Abstract
Faults represent important analytical targets for the identification of perceptual ground motions and associated seismic hazards. In particular, during oil production, important data such as the path and flow rate of fluid flows can be obtained from information on fault location and their connectivity. Seismic attributes are conventional methods used for fault detection, whereby information obtained from seismic data are analyzed using various property processing methods. The analyzed data eventually provide information on fault properties and imaging of fault surfaces. In this study, we propose an efficient workflow for fault detection and extraction of requisite information to construct a fault surface model using 3D seismic cubes. This workflow not only improves the ability to detect faults but also distinguishes the edges of a fault more clearly, even with the application of fewer attributes compared to conventional workflows. Thus, the computing time of attribute processing is reduced, and fault surface cubes are generated more rapidly. In addition, the reduction in input variables reduces the effect of the interpreter’s subjective intervention on the results. Furthermore, the clustering method can be applied to the azimuth and dip of the fault to be extracted from the complexly intertwined fault faces and subsequently imaged. The application of the proposed workflow to field data obtained from the Vincentian oil field in Australia resulted in a significant reduction in noise compared to conventional methods. It also led to clearer and continuous edge detection and extraction.
Highlights
Fractures are formed when the magnitude of stress exceeds the strength of a rock, thereby causing the rock to diverge in a particular direction
We proposed an improved fault detection workflow consisting of directional edge detection, summation, and edge enhancement
Compared to the conventional fault detection workflow using seismic attributes, the proposed method is less cumbersome for controlling the parameters and does not require the selection of seismic attributes based
Summary
Fractures are formed when the magnitude of stress exceeds the strength of a rock, thereby causing the rock to diverge in a particular direction. Amplitude images are primarily used, which are apto fault detection through various attributes. A widely used method based on seismic attributes consists of the following parts: conditioning, edge detection, and edge enhancement. We propose an effective workflow for fault detection and extraction to. We propose an effective workflow for fault detection and extraction to construct a fault surface model. The workflow proposed in this paper consists of directional edge detection and edge enhancement. The amplitude amplitudecontrast contrastattribute attribute was applied basis of the direction in which the edges are to be detected within the cube. Workflow proposed proposedininthis thisstudy studyfor forfault fault detection consists of directional edge detection, summation, and edge enhancement. Time is reduced due to the application of reduced attributes
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