{"title":"利用物理信息生成对抗网络建立三维多孔介质模型","authors":"Zihan Ren, Sanjay Srinivasan","doi":"arxiv-2409.11541","DOIUrl":null,"url":null,"abstract":"Micro-CT scanning of rocks significantly enhances our understanding of\npore-scale physics in porous media. With advancements in pore-scale simulation\nmethods, such as pore network models, it is now possible to accurately simulate\nmultiphase flow properties, including relative permeability, from CT-scanned\nrock samples. However, the limited number of CT-scanned samples and the\nchallenge of connecting pore-scale networks to field-scale rock properties\noften make it difficult to use pore-scale simulated properties in realistic\nfield-scale reservoir simulations. Deep learning approaches to create synthetic\n3D rock structures allow us to simulate variations in CT rock structures, which\ncan then be used to compute representative rock properties and flow functions.\nHowever, most current deep learning methods for 3D rock structure synthesis\ndon't consider rock properties derived from well observations, lacking a direct\nlink between pore-scale structures and field-scale data. We present a method to\nconstruct 3D rock structures constrained to observed rock properties using\ngenerative adversarial networks (GANs) with conditioning accomplished through a\ngradual Gaussian deformation process. We begin by pre-training a Wasserstein\nGAN to reconstruct 3D rock structures. Subsequently, we use a pore network\nmodel simulator to compute rock properties. The latent vectors for image\ngeneration in GAN are progressively altered using the Gaussian deformation\napproach to produce 3D rock structures constrained by well-derived conditioning\ndata. This GAN and Gaussian deformation approach enables high-resolution\nsynthetic image generation and reproduces user-defined rock properties such as\nporosity, permeability, and pore size distribution. Our research provides a\nnovel way to link GAN-generated models to field-derived quantities.","PeriodicalId":501289,"journal":{"name":"arXiv - EE - Image and Video Processing","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-09-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Using Physics Informed Generative Adversarial Networks to Model 3D porous media\",\"authors\":\"Zihan Ren, Sanjay Srinivasan\",\"doi\":\"arxiv-2409.11541\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Micro-CT scanning of rocks significantly enhances our understanding of\\npore-scale physics in porous media. With advancements in pore-scale simulation\\nmethods, such as pore network models, it is now possible to accurately simulate\\nmultiphase flow properties, including relative permeability, from CT-scanned\\nrock samples. However, the limited number of CT-scanned samples and the\\nchallenge of connecting pore-scale networks to field-scale rock properties\\noften make it difficult to use pore-scale simulated properties in realistic\\nfield-scale reservoir simulations. Deep learning approaches to create synthetic\\n3D rock structures allow us to simulate variations in CT rock structures, which\\ncan then be used to compute representative rock properties and flow functions.\\nHowever, most current deep learning methods for 3D rock structure synthesis\\ndon't consider rock properties derived from well observations, lacking a direct\\nlink between pore-scale structures and field-scale data. We present a method to\\nconstruct 3D rock structures constrained to observed rock properties using\\ngenerative adversarial networks (GANs) with conditioning accomplished through a\\ngradual Gaussian deformation process. We begin by pre-training a Wasserstein\\nGAN to reconstruct 3D rock structures. Subsequently, we use a pore network\\nmodel simulator to compute rock properties. The latent vectors for image\\ngeneration in GAN are progressively altered using the Gaussian deformation\\napproach to produce 3D rock structures constrained by well-derived conditioning\\ndata. This GAN and Gaussian deformation approach enables high-resolution\\nsynthetic image generation and reproduces user-defined rock properties such as\\nporosity, permeability, and pore size distribution. 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引用次数: 0
摘要
对岩石进行显微 CT 扫描极大地增强了我们对多孔介质孔隙尺度物理学的了解。随着孔隙尺度模拟方法(如孔隙网络模型)的进步,现在可以通过 CT 扫描岩石样本精确模拟多相流特性,包括相对渗透率。然而,由于 CT 扫描样本的数量有限,以及将孔隙尺度网络与油田尺度岩石属性连接起来的挑战,通常很难在现实油田尺度储层模拟中使用孔隙尺度模拟属性。然而,目前大多数用于三维岩石结构合成的深度学习方法并不考虑从油井观测中得出的岩石属性,孔隙尺度结构与油田尺度数据之间缺乏直接联系。我们提出了一种利用生成对抗网络(GANs)构建三维岩石结构的方法,该方法通过渐变高斯变形过程完成调节,并受制于观测到的岩石属性。我们首先对 WassersteinGAN 进行预训练,以重建三维岩石结构。随后,我们使用孔隙网络模型模拟器计算岩石属性。使用高斯变形方法逐步改变 GAN 中用于图像生成的潜向量,以生成受推导出的条件数据约束的三维岩石结构。这种 GAN 和高斯变形方法能够生成高分辨率的合成图像,并再现用户定义的岩石属性,如孔隙度、渗透性和孔径分布。我们的研究提供了一种将 GAN 生成的模型与现场数据联系起来的新方法。
Using Physics Informed Generative Adversarial Networks to Model 3D porous media
Micro-CT scanning of rocks significantly enhances our understanding of
pore-scale physics in porous media. With advancements in pore-scale simulation
methods, such as pore network models, it is now possible to accurately simulate
multiphase flow properties, including relative permeability, from CT-scanned
rock samples. However, the limited number of CT-scanned samples and the
challenge of connecting pore-scale networks to field-scale rock properties
often make it difficult to use pore-scale simulated properties in realistic
field-scale reservoir simulations. Deep learning approaches to create synthetic
3D rock structures allow us to simulate variations in CT rock structures, which
can then be used to compute representative rock properties and flow functions.
However, most current deep learning methods for 3D rock structure synthesis
don't consider rock properties derived from well observations, lacking a direct
link between pore-scale structures and field-scale data. We present a method to
construct 3D rock structures constrained to observed rock properties using
generative adversarial networks (GANs) with conditioning accomplished through a
gradual Gaussian deformation process. We begin by pre-training a Wasserstein
GAN to reconstruct 3D rock structures. Subsequently, we use a pore network
model simulator to compute rock properties. The latent vectors for image
generation in GAN are progressively altered using the Gaussian deformation
approach to produce 3D rock structures constrained by well-derived conditioning
data. This GAN and Gaussian deformation approach enables high-resolution
synthetic image generation and reproduces user-defined rock properties such as
porosity, permeability, and pore size distribution. Our research provides a
novel way to link GAN-generated models to field-derived quantities.