better predictive performance. Our proposed hybrid models are first validated using a 2D benchmark reservoir simulation case and then applied to a field-scale reservoir case to show the robustness and efficiency of the method. The hybrid models are shown to provide prediction performance that is superior to pure machine learning models and reduced physics models in terms of multiphase production rates. Specifically, in the second method with PINN, the trained hybrid neural network model satisfies the reduced physics system, making it physically interpretable, and provides interwell connectivity in terms of well flux allocation. The flux allocation estimated from the hybrid model was compared with streamline-based flux allocation, and reasonable agreement was obtained. By combining the reduced physics model with the efficacy of deep learning, model calibration can be done very efficiently without constructing a geologic model. The proposed hybrid models with physics-based regularization and physics-based preprocessing provide novel approaches to augment data-driven models with underlying physics to build interpretable models for understanding reservoir connectivity between wells and for robust future production forecasting.
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用于储层连通性识别和稳健生产预测的物理信息机器学习
常规的油井注采数据包含大量信息,可用于闭环油藏管理和快速油田决策。对于短期决策周期而言,传统的基于物理的数值油藏模拟在计算上可能过于昂贵,而且需要详细的地质模型。简化物理模型可提供高效的无模拟器工作流程,但适用范围往往有限。纯粹的机器学习模型缺乏物理可解释性,预测能力有限。为了应对这些挑战,我们提出了混合模型,结合机器学习和基于物理的方法,利用常规注水/生产和压力数据进行快速生产预测和储层连通性表征。我们的框架将常规测量数据(如注入率和压力数据)作为输入,将多相生产率作为输出。我们通过两种不同的方法将还原物理模型与神经网络架构相结合。在第一种方法中,简化物理模型用于预处理,以获得近似解,并将其作为输入输入到神经网络中。这种基于物理的输入特征可以降低模型的复杂性,并显著提高预测性能。第二种方法采用物理信息神经网络(PINN)。在神经网络损失函数中增加残差项,作为基于物理的正则化,该正则化依赖于支配偏微分方程(PDE)。为实现高效的神经网络训练,对支配偏微分方程使用了还原物理模型。正则化使模型避免过度拟合,并提供更好的预测性能。我们提出的混合模型首先通过二维基准储层模拟案例进行验证,然后应用于现场规模的储层案例,以显示该方法的鲁棒性和效率。结果表明,就多相生产率而言,混合模型的预测性能优于纯机器学习模型和简化物理模型。具体来说,在使用 PINN 的第二种方法中,经过训练的混合神经网络模型满足还原物理系统的要求,使其在物理上可以解释,并在油井流量分配方面提供井间连通性。将混合模型估算出的通量分配与基于流线的通量分配进行了比较,得到了合理的一致。通过将简化物理模型与深度学习的功效相结合,无需构建地质模型即可非常高效地完成模型校准。所提出的混合模型具有基于物理的正则化和基于物理的预处理功能,提供了新的方法来利用底层物理增强数据驱动模型,从而建立可解释的模型,用于理解井间储层的连通性,并进行稳健的未来产量预测。
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