A texture-based region growing algorithm for volume extraction in seismic data

M. G. Orozco-del-Castillo; M. Cárdenas-Soto; C. Ortiz-Alemán; C. Couder-Castañeda; J. Urrutia-Fucugauchi; A. Trujillo-Alcántara

doi:10.1111/1365-2478.12381

A texture-based region growing algorithm for volume extraction in seismic data

M. G. Orozco-del-Castillo, M. Cárdenas-Soto, C. Ortiz-Alemán, C. Couder-Castañeda, J. Urrutia-Fucugauchi, A. Trujillo-Alcántara

Centro de Desarrollo Aeroespacial (CDA)

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

6 Citas (Scopus)

Resumen

We present a novel approach to automated volume extraction in seismic data and apply it to the detection of allochthonous salt bodies. Using a genetic algorithm, we determine the optimal size of volume elements that statistically, according to the U-test, best characterize the contrast between the textures inside and outside of the salt bodies through a principal component analysis approach. This information was used to implement a seeded region growing algorithm to directly extract the bodies from the cube of seismic amplitudes. We present the resulting three-dimensional bodies and compare our final results to those of an interpreter, showing encouraging results.

Idioma original	Inglés
Páginas (desde-hasta)	97-105
Número de páginas	9
Publicación	Geophysical Prospecting
Volumen	65
N.º	1
DOI	https://doi.org/10.1111/1365-2478.12381
Estado	Publicada - 1 ene. 2017

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abstract = "We present a novel approach to automated volume extraction in seismic data and apply it to the detection of allochthonous salt bodies. Using a genetic algorithm, we determine the optimal size of volume elements that statistically, according to the U-test, best characterize the contrast between the textures inside and outside of the salt bodies through a principal component analysis approach. This information was used to implement a seeded region growing algorithm to directly extract the bodies from the cube of seismic amplitudes. We present the resulting three-dimensional bodies and compare our final results to those of an interpreter, showing encouraging results.",

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AU - Orozco-del-Castillo, M. G.

AU - Cárdenas-Soto, M.

AU - Ortiz-Alemán, C.

AU - Couder-Castañeda, C.

AU - Urrutia-Fucugauchi, J.

AU - Trujillo-Alcántara, A.

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N2 - We present a novel approach to automated volume extraction in seismic data and apply it to the detection of allochthonous salt bodies. Using a genetic algorithm, we determine the optimal size of volume elements that statistically, according to the U-test, best characterize the contrast between the textures inside and outside of the salt bodies through a principal component analysis approach. This information was used to implement a seeded region growing algorithm to directly extract the bodies from the cube of seismic amplitudes. We present the resulting three-dimensional bodies and compare our final results to those of an interpreter, showing encouraging results.

AB - We present a novel approach to automated volume extraction in seismic data and apply it to the detection of allochthonous salt bodies. Using a genetic algorithm, we determine the optimal size of volume elements that statistically, according to the U-test, best characterize the contrast between the textures inside and outside of the salt bodies through a principal component analysis approach. This information was used to implement a seeded region growing algorithm to directly extract the bodies from the cube of seismic amplitudes. We present the resulting three-dimensional bodies and compare our final results to those of an interpreter, showing encouraging results.

KW - Genetic algorithms

KW - Principal component analysis

KW - Salt bodies

KW - Seeded-based region growing

KW - Seismic textures

KW - Statistical tests

KW - seismic textures

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A texture-based region growing algorithm for volume extraction in seismic data

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