• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    METHOD AND SYSTEM FOR MARINE SEISMIC RESEARCH PATTERN FOR A RESEARCH SHIP. The present invention relates to techniques relating to determining or executing a survey pattern for a marine seismic survey vessel. The search pattern can be determined based on a specific subsurface of lighting area. The lighting surface subsurface can be identified from primary reflections and reflections of a higher order detected by sensors placed in a marine sensor recording cable configuration that can be towed behind the research vessel. The configuration of the marine recording cable sensor may include a plurality of marine recording cables.
    公开号:BR102013013317B1
    申请号:R102013013317-5
    申请日:2013-05-28
    公开日:2021-02-17
    发明作者:Walter Söllner;Martin Widmaier;Stian Hegna;Steve Bishop
    申请人:Pgs Geophysical As;
    IPC主号:
    专利说明:

    [0001] [0001] The present invention relates to marine seismic surveys that can use energy, such as sound, which is transmitted to subsurface aspects, and reflected back to sensors. The sensors can be configured as part of a number of marine recording cables, which can be towed behind a research vessel. These marine recording cables can be configured as a submerged system of multiple subsea recording cables, which can be arranged in parallel.
    [0002] [0002] A common application of marine seismic research is oil and gas exploration in marine environments For example, sound waves received during a marine seismic survey can be analyzed to locate geological structures that support hydrocarbons, and thus determine the location of deposits of oil and natural gas. For this purpose, search paths can be calculated to provide optimized search coverage for an area of interest. Such research routes may require a research vessel to conduct numerous research passes to adequately cover the area of interest. Brief description of the drawings
    [0003] [0003] Figure 1 outlines an example of a seismic survey vessel suitable for carrying out techniques in accordance with modalities disclosed here, towing marine recording cables and a seismic source in a body of water.
    [0004] [0004] Figure 2A outlines an example of primary and multiple reflections that can be received on a sensor and assembled for use in image formation in various modalities.
    [0005] [0005] Figure 2B illustrates the primary and multiple reflections outlined in the example in figure 2A together with an additional multiple reflection of a higher order.
    [0006] [0006] Figure 3 delineates a lighting area surface based on image formation using primary and multiple reflections according to some modalities.
    [0007] [0007] Figure 4 outlines an example of a research path that can be determined using techniques according to some modalities.
    [0008] [0008] Figure 5 is a flow chart that illustrates the method for navigating a research ship according to a modality.
    [0009] [0009] Figure 6A is a flow chart illustrating the method for determining a survey pattern with a subsurface of lighting area that is based on image formation using primary reflections and multiple reflections.
    [0010] [0010] Figure 6B is a flowchart that illustrates the method for determining the survey pattern and that includes a trigger sampling plan for use with a subsurface lighting area that is based on image formation using primary reflections and reflections from higher order.
    [0011] [0011] Figure 7 is a block diagram of a modality of a system that includes a data acquisition system and a navigation system in accordance with the various modalities of the present disclosure. Detailed Description
    [0012] [0012] This specification includes references to "a modality" or "modality" of. The appearance of the phrases "in one modality" or "in modality" does not necessarily refer to the same modality. Particular aspects, structures or characteristics may be combined in any appropriate manner consistent with this disclosure.
    [0013] [0013] Terminology: the following paragraphs provide definitions and / the context for terms found in this disclosure (including the appended claims):
    [0014] [0014] "Usable by". In the context of "element X is 'usable by' by system Y to make Z", this phrase refers to a situation in which system Y is configured to perform function Z using (for example, read, manipulate, execute) the element X. Thus, if a system is configured to determine a lighting surface subsurface by performing various operations based on detected and collected information, it can be said that the information detected and assembled is "usable by" the system to determine the subsurface of the lighting area. lighting.
    [0015] [0015] "First", "Second" etc. As used here, these terms are used with light labels for nouns that precede them, and do not imply any sort of ordering (for example, spatial, temporal, logic, etc.) unless otherwise indicated.
    [0016] [0016] "Based on," As used herein, this term is used to describe one or more factors that affect a determination. This term does not rule out additional factors that may affect a determination. That is, a determination can be based only on those factors or based only in part on those factors. Consider the phrase "determine A based on B." Although B may be a factor that affects the determination of A, such a phrase does not rule out the determination of A also being based on C. In other cases, A can be determined based only on B.
    [0017] [0017] "Understanding." This is an open term that means "including the following elements (or their equivalents), but not excluding others." As used in the appended claims, the term does not rule out additional structure or steps. Consider a claim that describes: "A system that comprises one or more marine sensor recording cables ...". Such a claim does not rule out the system of including additional components (for example, a seismic source, data acquisition systems, navigation systems). "Including" and "having" are terms used in a similar way that are also open.
    [0018] [0018] "Configured for." As used herein, this term means that a particular piece of hardware or software is arranged to perform a particular task or tasks when operated. Thus, a system that is "configured to" perform task A means that the system can include hardware and or software that during system operation performs or can be used to perform task A. (In this way a system can be "configured for" perform task A even if the system is not currently operating).
    [0019] [0019] A configuration taken as an example for planning and designing the seismic survey path is outlined in the plan view of figure 1. The research vessel 110 can tow one or more sources 120 and a plurality of sensor marine recording cables 130 in in-line direction 101. Alternatively, in some embodiments, sensor sources 120 and marine recording cables 130 may be towed by separate vessel, or otherwise arranged appropriately in the body of water. The various sensor marine recording cables 130 may in some cases be arranged in a substantially parallel manner (spaced in the direction of a transverse line 102) to provide imaging of a subsurface area. Image formation can be performed using received data that corresponds to the signal reflection dispersion (for example, pressure waves) generated by the source 120. As outlined, the different sensor marine recording cables 130 are arranged parallel to the towing direction and inline of research vessel 110. In some embodiments, the various sensor marine recording cables 130 can be arranged in a configuration that is offset from the towing direction of research vessel 110 (for example, aligned according to an angle that is displaced towing direction) and / or in a configuration in which the various sensor marine recording cables 130 are not substantially parallel to each other (for example, aligned at different angles to the towing direction.
    [0020] [0020] Each of the various marine recording cables sensors 130 may include a number of sensors 140. Sensors 140 may include, for example, submerged pressure sensors (for example, hydrophones) and speed sensors (for example, geophones). Marine recording cable sensor 130 may also include several additional components, such as steering devices.
    [0021] [0021] Although figure 1 outlines a configuration that uses eight marine sensor recording cables and a seismic source, embodiments of the present invention may employ configurations that use more than one source and / or different numbers of marine sensor recording cables. In addition, the number of sensors 140 outlined in Figure 1 is for illustrative purposes and different modalities of the present disclosure may use a different number of sensors per marine recording cable. In some modalities the different marine recording cables sensors may not include all the same numbers of marine recording cables. In some modalities the sensors can be placed in different patterns and / or they can be spaced irregularly over the different marine recording cables.
    [0022] [0022] Turning now to figures 2A and 2B, seen looking ahead outlines examples of primary and multiple reflections that can in some cases be used in image formation of a subsurface of the lighting area. As shown in figure 2A the source 120 can cause primary reflections and several reflections of a higher order to be received in sensors such as the outermost sensor 140a. Figure 2A outlines primary reflection taken as an example 230, in which a waveform from source 120 is reflected once through reflector 202 (e.g., seabed, sub-bottom aspects) before reaching sensor 140a. Figure 2A also outlines higher-order reflection taken as an example 220, in which one waveform is reflected multiple times before reaching 140 (in this example the shape of another wave in question is reflected three times by means of reflector 202 and twice by subsurface of the sea 201, for a total of five times). The term "higher-order reflections" thus refers to a waveform that has been reflected at least twice between the source and the destination sensor.
    [0023] [0023] Conventional seismic acquisition methods that employ image formation based only on primaries can define subsurface lighting area through midpoint dispersion (for example, modeling subsurface structures as horizontally layered means in research planning) . In such cases, the midpoint position can be a vector provided by half the sum of the receiver position vector and the source position vector. The transverse lines can be sequential numbers of the midpoints of a nominal source receiver configuration projected onto the transverse centerline (the centerline in the direction of the transverse line, perpendicular to the direction of the main navigation line). The 'in lines' can be sequential numbers of the midpoints of a nominal source receiver configuration projected on the inline centerline (the centerline in the inline direction, parallel to the main navigation line direction). The distance between consecutive "in lines" and transverse lines can be provided by projecting the difference in consecutive midpoint vectors from a nominal source receiver configuration (eg, 3D marine recording cable ship) onto the inline centerline and the center line of the transverse line, respectively. Thus, a primary reflected waveform 230 received at the outermost sensor 140a can provide an outermost boundary of a lighting area that provides reflector image formation 202 (e.g., seabed, subsurface aspects) up to distance 212 ( half the distance 211 from source 120 to sensor 140a). Thus, marine seismic survey standards designed to correspond to these conventional methods may require shipping line separations that correspond to half of the total dispersion of marine recording cable (for example, the number of marine recording cables times the separation of marine cable). marine recording divided by two, the distance between the transverse lines of the outermost marine recording cables) to provide complete coverage of the area of interest. Similarly, the number (for example, frequency) of shots that may be required to provide a desired in-line coverage, can be determined based on the in-line dimensions of the lighting area.
    [0024] [0024] In contrast to conventional marine seismic acquisition systems, acquisition of a double (or multiple) sensor and with a double (or multiple) marine recording cable can allow separating wave fields that propagate upward from wave fields that propagate down. The separate wave fields can provide suppression of spectral slits related to receiver ghosting, resulting in high resolution images.
    [0025] [0025] For certain parts of the spectral content of seismic signals (for example, where motion sensors are contaminated by noise) and under certain sea surface limiting conditions, wave field separation can be performed using only pressure sensors in acquisition with conventional marine recording cable. See US Patent Nos. 7,359,283 and 7,835,225.
    [0026] [0026] In contrast to conventional methods, techniques disclosed here can be employed to determine navigation paths for marine seismic research based on subsurface lighting that results from image formation using separate wave fields (for example, full wave fields upward and downward), including primary and multiple reflections. For example, Whitmore et al. Describes imaging of primaries and multiples using dual sensor data, wave field separation from dual marine recording cable, downward extrapolation, and the application of imaging conditions. See ND Whitmore, AA Valenciano, W. Sollner, S. Lu, Imaging of primaries and multiples using a dual-sensor towed streamer, International Meeting, SEG. 3187-3192, hereby incorporated by reference in its entirety. In contrast to imaging principles that use only primaries (for example, techniques that can filter data that corresponds to multiples such as noise), imaging using separate separate wave fields (including primary reflections and higher-order reflections) can allow downward wave fields at each sensor location (e.g., downward portions of multiple reflection wave field 220) to be looked at as a secondary source. Thus, the sub-surface of the lighting area in both, in the direction of the transverse line and in the direction of the line, which may have image formation, can be extended substantially. For example, figure 2A outlines a subsurface of lighting area that extends from the source to at least the middle between the two outermost marine recording cables. More specifically, figure 2A illustrates an example of image formation that uses primers and multiples to facilitate the formation of reflector image 202 in the direction of the transverse line for distance 213, which is the distance from the source 120 to the distance from the point medium (distance 215) in the transverse direction of the total distance between the outermost sensor 140a (located at distance 211) and the next outermost sensor 140b (located at distance 214 in the transverse direction from sensor 140a).
    [0027] [0027] Figure 2B outlines an example of an even larger lighting surface subsurface that can have an image formed in cases where multiples of a higher order are used. The subsurface of the outlined lighting area which is further determined based on the higher order multiple reflection wave field 240, extends over a distance 216 which is almost the entire cross-line distance between the source 120 and the sensor 140 a. When this principle is extended to multiples of a much higher order, the wave field may in some cases behave like a downward plane wave (for example, a source wave field over the entire length of the acquisition surface), and the The resulting area of the formed image can in some cases cover the complete dispersion of marine recording cable. Generally, real sea surfaces are not completely flat, but instead will typically show some degree of roughness (for example, depending on weather conditions). As a consequence, wave fields that propagate downwards can generally be considered as an omni-directionally dispersed wave field in each receiving position. In several modalities taken as an example, the resulting area of formed image can have a dimension in transverse line that is at least 95% of the distance in transverse line between the two outermost marine recording cables.
    [0028] [0028] In seismic data obtained using modalities of marine acquisition configurations that can employ double sensors and one or more active sources, and that can use image formation technology that is based on the principle of forming images with separate wave fields, the full downward wave field can act as "simultaneous sources" at each receiving position. Conventional seismic surveys using active sources at each receiving position (for example, symmetric sampling) provide favorable configurations in relation to the reconstruction of the reliable wave field. Modalities of the present disclosure can achieve "simultaneous symmetric sampling" (for example, without the use of active sources in each receiving position) combining dual sensor acquisition with the principle of image formation with separate wave fields.
    [0029] [0029] These techniques also apply to the lighting area subsurface in the line direction as discussed in more detail with respect to figure 3. Consequently, the present techniques can be used to determine seismic survey navigation paths based on subsurface surfaces. larger lighting areas taking into account primary and multiple, thereby reducing the acquisition effort and reducing the number of passages that a research ship must complete to form an image of an area of interest.
    [0030] [0030] In addition, this use of multiples can also provide increased involvement (for example, increased received seismic data, representative of the lighting area) in the transverse line and / or in the inline directions. For example, higher order multiple reflection wave field 240 which is outlined in figure 2B can provide enormously increased seismic data (by triggering from source 120) that can be received by several sensors 140. Consequently, the present techniques can achieve a desired subsurface wrapping using fewer active shots than that used in conventional imaging methods based only on primers.
    [0031] [0031] Figure 3 provides a plan view that illustrates a larger example of a lighting surface subsurface that can be determined using the modalities of the present techniques and the improved navigation path (for example, based on wider spaced navigation lines) that can be determined. In this example, the subsurface of the illumination area 330 represents an illumination area that can be achieved by conventional imaging techniques using only primers. The transverse line dimension of the subsurface of the lighting area 330 extends in the direction of the transverse line 102 to the distance 331 from the source 120. As discussed above, the distance 331 is half the distance to the outermost marine recording cable 130h (half distance 333). Thus, the transverse line direction of the subsurface of the lighting area 330 can be expressed as half the transverse line distance between the two outermost marine recording cables 130a and 130h.
    [0032] [0032] Similarly, the in-line dimension of the lighting surface subsurface that can be achieved using conventional image formation techniques using only primers is the distance 332 in the example in figure 3. This distance is the distance between the midpoint 312 in the line direction of the distance between the source and the front sensors (distance 314) and the midpoint 334 in the line direction of the distance between the source and the rear sensors (distance 336).
    [0033] [0033] In contrast, an example of the improved lighting area provided by the present techniques is outlined in this example as a subsurface of the lighting area 320. The cross-sectional dimension outlined of the sub-surface of the lighting area 320 (which is larger than the transverse line dimension described above area 330) extends in the transverse line direction 102 through the distance 321 from the source 120. As discussed above, the distance 321 is the transverse line distance from the source 120 to the midpoint 325 in the transverse direction of the distance 323 between the outermost marine recording cable 130h and the next outermost marine recording cable 130g. Thus, the overall transverse line direction of the lighting area subsurface 320 can be expressed as the sum of the transverse line distance between the next outermost marine recording cable on the port side and the next outermost marine recording cable on starboard (cables). marine recording cables 130b and 130g), half the cross-line distance between the next outermost marine recording cable on port 130b and the outermost marine recording cable on port 130a and half the cross-line distance between marine recording cable next outermost starboard 130g and the outermost marine recording cable on starboard 130h.
    [0034] [0034] As discussed above, in other examples, the lighting surface subsurface may be close to or equal to the distance between the two outermost marine recording cables (for example, outermost marine recording cable on port 130a and recording cable outermost marine starboard 130h). In some instances the subsurface of the lighting area may be greater than or equal to 95% of the distance between the two outermost marine recording cables.
    [0035] [0035] Modalities of the present techniques can be used to provide a subsurface of lighting area similarly improved in the in-line direction. For example, the in-line dimension of the subsurface of the lighting area 320 in Figure 3 (which is greater than the dimension of the area 330 in the transverse line described above) is the distance between 1) the midpoint 312 in the in-line direction of the distance between the source and the front sensors (distance 314) and 2) the midpoint 326 in the line direction of the distance 324 between the next rear sensors (for example 140k) and the rear sensors (for example, 140j).
    [0036] [0036] In several modalities, an improved lighting area surface allows a ship to carry out a research pattern that includes less passage over a given area. Referring to figure 4, for example, a ship 110 that implements the techniques described here, may have a search pattern that includes search routes 410a and 410b that have a spacing of 420. In this case, the spacing 420 between paths 410 may be significantly greater than the spacing of routes taken by a ship using traditional survey techniques. Furthermore, in some embodiments, the ship 110 performs a survey pattern that includes a firing sampling plan that is not as dense as previous plans due to the size of the surface of the improved lighting area. That is, vessel 110 can perform fewer, more spaced shots to achieve a desired subsurface coverage.
    [0037] [0037] Turning now to figure 5, a flowchart of a modality of a method for navigating a research vessel on a research path is shown. Method 500 includes towing a plurality of marine sensor recording cables, for example, in a line direction behind a research vessel 110. Method 500 further includes gathering information received from sensors placed along the plurality of marine recording cables 520 sensors. The information gathered includes data that correspond to primary reflections and data that correspond to reflections of a higher order. In 530 a method includes navigating the survey vessel in a survey pattern. This navigation can be based on a subsurface of lighting area identifiable from information that corresponds to primary reflections and information that corresponds to reflections of a higher order. In some modalities, navigation includes implementing a trigger sampling plan based on the sub-surface dimension of the lighting area. Consequently, in one modality the research vessel can adjust the firing sampling plan by decreasing or increasing the speed at which firings are made, that is, the firing density, after or in response to a change in the subsurface of the lighting area ( that is, an increase or decrease in the current size of the area). In one embodiment, this adjustment can be carried out automatically by means of a data acquisition system from the research vessel, such as a data acquisition system 710 discussed below in relation to figure 7.
    [0038] [0038] The plurality of marine sensor recording cables may include a first outer marine recording cable, a second outer marine recording cable and two or more marine sensor recording cables placed between the first and second marine recording cables more exterior. The two or more marine sensor recording cables placed between the first and second outer marine recording cables include a third marine recording cable that is closest to the first outer marine recording cable, and a fourth marine recording cable that it is closer to the plurality of marine sensor recording cables to the second outermost marine recording cable. In figure 3, for example, the first and second outermost marine recording cables can be marine recording cables 130a and 130h, respectively. The third and fourth marine recording cables that are closest to the first and second outermost marine recording cables are marine recording cables 130b and 130g, respectively (these marine recording cables are adjacent to marine recording cables 130a and 130h ). In some cases navigation is based on a subsurface of lighting area comprising a dimension (for example, a width) in a transverse line direction that is at least the sum of the transverse line distance between the third marine recording cable and the fourth marine recording cable, half the cross-line distance between the first outermost marine recording cable and the third marine recording cable and half the cross-line distance between the second outermost marine recording cable and the fourth marine recording.
    [0039] [0039] Some modalities may include a single source of seismic energy. In other modalities, several sources can be used.
    [0040] [0040] Figure 6A shows a flow chart of a method 600 to determine a research pattern. In 610 the method includes determining a subsurface of identifiable lighting area from detected primary reflections and reflections of a higher order. These primary and higher order reflections can be detected using sensors placed in a marine recording cable configuration that includes a plurality of towed marine sensor recording cables. In some embodiments, a data acquisition system for the research vessel (for example, data acquisition system 710 described below in relation to figure 7) determines the lighting area subsurface by tracking locations of sensor marine recording cables. For example, in one mode, the data acquisition system can track multiple coordinate positions (for example, in relation to inline and transverse centerlines) along a given marine recording cable, where positions can correspond to some of the sensors on the marine recording cable (for example, the frontmost sensor, the rearmost sensor and one or more intermediate sensors). In some modalities, the data acquisition system determines (for example, in real time) an instantaneous subsurface of lighting area based on the locations. In one embodiment, this area can be determined by determining an instantaneous dimension in a line direction and an instantaneous dimension in a cross-line direction for the marine sensor recording cables based on the various criteria discussed above. In 620, the method includes determining a survey pattern based on the subsurface of the lighting area. In some modalities, determining the search pattern includes selecting a course for the research vessel (for example, some behavior that corresponds to a 410 route) based on the instantaneous subsurface of the lighting area and providing the selected course for the navigation system of the research ship (for example, the system of negation 720 discussed below in relation to figure 7. In such modality the navigation system can be configured to adjust a current course of the research ship to be the selected course. For example , a research vessel may encounter a transverse current that initially causes a portion of the starboard sensor marine recording cables to move a modality the research ship can change its course to take into account the potential blind spots caused by this reduction. adhesion the search standard determined in 620 can be determined as a function of the data acquisition system, a function of the navigation system or a function of some other system of the research vessel.
    [0041] [0041] Figure 6B shows a method flow chart 601 to determine a research pattern. In 630 a method includes determining a subsurface of identifiable lighting area by detecting primary reflections and reflections of a higher order. These primary and higher order reflections can be detected by means of sensors placed in a marine recording cable configuration that includes a plurality of towed marine sensor recording cables. In 640 the method includes determining the trigger sampling plan based on the sub-surface of the lighting area (for example, based on a determined in-line dimension of the sub-surface of the lighting area).
    [0042] [0042] As an application taken as an example of "simultaneous symmetric sampling", a marine survey pattern using dual sensors and the separate wave field imaging principle can close the lighting spaces caused by the straightening of the marine recording cable or navigation around obstacles (such as platforms or other fixed installations) to a minimum. In conventional marine recording cable acquisition methods, such spaces are typically filled by expensive filling and sub-shooting acquisition procedures.
    [0043] [0043] Figure 7 outlines an example of a modality that can be used to practice the methods described above. System 700 may include data acquisition system 710 and navigation system 720. In some embodiments, data acquisition system 710 and navigation system 720 may be integrated as a part of the system. In other modalities the respective systems can be different systems.
    [0044] [0044] As shown, the data acquisition system 710 can include processor 710a, memory subsystem 710b, storage subsystem 710c. The 710a processor (which can be multiple individual processors) may contain a cache or other form of built-in memory.
    [0045] [0045] Memory 710b can include one or more components of memory subsystem. For example, in several modalities the 710b memory can be implemented using one or more subsystems that can individually include flash memory, random access memory (RAM, SRAM, EDO RAM, SDRAM, DDR, SDRAM. RDRAM, etc.), ROM, (PROM, EPROM, EEPROM ,, etc.), and / or several other forms of volatile or non-volatile memory. Memory 710b can store executable program instructions by data acquisition system 710 using processors 710a, and including executable program instructions to cause system 700 to implement the various techniques described here.
    [0046] [0046] Storage 710c may include one or more component storage subsystems. For example, in several embodiments, 710c storage can be implemented using one or more systems having any type of physical storage technology, including hard disk storage (for example, magnetic or solid state), floppy disk storage, disk storage optical, tape storage, and so on. Some modalities of data acquisition system 710 may not include storage 710c that is separate from memory 710b (for example, systems that have only volatile memory, systems that have non-volatile memory implemented only in flash memory). In some embodiments, all or part of storage 710c can be remote to the other components of the data acquisition system 710. Storage 710c can store program instructions executable by computer system 100 using 710a processors, including executable program instruction to make the data acquisition system 710 using 710a processors including executable program instruction causes system 700 to implement the various techniques disclosed here.
    [0047] [0047] As shown, the navigation system 720 can include processor 720a, memory subsystem 720b and storage subsystem 720c. These elements are similar to processor 710a, memory subsystem 710b and storage subsystem 710c described above in the context of the data acquisition system 710. Consequently, the description of these elements with the data acquisition system 710 applies equally to these elements in the context navigation system 720.
    [0048] [0048] Although specific modalities have been described above, these modalities are not intended to limit the scope of the present disclosure, even where there is only a single modality described with respect to a particular aspect. Examples of aspects provided in the disclosure are designed to be illustrative rather than restrictive, unless otherwise stated. The above description is designed to cover such alternatives, modifications and equivalents, as should be evident to someone skilled in the art, with the benefit of this disclosure.
    [0049] [0049] The scope of this disclosure includes any aspect or combination of aspects disclosed here (either explicitly or implicitly) or any generalization of whether or not it alleviates any of the problems faced here. Consequently, new claims may be made during the course of this Order (or an Order that claims priority for it) for any such combination of aspects. In particular, with reference to the appended claims, aspects from dependent claims can be combined with those from the independent claims, and aspects of the respective independent claims can be combined in any appropriate manner, and not merely in the specific combinations listed in the appended claims.
    权利要求:
    Claims (20)
    [0001]
    Method characterized by understanding: - towing a plurality of sensor streamers (520) behind a research vessel; - gather, based on data received from sensors across the plurality of streamers (520) sensors, information that corresponds to primary reflections and information that corresponds to reflections of a higher order; - determine, based on the information collected, an identifiable subsurface lighting area from the primary reflections and the reflections of a higher order, where the illumination subsurface has a dimension in a transverse line direction that is greater than half the cross-line distance from a first outermost streamer to a second outermost streamer; and - navigate the research vessel in a research pattern, in which said navigation is based on the determined lighting area subsurface.
    [0002]
    Method according to claim 1, characterized in that said towing includes towing the plurality of sensor streamers (520) in an in-line direction and in a direction in a non-linear path; and in which said gathering includes separating wave fields that propagate upward from wave fields that propagate downward.
    [0003]
    Method of claim 1, characterized by the fact that primary reflections and reflections of a higher order are produced using a single source of energy towed by the research vessel; and wherein the plurality of sensor streamers (520) is towed in a direction in a normal line to the direction in a transverse line.
    [0004]
    Method according to claim 1, characterized in that the plurality of sensor streamers (520) includes the first outermost streamer, the second outermost streamer, a third streamer adjacent to the first outermost streamer and a fourth streamer adjacent to the second outermost streamer; and in which the lighting area subsurface has a dimension in a transverse direction in which the dimension is at least the sum of 1) the transverse line distance between the third streamer and the fourth streamer, 2) half the in-line distance transverse between the first outermost streamer and the third streamer, and 3) half the distance in transverse line between the second outermost streamer and the fourth streamer.
    [0005]
    Method according to claim 4, characterized by the fact that primary reflections and reflections of a higher order are produced using a single energy source.
    [0006]
    Method according to claim 1, characterized by the fact that the lighting surface subsurface has a dimension in a transverse line direction that is at least 95% of the transverse line distance from the first outermost streamer to the second streamer outermost.
    [0007]
    The method of claim 1, characterized by the fact that said navigation includes implementing a trigger sampling plan based on a dimension of the sub-surface of the lighting area and in which the sub-surface of the lighting area has a dimension in a line direction that is greater than the line distance between: a first position located at a midpoint between a power source and a more forward position of sensors along the plurality of sensor streamers (520); and a second position located at a midpoint between the power source and a more posterior position of sensors along the plurality of sensor streamers (520).
    [0008]
    Method according to claim 1, characterized by the fact that said navigation includes implementing a trigger sampling plan based on a dimension of the sub-surface of the lighting area in which the sub-surface of the lighting area has a dimension in a line direction which is greater than the distance in line between: a first position located at a midpoint between a power source and a more forward position of sensors along the plurality of sensor streamers (520); and a second position located at a midpoint between a rearmost position and the next rearmost position of sensors along the plurality of sensor streamers (520).
    [0009]
    Method characterized by understanding: determine an identifiable subsurface of illumination area from primary reflections and reflections of a higher order detected by sensors along a plurality of sensor streamers (520) that are towed by a research vessel, and determine the subsurface of illumination area it comprises determining a dimension in a transverse line direction that is greater than half the transverse line distance from a first outermost streamer to a second outermost streamer; and determine a survey pattern for the survey vessel based on the specified lighting area subsurface.
    [0010]
    Method according to claim 9, characterized by the fact that detecting primary reflections and reflections of a higher order includes the research vessel identifying wave fields that have propagated upwards and wave fields that propagate downwards.
    [0011]
    Method according to claim 9, characterized by the fact that said determination of the lighting surface subsurface includes: a data acquisition system (710) from the research vessel that tracks locations of the plurality of sensor streamers (520); and the data acquisition system (710) which determines an instantaneous subsurface of lighting area based on locations.
    [0012]
    Method according to claim 11, characterized by the fact that said research pattern determination includes: select a course for the research vessel based on the instantaneous subsurface of the lighting area; and providing the selected course for a survey vessel's navigation system (720), in which the navigation system (720) is configured to adjust the current survey vessel's course to be the selected course.
    [0013]
    Method according to claim 9, characterized in that said determination of the subsurface of the lighting area includes determining a dimension in a transverse line direction that is at least 95% of the transverse line distance from the first outermost streamer to the second outermost streamer.
    [0014]
    Method according to claim 9, characterized by the fact that it still comprises: determine a survey firing plan based on the subsurface of the lighting area; and adjust the survey firing plan that responds to a change in the lighting area subsurface.
    [0015]
    Method according to claim 9, characterized by the fact that it still comprises: determine a survey firing plan based on the lighting area subsurface in which the lighting area subsurface has a dimension in a line direction in which the dimension is greater than the line distance between: a first position located at a midpoint between the power source and a more forward position of sensors along the plurality of sensor streamers (520); and a second position located at a midpoint between a rearmost position and the next rearmost position of sensors along the plurality of sensor streamers (520).
    [0016]
    System characterized by understanding: a data acquisition system (710) configured to gather information detected in sensors over a plurality of streamers (520) sensors that are towed behind a research vessel, in which the collected information includes data that correspond to primary reflections and to data that correspond to reflections of a higher order; a navigation system (720) configured to navigate the search vessel in a search pattern in which the search pattern is based on a subsurface of illuminable area identifiable from the data corresponding to the primary reflections and the data corresponding to the reflections of higher order, and where the lighting surface subsurface has a dimension in a transverse line direction that is greater than half the transverse distance from the first outermost streamer to the second outermost streamer.
    [0017]
    The system of claim 16, characterized by the fact that it still comprises: the plurality of sensor streamers (520), in which the plurality of sensor streamers (520) includes: the first outermost streamer, the second outermost streamer and two or more streamers (520) placed between the first and second streamers (520) more exterior, and a single source of energy towed behind the marine research ship, in which the single source of energy is configured to produce waveforms that correspond to primary reflections and reflections of a higher order.
    [0018]
    System according to claim 16, characterized by the fact that it still comprises: the plurality of sensor streamers (520) in which the plurality of sensor streamers (520) includes: the first outermost streamer the second outermost streamer a third streamer adjacent to the first outermost streamer; and a fourth streamer adjacent to the second outermost streamer; and in which the lighting area subsurface has a dimension in a transverse line direction that is at least the sum of: the transverse line distance between the third streamer and the fourth streamer; half the cross-line distance between the first outermost streamer and the third streamer; and half the cross-line distance between the second outermost streamer and the fourth streamer.
    [0019]
    System according to claim 16, characterized by the fact that the subsurface of the lighting area has a dimension in a transverse line direction that is at least 95% of the transverse line distance from the first outermost streamer to the second streamer outermost.
    [0020]
    System according to claim 16, characterized by the fact that the lighting surface subsurface has a dimension in a line direction that is greater than the line distance between: a first position located at a midpoint between a power source and a more forward position of sensors along the plurality of sensor streamers (520); and a second position located at a midpoint between the power source and a more rear position of sensors along the plurality of sensor streamers (520).
    类似技术:
    公开号 | 公开日 | 专利标题
    BR102013013317B1|2021-02-17|method and system for marine seismic survey standard for a research vessel
    AU2003236480B2|2008-03-06|Method for suppressing noise from seismic signals by source position determination
    US10520623B2|2019-12-31|Methods and systems for marine survey acquisition
    US8456953B2|2013-06-04|Wave equation illumination
    BR102014005983B1|2021-05-25|method of activating multiple sources towed by one or more research vessels, computer system for pseudorandomization of the order in which multiple sources are triggered, computer readable medium and seismic data acquisition system
    US7869303B2|2011-01-11|Method for noise suppression in seismic signals using spatial transforms
    MX2007002733A|2007-04-24|System for the attenuation of water bottom multiples in seismic data recorded by pressure sensors and particle motion sensors.
    US20140022863A1|2014-01-23|Interpolation and/or extrapolation of seismic data
    BRPI0917809A2|2019-09-03|attenuation of seismic interference by the use of a dual sensor recording system
    BR102014005630B1|2021-05-25|seismic source operation method, marine seismic data acquisition system, non-transient computer readable medium and computer system for seismic source operation
    CN110073245A|2019-07-30|Constraint to the shake of source actuating
    BR102015013658B1|2021-09-21|METHOD AND SYSTEM OF SEISMIC IMAGE CREATION USING HIGHER ORDER REFLECTIONS AND NON- TRANSIENT COMPUTER READIBLE MEDIUM
    BR102014015913A2|2015-10-06|research techniques using cords at different depths
    US10215871B2|2019-02-26|Method and system of suppressing data corresponding to noise using a model of noise propagation along a sensor streamer
    US11016208B2|2021-05-25|Highly-sparse seabed acquisition designs adapted for imaging geological structure and/or monitoring reservoir production
    US20160238726A1|2016-08-18|Crosstalk Attenuation for Seismic Imaging
    BR102014007974A2|2015-11-03|acquisition method and system for mixed seismic data
    BR102018071736A2|2019-06-04|MATRIXES OF TUNED SEISMIC SOURCE.
    US20170059729A1|2017-03-02|Nodal hybrid gather
    Jin et al.2009|Visibility Analysis and Its Applications to Seismic Data Acquisition and Prestack Imaging
    Zinn1997|Modelling Velocity Gradients in an OBC, First-Break Positioning Algorithm
    Clarke et al.2007|Case Study: A Large 3D Wide-Azimuth Ocean-Bottom Survey in the Deepwater Gulf of Mexico
    BR102016015148A2|2017-01-03|SEPARATION OF ASCENDANT AND DESCENDENT WAVE FIELDS INCLUDING DIRECT ARRIVAL
    BR132013005721E2|2018-06-26|Seismic Data Processing Appliance
    同族专利:
    公开号 | 公开日
    AU2013205828A1|2013-12-19|
    MX2013006121A|2013-11-29|
    AU2013205828B2|2016-09-22|
    BR102013013317A2|2015-06-23|
    EA201370093A3|2014-05-30|
    CA2815269A1|2013-11-30|
    US9007870B2|2015-04-14|
    US20130322205A1|2013-12-05|
    EP2669714B1|2021-07-21|
    EP2669714A3|2015-11-18|
    MY162785A|2017-07-14|
    CN103454683A|2013-12-18|
    EA201370093A2|2014-03-31|
    CA2815269C|2020-03-31|
    EP2669714A2|2013-12-04|
    EA025450B1|2016-12-30|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP0297852A2|1987-07-02|1989-01-04|Mobil Oil Corporation|Method for real time display of marine seismic survey data coverage|
    US4937793A|1989-05-30|1990-06-26|Halliburton Geophysical Services, Inc.|Processing method for marine seismic surveying utilizing dual streamers|
    US6590831B1|1997-12-30|2003-07-08|Westerngeco L.L.C.|Method and apparatus for controlling and optimizing seismic data acquisition|
    AUPR364701A0|2001-03-09|2001-04-12|Fleming, Ronald Stephen|Marine seismic surveys|
    US6925386B2|2003-09-12|2005-08-02|Pgs Americas, Inc.|Illumination monitoring process for making infill decisions|
    US7359283B2|2004-03-03|2008-04-15|Pgs Americas, Inc.|System for combining signals of pressure sensors and particle motion sensors in marine seismic streamers|
    US7791980B2|2004-05-21|2010-09-07|Westerngeco L.L.C.|Interpolation and extrapolation method for seismic recordings|
    US8391102B2|2005-08-26|2013-03-05|Westerngeco L.L.C.|Automatic systems and methods for positioning marine seismic equipment|
    US7520467B2|2006-03-06|2009-04-21|Northrop Grumman Corporation|Aircraft sensor pod assembly|
    US7835225B2|2006-10-11|2010-11-16|Pgs Geophysical As|Method for attenuating particle motion sensor noise in dual sensor towed marine seismic streamers|
    US7505361B2|2007-04-11|2009-03-17|Pgs Geophysical As|Method for prediction of surface related multiples from marine towed dual sensor seismic streamer data|
    US8681580B2|2008-05-15|2014-03-25|Westerngeco L.L.C.|Multi-vessel coil shooting acquisition|
    US8175765B2|2007-12-13|2012-05-08|Westerngeco L.L.C.|Controlling movement of a vessel traveling through water during a seismic survey operation|
    US7872942B2|2008-10-14|2011-01-18|Pgs Geophysical As|Method for imaging a sea-surface reflector from towed dual-sensor streamer data|
    US8588025B2|2009-12-30|2013-11-19|Westerngeco L.L.C.|Method and apparatus for acquiring wide-azimuth marine data using simultaneous shooting|
    US8949030B2|2011-07-29|2015-02-03|Westerngeco L.L.C.|Attenuating sea-surface ghost wave effects in seismic data|US20140297189A1|2013-03-26|2014-10-02|Cgg Services Sa|Seismic systems and methods employing repeatability shot indicators|
    US9651695B2|2013-09-19|2017-05-16|Pgs Geophysical As|Construction and application of angle gathers from three-dimensional imaging of multiples wavefields|
    US9817143B2|2013-10-30|2017-11-14|Pgs Geophysical As|Methods and systems for constraining multiples attenuation in seismic data|
    US10598807B2|2014-02-18|2020-03-24|Pgs Geophysical As|Correction of sea surface state|
    US10670757B2|2014-02-26|2020-06-02|Pgs Geophysical As|Methods and systems for quantifying coherency and constraining coherency-based separation in simultaneous shooting acquisition|
    US9903966B2|2014-04-14|2018-02-27|Pgs Geophysical As|Seismic data acquisition|
    US9791580B2|2014-04-17|2017-10-17|Pgs Geophysical As|Methods and systems to separate wavefields using pressure wavefield data|
    US9689999B2|2014-06-13|2017-06-27|Pgs Geophysical As|Seismic imaging using higher-order reflections|
    US10132946B2|2014-08-13|2018-11-20|Pgs Geophysical As|Methods and systems that combine wavefields associated with generalized source activation times and near-continuously recorded seismic data|
    US10317553B2|2014-08-13|2019-06-11|Pgs Geophysical As|Methods and systems of wavefield separation applied to near-continuously recorded wavefields|
    US10359526B2|2015-02-20|2019-07-23|Pgs Geophysical As|Amplitude-versus-angle analysis for quantitative interpretation|
    US10317551B2|2015-06-01|2019-06-11|Pgs Geophysical As|Using seabed sensors and sea-surface reflections for structural imaging of a subsurface location in a geological formation|
    US11016208B2|2015-06-01|2021-05-25|Pgs Geophysical As|Highly-sparse seabed acquisition designs adapted for imaging geological structure and/or monitoring reservoir production|
    CN105467453A|2015-12-31|2016-04-06|中国海洋大学|Self-contained marine vertical cable seismic exploration data acquisition system|
    CN105743895A|2016-02-01|2016-07-06|桂林航天工业学院|Data exchanging system based on BDS and UWSNs|
    US10267936B2|2016-04-19|2019-04-23|Pgs Geophysical As|Estimating an earth response|
    US11035970B2|2019-06-19|2021-06-15|Magseis Ff Llc|Interleaved marine diffraction survey|
    法律状态:
    2015-06-23| B03A| Publication of a patent application or of a certificate of addition of invention [chapter 3.1 patent gazette]|
    2018-12-04| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-11-05| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-11-24| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-02-17| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 28/05/2013, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    US13/485,552|US9007870B2|2012-05-31|2012-05-31|Seismic surveying techniques with illumination areas identifiable from primary and higher-order reflections|
    US13/485,552|2012-05-31|
    [返回顶部]