47 research outputs found
Neural networks in geophysical applications
Neural networks are increasingly popular in geophysics.
Because they are universal approximators, these
tools can approximate any continuous function with an
arbitrary precision. Hence, they may yield important
contributions to finding solutions to a variety of geophysical applications.
However, knowledge of many methods and techniques
recently developed to increase the performance
and to facilitate the use of neural networks does not seem
to be widespread in the geophysical community. Therefore,
the power of these tools has not yet been explored to
their full extent. In this paper, techniques are described
for faster training, better overall performance, i.e., generalization,and the automatic estimation of network size
and architecture
Automatic Stack Velocity Picking Using an Unsupervised Ensemble Learning Method
Seismic velocity picking algorithms that are both accurate and efficient can
greatly speed up seismic data processing, with the primary approach being the
use of velocity spectra. Despite the development of some supervised deep
learning-based approaches to automatically pick the velocity, they often come
with costly manual labeling expenses or lack interpretability. In comparison,
using physical knowledge to drive unsupervised learning techniques has the
potential to solve this problem in an efficient manner. We suggest an
Unsupervised Ensemble Learning (UEL) approach to achieving a balance between
reliance on labeled data and picking accuracy, with the aim of determining the
stack velocity. UEL makes use of the data from nearby velocity spectra and
other known sources to help pick efficient and reasonable velocity points,
which are acquired through a clustering technique. Testing on both the
synthetic and field data sets shows that UEL is more reliable and precise in
auto-picking than traditional clustering-based techniques and the widely used
Convolutional Neural Network (CNN) method
Estimation Of Reservoir Properties From Seismic Data By Smooth Neural Networks
Traditional joint inversion methods reqnire an a priori prescribed operator that links the reservoir properties to the observed seismic response. The methods also rely on a linearized approach to the solution that makes them heavily dependent on the selection of
the starting model. Neural networks provide a useful alternative that is inherently nonlinear and completely data-driven, but the performance of traditional back-propagation
networks in production settings has been inconsistent due to the extensive parameter
tweaking needed to achieve satisfactory results and to avoid overfitting the data. In
addition, the accuracy of these traditional networks is sensitive to network parameters,
such as the network size and training length. We present an approach to estimate the
point-values of the reservoir rock properties (such as porosity) from seismic and well
log data through the use of regularized back propagation and radial basis networks.
Both types of networks have inherent smoothness characteristics that alleviate the nonmonotonous generalization problem associated with traditional networks and help to
avert overfitting the data. The approach we present therefore avoids the drawbacks of
both the joint inversion methods and traditional back-propagation networks. Specifically,
it is inherently nonlinear, requires no a priori operator or initial model, and is not
prone to overfitting problems, thus requiring no extensive parameter experimentation.Massachusetts Institute of Technology. Borehole Acoustics and Logging ConsortiumMassachusetts Institute of Technology. Earth Resources Laboratory. Reservoir Delineation
ConsortiumSaudi Aramc
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Automatic channel detection using deep learning
Picking 3D channel geobodies in seismic volumes is an important objective in seismic interpretation for hydrocarbon exploration. Manual detection of channel geobodies is a time-consuming and subjective process. The interpreter can calculate different seismic attributes such as coherence to aid for manual detection of channel geobodies in seismic volumes. However, these attributes still do not directly identify 3D channel geobodies.
Machine learning and deep learning are data-driven techniques that have been getting more attention recently in different fields, such as medical imaging and computer vision. With large volumes of available data in different types and a development of powerful computational resources, geophysics is a promising field for applying machine learning and deep learning. Many seismic interpretation steps are analogous to different problems in computer vision that have been solved successfully using deep learning. Channel detection in seismic volumes is analogous to segmentation problems for images. Applying deep learning to seismic interpretations, specifically to automatic channel detection in 3D seismic volumes, can make the process faster and the workflow less subjective. Decision-making based on interpretations is uncertain; so uncertainties in interpretation results are very important. Deep learning with different algorithms can also help interpreters quantify this uncertainty.Geological Science
Intelligent data-driven decision-making to mitigate or stop lost circulation
âLost circulation is a challenging problem in the oil and gas industry. Each year, millions of dollars are spent to mitigate or stop this problem. The aim of this work is to utilize machine learning and other intelligent solutions to help to make better decision to mitigate or stop lost circulation. A detailed literature review on the applications of decision tree analysis, expected monetary value, and artificial neural networks in the oil and gas industry was provided. Data for more than 3000 wells were gathered from many sources around the world. Detailed economics and probability analyses for lost circulation treatmentsâ strategies were conducted for three formations in southern Iraq which are the Dammam, Hartha, and Shuaiba formations.
Multiple machine learning methods such as support vector machine, decision trees, logistic regression, artificial neural networks, and ensemble trees were used to create models that can predict lost circulation and recommend the best lost circulation treatment based on the type of loss and reason of loss. The results showed that the created models can predict lost circulation and recommend the best lost circulation strategy within a reasonable margin of error. The created models can be used globally which avoids the shortcoming in the literature. Intelligence solutions and machine learning have proven their applicability to solve complicated problems and make better future decisions. With the large data available in the oil and gas industry, these methods can help the decision-makers to make better future decisions that will save time and moneyâ--Abstract, page iv
PhaseLink: A Deep Learning Approach to Seismic Phase Association
Seismic phase association is a fundamental task in seismology that pertains to linking together phase detections on different sensors that originate from a common earthquake. It is widely employed to detect earthquakes on permanent and temporary seismic networks and underlies most seismicity catalogs produced around the world. This task can be challenging because the number of sources is unknown, events frequently overlap in time, or can occur simultaneously in different parts of a network. We present PhaseLink, a framework based on recent advances in deep learning for gridâfree earthquake phase association. Our approach learns to link phases together that share a common origin and is trained entirely on millions of synthetic sequences of P and S wave arrival times generated using a 1âD velocity model. Our approach is simple to implement for any tectonic regime, suitable for realâtime processing, and can naturally incorporate errors in arrival time picks. Rather than tuning a set of ad hoc hyperparameters to improve performance, PhaseLink can be improved by simply adding examples of problematic cases to the training data set. We demonstrate the stateâofâtheâart performance of PhaseLink on a challenging sequence from southern California and synthesized sequences from Japan designed to test the point at which the method fails. For the examined data sets, PhaseLink can precisely associate phases to events that occur only âŒ12 s apart in origin time. This approach is expected to improve the resolution of seismicity catalogs, add stability to realâtime seismic monitoring, and streamline automated processing of large seismic data sets