Production Forecasting Based on Attribute-Augmented Spatiotemporal Graph Convolutional Network for a Typical Carbonate Reservoir in the Middle East

Gao, Meng; Wei, Chenji; Zhao, Xibin; Huang, Ruijie; Yang, Jian; Li, Baozhu

doi:10.3390/en16010407

Cited by 4 publications

References 43 publications

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Shale Gas Production Forecasting with Well Interference Based on Spatial-Temporal Graph Convolutional Network

Xu,

Leung

2023

SPE Annual Technical Conference and Exhibition

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One of the core assumptions of most deep learning-based data-driven models is that samples are independent. However, this assumption poses a key challenge in production forecasting - performance is influenced by well interference and reservoir connectivity. Most shale gas wells are hydraulically fractured and exist in complex fracture systems, and the neighbouring well characteristics should also be considered when constructing data-driven forecast models. Researchers have explored using the Graph Convolutional Network (GCN) to address this issue by incorporating neighbouring well characteristics into production forecasting models. However, applying GCN to field-scale studies is problematic, as it requires training on a full batch, leading to gigantic cache allocation. Additionally, the transductive nature of GCN poses challenges for direct generalization to unseen nodes. To overcome these limitations, we adopt the Graph Sampling and Aggregation (GraphSAGE) network architecture, which allows training large graphs with mini-batches and generalizing predictions for previously unseen nodes. By cooperating with the Gated Recurrent Unit (GRU) network, the proposed Spatial-Temporal (ST)- GraphSAGE model can capture cross-time relationships between the target and the neighbouring wells and generate promising prediction time series for the target wells, even if they are newly drilled wells. The data set is based on field data corresponding to 2,240 Montney shale gas wells and consists of formation properties, fracture parameters, production history and operational data. The algorithm aggregates the first-hop information to the target node for each timestep. The Encoder-Decoder (ED) architecture is employed to generate forecasts for the subsequent three-year production rate by using the one-year production history of the wells. The trained model enables the evaluation of production predictions for newly developed wells at any location. We evaluate the model's performance using P10, P50, and P90 of the test dataset's Root Mean Square Error (RMSE). Our method preserves the topological characteristics of wells and generalizes the prediction to unseen nodes while significantly reducing training complexity, making it applicable to larger oil/gas fields. By incorporating information from adjacent wells and integrating spatial-temporal data, our ST-GraphSAGE model outperforms the traditional GRU-ED model and shows enhanced interpretability.

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Shale Gas Production Forecasting with Well Interference Based on Spatial-Temporal Graph Convolutional Network

Xu,

Leung

2023

SPE Annual Technical Conference and Exhibition

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Shale Gas Production Forecasting with Well Interference Based on Spatial-Temporal Graph Convolutional Network

Xu,

Leung

2024

SPE Journal

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Summary One of the core assumptions of most deep-learning-based data-driven models is that samples are independent. However, this assumption poses a key challenge in production forecasting—performance is influenced by well interference and reservoir connectivity. Most shale gas wells are hydraulically fractured and exist in complex fracture systems, and the neighboring well characteristics should also be considered when constructing data-driven forecast models. Researchers have explored using the graph convolutional network (GCN) to address this issue by incorporating neighboring well characteristics into production forecasting models. However, applying GCN to field-scale studies is problematic, as it requires training on a full batch, leading to gigantic cache allocation. In addition, the transductive nature of GCN poses challenges for direct generalization to unseen nodes. To overcome these limitations, we adopt the graph sampling and aggregation (GraphSAGE) network architecture, which allows training large graphs with batches and generalizing predictions for previously unseen nodes. By utilizing the gated recurrent unit (GRU) network, the proposed spatial-temporal (ST)-GraphSAGE model can capture cross-time relationships between the target and the neighboring wells and generate promising prediction time series for the target wells, even if they are newly drilled wells. The proposed approach is validated and tested using the field data from 2,240 Montney shale gas wells, including formation properties, hydraulic fracture parameters, production history, and operational data. The algorithm aggregates the first-hop information to the target node for each timestep. The encoder-decoder (ED) architecture is used to generate forecasts for the subsequent 3-year production rate by using the 1-year production history of the wells. The trained model enables the evaluation of production predictions for newly developed wells at any location. We evaluate the model’s performance using P10, P50, and P90 of the test data set’s root mean square error (RMSE). Our method preserves the topological characteristics of wells and generalizes the prediction to unseen nodes while significantly reducing training complexity, making it applicable to larger data sets. By incorporating information from adjacent wells and integrating ST data, our ST-GraphSAGE model outperforms the traditional GRU-ED model and shows enhanced interpretability.

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Graph-Level Feature Embedding with Spatial– Temporal GCN Method for Interconnected Well Production Forecasting

Xu,

Leung

2024

SPE Annual Technical Conference and Exhibition

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Deep-learning models have been employed for production forecasting in oil and gas reservoirs, but they often assume that each well operates independently, neglecting the connectivity and dynamic interactions between wells. This simplification can significantly compromise prediction accuracy. Therefore, graph convolutional networks (GCNs) have been applied to incorporate data from neighbouring wells. However, existing spatial-temporal GCN (ST-GCN) methods are mainly used for autoregressive tasks and face limitations in predicting newly developed wells and fully utilizing temporal neighbour interactions. This study introduces an ST-graph- level feature embedding (ST-GFE) method that provides accurate production forecasting for newly developed wells. It enhances forecasting by aggregating the historical data from neighbouring wells into a single feature vector. This aggregated vector, merging local and contextual information, contains richer information about the studied region. We evaluate ST-GFE using a dataset of 6,605 Montney shale gas wells, incorporating formation properties, fracture parameters, and production history. The ST-GFE is integrated with a non-autoregressive encoder-decoder structure to do production forecasting. The findings demonstrate that ST-GFE significantly improves prediction accuracy for newly developed wells compared to the purely temporal models, such as recurrent neural network (RNN)-based and Transformer models. ST-GFE adapts to production changes in adjacent wells, providing accurate predictions across various application scenarios, including shut-in and in-fill drilling activities. Additionally, while traditional GCNs require a full-batch training approach that leads to scalability issues, the ST-GFE model treats each well and its surrounding wells as a graph, enabling batch training and significantly reducing memory usage. Furthermore, the model dynamically updates its forecasts with real-time production data, enhancing precision and relevance. Experimental results confirm that ST-GFE effectively leverages spatio-temporal dynamics and interactions between adjacent wells, further improving production forecasting accuracy. This method enhances predictions and generalization capabilities for new developing locations, broadening its applicability to various drilling and production scenarios.

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Production Forecasting Based on Attribute-Augmented Spatiotemporal Graph Convolutional Network for a Typical Carbonate Reservoir in the Middle East

Cited by 4 publications

References 43 publications

Shale Gas Production Forecasting with Well Interference Based on Spatial-Temporal Graph Convolutional Network

Shale Gas Production Forecasting with Well Interference Based on Spatial-Temporal Graph Convolutional Network

Shale Gas Production Forecasting with Well Interference Based on Spatial-Temporal Graph Convolutional Network

Graph-Level Feature Embedding with Spatial– Temporal GCN Method for Interconnected Well Production Forecasting

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