RU97108599A

RU97108599A - METHOD AND DEVICE FOR PROCESSING SEISMIC SIGNAL AND CARRYING OUT EXPLORATION OF USEFUL MINES

Info

Publication number: RU97108599A
Application number: RU97108599/25A
Authority: RU
Inventors: Курт Марфурт; Р.Линн Кирлин; Стивен Л. Фармер; Майкл С. Бахорич
Original assignee: Амоко Корпорейшн
Priority date: 1995-10-06
Filing date: 1996-09-30
Publication date: 1999-05-27

Claims

1. A method for exploration of hydrocarbon raw materials, characterized in that it includes the following operations: (a) obtaining a representative set of seismic traces distributed over a given three-dimensional volume of the earth's thickness, and this volume of the earth has underground parameters characterized by inclination and inclination azimuth, which determined relative to a predetermined measurement axis of the inclination azimuth, (b) dividing said three-dimensional volume into at least one horizontal time layer, and dividing said temporarily layer to a set of three-dimensional analysis cells, each analysis cell having two predetermined mutually perpendicular lateral sizes and sections of at least five seismic traces mixed from each other in the lateral direction, localized in it, (c) calculation, inside each specified analysis cell , a set of similarity criteria for the indicated traces localized in it, and each similarity measurement is at least a function of time, the number of seismic traces within the specified analysis cell and the apparent inclined the apparent inclination azimuth of the indicated traces within the specified analysis cell, (d) identifying, within each analysis cell, the largest of the specified similarity criteria calculated and determining the corresponding visible inclination and apparent inclination azimuth as an estimate of the true inclination and true azimuth of the seismic inclination traces within the specified analysis cell; and (e) the formation, from all of the indicated analysis cells, of a seismic attribute image from the largest of the similar similarity criteria calculated and from the indicated corresponding estimates of the true inclination and true azimuth of the inclination of the seismic traces within the specified time layer.

2. The method according to p. 1, characterized in that the operation (e) is carried out by forming a color map, which is characterized by color tone, saturation and brightness, and one of these estimates of the true azimuth of the inclination, these estimates of the true inclination and the largest of the calculated similarity criteria are applied to one of the scales of brightness, color tone and saturation, while the other of the indicated estimates of the true azimuth of the inclination, the specified estimates of the true inclination and the largest of the calculated ITER similarity applied to other scales of luminance, hue and saturation, and the remaining one of said estimates of true azimuth of inclination, the inclination of said true and said count of the largest of the calculated similarity criteria applied to the remaining one of the gray scale, hue and saturation.

3. The method according to p. 2, characterized in that the operation (e) is carried out by plotting the indicated estimates of the true azimuth of the inclination along the specified axis of the color tone.

4. The method according to p. 2, characterized in that the operation (e) is carried out by applying to the map these estimates of the true inclination along the specified axis of saturation.

5. The method according to p. 2, characterized in that the operation (e) is carried out by applying to the map the specified largest calculated similarity criteria along the specified brightness axis.

6. The method according to p. 1, characterized in that in the operation (c), each similarity criterion is at least a function of the energy of the indicated traces, the specified energy of each trace being a function of time, the number of seismic traces within the specified analysis cell, and the visible inclination and the visible azimuth of the inclination of the indicated paths within the specified analysis cell.

7. The method according to p. 6, characterized in that each similarity criterion is at least a function:

wherein each analysis cell contains sections of at least J (J ≥ 5) traces, with x and y representing distances measured from the center of the analysis cell, p and q are visible inclinations in the x and y directions, respectively, au _f (t , p, q, x, y) represents a seismic trace within the indicated analysis cell, and the true inclination d and the azimuth of the inclination φ are associated with p and q by the expressions: p = dsinφ and q = dcosφ.

8. The method according to p. 7, characterized in that each similarity criterion is a function of:

9. The method according to p. 7, characterized in that each similarity criterion for each inclination, inclination azimuth and analysis point is smoothed out by integrating the current time window in partial amounts from -K to + K:

where K represents half the width of the time window of the samples.

10. The method according to p. 1, characterized in that each trace inside each of the analysis cells is characterized by a maximum inclination and a maximum component of the current frequency; moreover, operation (c) includes the following operations: obtaining an estimate of the maximum true inclination and the maximum component of the current frequency of the indicated traces within the specified analysis cell, using the specified maximum true inclination, the specified maximum component of the current frequency and the specified predetermined lateral dimensions of the specified analysis cell to calculate increments of visible inclination in two mainly perpendicular directions relative to the specified axis of measurement of the azimuth of inclination onenia.

eleven . The method according to claim 1, characterized in that when the operation (c) is performed, the specified criterion is at least a function:

in which J represents the number of traces in the indicated analysis cell, while u _j (τ, p, q) is the mapping of seismic traces in the indicated analysis cell, where τ is the time, p is the apparent inclination in the x direction, and q is visible inclination in the y direction, with p and q measured in ms / s, and the x and y directions are mutually perpendicular.

12. The method according to p. 11, characterized in that during the operation (c), the specified criterion is also a function:

13. The method according to p. 11, characterized in that when the operation (c) is specified, this criterion is a function of:

14. A method for localizing underground characteristics, faults and contours, characterized in that it includes the following operations: (a) obtaining 3D seismic data covering a predetermined volume of the earth, (b) dividing the indicated volume into a grid of relatively small three-dimensional analysis cells, moreover, each of these analysis cells has at least five laterally displaced from each other and mainly vertical seismic traces localized in it, (c) determining in each of the indicated cells of similarity / bottom a beat of said paths with respect to two predetermined directions, and (d) registration of said affinity / similarity for said cells in the form of an image of a two-dimensional map of underground characteristics.

15. The method according to p. 14, characterized in that when the operation (c), the indicated predetermined directions are mutually perpendicular, and the indicated similarity / similarity of the indicated traces inside each cell is at least a function of time, the number of seismic traces within the specified cell analysis, as well as the apparent inclination and visible azimuth of the inclination of the indicated paths within the specified analysis cell.

16. The method according to p. 15, characterized in that the indicated similarity / similarity of the indicated paths within each cell is determined by performing a variety of similarity / similarity measurements of the indicated paths within each cell and selecting the largest measurement result of the specified similarity / similarity of each cell, the operation ( c) additionally includes the operation of determining the apparent inclination and the visible azimuth of the inclination corresponding to the largest of these measurements, which will be an estimate of the true inclination and an estimate and muddy azimuth inclination of seismic traces within said cell analysis.

17. The method of claim 16, wherein each of said plurality of measurements of said similarity / similarity is at least a function of the energy of said traces, said energy of said traces being a function of time, the number of seismic traces within said analysis cell, and visible inclination and apparent azimuth of the inclination of the indicated traces within the specified analysis cell.

18. The method according to p. 16, characterized in that the map is a color map, which is characterized by color tone, saturation and brightness, moreover, one of these estimates of the true azimuth of the inclination, these estimates of the true inclination and the largest of the calculated similarity criteria are applied to one of the scales of brightness, color tone and saturation, while the other of the indicated estimates of the true azimuth of the inclination, the specified estimates of the true inclination and the specified largest of the calculated similarity criteria applied to different scales of luminance, hue and saturation, and the remaining one of said estimates of true azimuth of inclination, these estimates of true dip and the largest of said calculated similarity criteria applied to the remaining one of the gray scale, hue and saturation.

19. The method according to p. 18, characterized in that the operation (d) includes the following operations: mapping the indicated estimates of the true azimuth of the inclination on the specified axis of the color tone, mapping on the map these estimates of the true inclination of the specified axis of saturation, and applying to the map of the indicated largest calculated similarity criteria along the specified brightness axis.

20. A product for seismic exploration, in which 3D seismic data containing reflected seismic energy is recorded as a function of time and using a computer programmed to process these seismic traces and to generate an image from them that is representative of underground geological parameters, characterized in that it includes a means that can be read by a computer and which contains commands for the specified computer to the process, which includes the following operations: (a) obtaining 3D seismic data for a given volume of the thickness of the earth, and these data include seismic traces that are characterized by time, position and amplitude, and (b) determining the similarity / similarity of the surrounding 3D areas seismic data of a specified volume by: (1) dividing at least one part of said data into a grid of relatively small, adjacent, three-dimensional analysis cells, each of these analysis cells having at least ive spaced laterally of seismic traces, and (2) computing a seismic attribute for each cell, which is a function of the largest of the plurality of similarity measurements and corresponding apparent dip and apparent azimuth corresponding inclination.

21. The product according to p. 20, characterized in that the said tool contains instructions for the computer to perform the operation (2) by measuring the similarity as a function of expression:

in which x _j and y _j are the distances measured from the center of the analysis cell along the mutually perpendicular axes x and y, where u _j (τ, p, q) is a reflection of the seismic path, while τ is the time, p is the apparent inclination in in the x direction, and q in the apparent inclination in the y direction, with p and q measured in ms / s.

22. The product according to p. 21, characterized in that the said tool contains instructions for the computer to perform the operation (2) by measuring the similarity as well as a function of the expression:

23. The product according to p. 21, characterized in that the said tool contains instructions for the computer to carry out the operation (1) by forming analysis cells having an elliptical cross section.

24. The product according to p. 23, characterized in that said predetermined volume is characterized by the presence of a crack extending in a direction that can be determined, said tool containing instructions for the computer to form analysis cells having mainly elliptical shape, the main axes of which aligned with the direction of the specified crack.

25. A seismic survey method in which reflected seismic energy is recorded as a function of time to obtain a series of seismic traces, characterized in that it includes the following operations: (a) obtaining a set of seismic trace data distributed over a three-dimensional volume of the earth’s thickness, this the volume of land has underground characteristics, which are characterized by inclination and azimuth of inclination; (b) calculating a plurality of similarity criteria for said traces within each relatively small three-dimensional analysis cell localized within a specified volume and at one part of a given time layer, each similarity measurement being at least a function of time, the number of seismic traces within the specified analysis cell, and visible inclination and visible azimuth of the inclination of the indicated paths within the specified analysis cell; (c) generating a seismic attribute for the indicated analysis cell, which is at least a function of the largest of the specified set of similarity criteria and the indicated corresponding apparent inclination and apparent inclination azimuth, said corresponding apparent inclination and apparent inclination azimuth being defined as true inclination estimates and true azimuth of the inclination of seismic traces inside the specified analysis cell; (d) repeating operations (b) and (c) for other parts of the time layer, and (e) forming a map of these seismic attributes for the specified time layer.

26. The method according to p. 25, characterized in that the operation (a) includes the following operations: (1) obtaining 3D seismic data for a predetermined volume of the earth’s thickness, said 3D seismic data including at least eleven seismic traces which are characterized by time, position and amplitude, and (2) dividing a portion of the indicated volume into at least one time layer containing a lattice of relatively small three-dimensional cubes that contain at least five seismic traces, said cubes are used as cells in the operation (b).

27. The method according to p. 26, characterized in that during the operation (b), each similarity criterion is a function of the expression:

in which each analysis cell contains sections of at least J seismic traces, with J at least 5, wherein x and y are the distances measured from the center of the analysis cell along the mutually perpendicular axes x and y, with p and q being visible inclinations in the x and y directions, respectively, au _f (t, p, q, x, y) displays a seismic trace within the specified analysis cell; moreover, the true inclination d and the azimuth of the inclination φ are related to p and q by the expressions: p = dsinφ and q = dcosφ.

28. The method according to p. 27, characterized in that each similarity criterion for each inclination, inclination azimuth and analysis point is smoothed out by integrating the current time window into partial sums of the time window within the specified time layer.

29. The method of seismic exploration, characterized in that it includes the following operations: (a) reading a set of 3D seismic data, which includes seismic signals of traces distributed in the bulk of the earth, (b) selecting at least one horizontal slice inside the indicated volume and the formation of cells in it, which are constructed in the form of rows and columns going laterally, each of these cells containing at least five seismic tracks that mainly cross it, (c) conducting with running calculations for each of the cells: (1) determination of the set of similarity criteria for the indicated traces, each criterion being at least a function of time, the number of seismic traces inside the indicated analysis cell, as well as the apparent inclination and the visible azimuth of the inclination of the indicated traces, (2) definition the largest of the specified set of similarity criteria, and (3) finding the estimate of the true inclination and the estimate of the true azimuth of the inclination of the seismic traces inside the indicated analysis cell from the visible inclination and visible azimuth inclination which corresponds to the highest criterion of similarity, and (d) generating an image of at least one horizontal slice maps indicated the greatest similarity criteria, and these estimates and the true mood of these true azimuth inclination of the estimates for each of these cells.

30. The method according to p. 29, characterized in that the operation (b) is carried out by selecting a horizontal slice that is characterized by a common time, and operation (d) is carried out by obtaining an image for the specified time slice of the mappings of the indicated largest similarity criteria and the indicated estimates of true inclinations and these estimates of the true azimuths of the inclination for each of these cells.

31. The method according to p. 29, characterized in that the operation (b) is carried out by forming a color map, which is characterized by color tone, saturation and brightness, and for each of these cells: one of the specified estimates of the true azimuth of the inclination, these estimates of the true inclination and the indicated largest of the calculated similarity criteria is applied to one of the scales of brightness, color tone and saturation, while the other of the indicated estimates of the true azimuth of the inclination, the specified estimates of the true inclination and the specified ca the largest of the calculated similarity criteria is applied to another of the brightness, color tone and saturation scales, and the remaining one of the indicated estimates of the true azimuth of inclination, the indicated estimates of the true inclination and the largest of the calculated similarity criteria are applied to the remaining one of the brightness, color tone scales and saturation.

32. A method of gas or oil exploration, in which seismic traces are recorded over the earth’s bulk of the earth, characterized in that this method includes the following operations: (a) grouping at least some parts of at least five relatively seismic relatively close to each other traces into the set of relatively small three-dimensional analysis cells, (b) conducting for each of the specified cells a set of similarity measurements of the indicated parts of the indicated traces as a function of at least time, the number of traces in them, as well as the visible the deviation of the indicated traces and the apparent azimuth of the inclination, (c) the identification for each of the indicated cells of the largest of the specified set of similarity measurements, the corresponding visible inclination and the corresponding azimuth of the inclination, and (d) the transformation of the indicated largest of the similarity measurements, the indicated corresponding visible inclination and the corresponding azimuth of the inclination of these cells in the color attributes of the color tone, saturation and brightness, and for each cell one of the indicated azimuth estimates is inclined The indicated inclination estimates and the indicated largest similarity criteria calculated are applied to one of the scales of brightness, color tone and saturation, while the other of the indicated inclination azimuth estimates, the indicated inclination estimates and the indicated largest similarity criterion are applied to another of the scales brightness, hue and saturation, and the remaining one of the specified estimates of the azimuth of the inclination, the specified estimates of the inclination and the specified largest of the similarity criteria calculated are applied to the remaining one of the scales of brightness, hue and saturation.

33. A product adapted for use by a workstation in which 3D seismic data are entered into memory and processed as a digital image of underground geological parameters, characterized in that it includes a computer-readable tool containing instructions for carrying out the process, which includes the following operations: (1) digital localization of the indicated 3D seismic data in the lattice of relatively small three-dimensional cells, each of these cells containing part mappings at least five seismic traces, (2) calculating, for each of the indicated cells, similarity estimates, true inclination estimates and true inclination azimuth estimates of the indicated parts, and (3) converting the similar similarity estimates, the indicated true inclination estimates and the specified true inclination azimuth estimates to the lattice numerical values corresponding to the color attributes of hue, saturation, and brightness.

34. The device according to p. 33, characterized in that one of the indicated estimates of the true azimuth of the inclination, the specified estimates of the true inclination and the specified similarity ratings are applied to one of the scales of brightness, color tone and saturation for each of these cells, while the other of these estimates of the true azimuth of the inclination, these estimates of the true inclination and these estimates of similarity are applied to another of the scales of brightness, color tone and saturation for each of these cells, and the remaining one of these estimates of the true azimuth deviation, these estimates of true inclination and these estimates of similarity are applied to the remaining one of the scales of brightness, color tone and saturation for each of these cells.

35. The device according to p. 33, characterized in that said computer-readable tool comprises instructions for performing operation (2) by: (i) calculating a plurality of similarity criteria with respect to at least two directions, and selecting the largest of these criteria, ( ii) selecting a visible inclination corresponding to the indicated largest similarity criterion found in operation (i), and (iii) selecting a visible inclination azimuth corresponding to the indicated largest similarity criterion found in operation (i).

36. The device according to p. 33, characterized in that the specified computer-readable tool selected from the group including magnetic tape, magnetic disk, optical disk and CD-ROM.

37. A method for searching for hydrocarbon deposits, characterized in that it includes the following operations: (a) obtaining a color image of the 3D seismic attribute of seismic data for a given three-dimensional volume of the earth’s thickness, and this image is generated using data obtained using a computer and at least one program for the specified computer, which gives commands for the specified computer to perform the following operations: (1) converting the specified volume into a lattice of relatively small three-dimensional cells, and each of these cells contains a section of at least five seismic traces localized in it, (2) taking many similarity measurements inside each of these cells, each measurement being at least a function of time, the number of seismic traces inside the specified cell as well as the apparent inclination of the indicated traces and the apparent azimuth of the inclination of the indicated traces, (3) the choice of the largest of the indicated similarity measurements for each cell, (4) use as an estimate of the true inclination and as an estimate the true azimuth of the inclination in each cell of the visible inclination and the visible azimuth of the inclination, which correspond to the indicated largest of the indicated similarity measurements in the specified cell, (5) mapping the indicated estimates of the true azimuth of the inclination on the color scale, (6) mapping of the indicated estimates true inclination on the saturation scale, and (7) mapping the largest of the calculated similarity measurements on the brightness scale, and (b) using the specified color image to identify structures molecular weight and sedimentological subsurface parameters that are typically associated with the capture and accumulation of hydrocarbons.

38. The method according to p. 37, characterized in that it further includes the operation of using the specified card to identify hazards during drilling.

39. The method according to p. 38, characterized in that it further includes a drilling operation at a location identified during operation (b).

40. The method according to p. 37, characterized in that the operation (a) (2) includes the calculation operation:

where each cell is characterized by two perpendicular directions, with x _j and y _j representing the distances measured from the center of the analysis cell along the mutually perpendicular axes x and y, while J is the number of seismic traces, u _j (τ, p, q) is a seismic trace, with τ being the time, p being the apparent inclination in the x direction, aq being the visible inclination in the y direction.

41. The method according to p. 40, characterized in that the operation (a) (2) includes the operation of calculating the expression:

42. An oil or gas exploration map, characterized in that it includes: (a) a mainly flat means for recording visually distinguishable color images, said color images being characterized by color tone, saturation and brightness, and (b) a plurality of images on the specified tool, which are representative for displaying the similarity, true inclination and true azimuth of the inclination of 3D seismic traces within a given volume of the earth's thickness, and the true inclination azimuth is plotted on scales hue, true dip delayed scale saturation and similarity delayed luminance scale.

43. The map of claim 42, wherein said volume is representative of the grid of the area of three-dimensional cells, each of which contains a display of parts of at least five seismic traces, each of these images corresponding to one of these cells, the similarity of the traces within each cell is determined by performing a variety of similarity measurements of the indicated traces within each cell and selecting the largest of these measurements, each similarity measurement being at least Here is a function of time, the number of seismic traces inside the indicated cell, as well as the apparent inclination of the indicated traces and the apparent azimuth of the inclination of the indicated traces, the true inclination of each cell being displayed by the visible inclination, which corresponds to the largest of the indicated similarity measurements, and the true inclination azimuth is displayed visible azimuth of inclination, which corresponds to the largest of these measurements of similarity.

44. The card according to p. 43, characterized in that the similarity is measured as a function of:

where x _j and y _j are the distances measured from the center of the analysis cell along the mutually perpendicular axes x and y, where J is the number of seismic traces localized in the cell, and u _j (τ, p, q) is a mapping of the seismic trace, where τ is time, p is the apparent inclination in the x direction, and q is the visible inclination in the y direction.

45. The card according to p. 44, characterized in that the similarity is measured as a function of:

46. The card according to p. 42, characterized in that the said tool is a front surface of a CRT.

47. A computer for a computer workstation in which 3D seismic data obtained for a given three-dimensional volume of the earth’s thickness is stored in memory, and the computer divides the indicated volume into a grid of three-dimensional analysis cells, with each cell containing at least a portion offset from each other in the lateral direction of seismic traces, localized in it, and the computer is used to convert such data into an image of seismic attributes, while the computer is different in that it carries out the process s, which includes the following operations: (1) calculating in each cell the similarity value for the indicated seismic traces, the specified similarity value being at least a function of time, the number of seismic traces inside the specified cell, as well as the apparent inclination of the indicated traces and the visible the inclination azimuth of the indicated paths, and (2) displaying the indicated similarity value for each cell that lies between two planes inside the 3D volume to indicate the parameters of the lower horizon, which are usually connected us with the capture and accumulation of hydrocarbons.

48. A computer for a computer workstation according to claim 47, wherein the computer performs operation (1) by performing a plurality of similarity measurements within each cell, and selecting the largest of the indicated plurality of measurements as the similarity value of the specified cell.

49. A computer for a computer workstation according to claim 48, characterized in that after the operation (1), the computer performs the operation of using the visible inclination and the visible azimuth of the inclination, which correspond to the indicated largest similarity measurement in the indicated cell, as an estimate of the true inclination and true azimuth of the inclination of the specified cell.

50. The computer workstation of claim 49, wherein the image in operation (2) is characterized by color components of color tone, saturation and brightness, and operation (2) includes operations of plotting the indicated true inclination estimate for each cell on the saturation scale, and plotting the indicated largest of the calculated similarity measurements on the brightness scale.