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WAVSEIS SOURCING

20210109240 · 2021-04-15

    Inventors

    Cpc classification

    International classification

    Abstract

    Improved methods of providing acoustic source signals for seismic surveying, wherein a plurality of signals can be easily separated from one another after data acquisition, wherein the source signals are not sweep based.

    Claims

    1. A plurality of seismic source signals for seismic surveying, said each seismic source signal having a length t, a plurality of frequencies and a plurality of amplitudes at a plurality of times, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially by more than 6 notes, and wherein said plurality of seismic source signals are each unique and do not substantially overlap in frequency and amplitude and rhythm such that they can be distinguished from each other.

    2. The plurality of plurality of seismic source signals of claim 1, wherein said plurality of patterns were confirmed by cross-correlation to not substantially overlap.

    3. The plurality of seismic source signals of claim 1 or 2, which do not substantially overlap in timbre.

    4. The plurality of seismic source signals of claim 1 or 2, which do not substantially overlap in phase.

    5. A plurality of n seismic source signals for seismic surveying, said each seismic source signal having a length t (t.sub.1, t.sub.2 . . . t.sub.n), and having a pattern p (p.sub.1, p.sub.2 . . . p.sub.n), comprising a plurality of frequencies and a plurality of amplitudes at a plurality of times, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially over an entirety of said length, and wherein said plurality of seismic source signals patterns (p.sub.1, p.sub.2 . . . p.sub.n) do not substantially overlap in frequency, rhythm or amplitude such that they can be distinguished from each other.

    6. The plurality of plurality of seismic source signals of claim 5, wherein said plurality of seismic source patterns were confirmed by cross correlation to not substantially overlap.

    7. The plurality of n seismic source signals of claim 5 or 6, which do not overlap in timbre.

    8. The plurality of n seismic source signals of claim 5 or 6, which do not overlap in phase.

    9. A method of acquiring seismic survey data, comprising: a) providing one or more electric or hydraulic vibratory sources; b) each vibratory source providing a different acoustic signal pattern p (p.sub.1, p.sub.2 . . . p.sub.n), having a length t (t.sub.1, t.sub.2 . . . t.sub.n); c) each pattern (p.sub.1, p.sub.2 . . . p.sub.n) comprising a plurality of frequencies and a plurality of amplitudes, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially; d) confirming that said plurality of seismic source signals patterns (p.sub.1, p.sub.2 . . . p.sub.n) do not substantially overlap such that they can be separated from each other, and if not changing one ore more seismic source signals patterns or a portion thereof and repeating step d; e) applying said patterns to a reservoir, and f) acquiring reflected and refracted seismic signal data at one or more receivers; and, g) processing said signal data to create a seismic survey.

    10. The method of claim 9, wherein confirming step d) uses cross-correlating two patterns and changing one of them to maximize the separability, and repeating for each pair of patterns.

    11. The method of claim 9, wherein said processing includes separating reflected and refracted seismic signal data from each of said patterns.

    12. The method of claim 11, wherein said separating step uses inversion.

    13. The method of claim 11, wherein said separating step uses an iterative adaptive subtraction method.

    14. A method of surveying a reservoir, comprising: a) providing one or more electric vibratory sources near a reservoir; b) each vibratory source providing a different acoustic signal pattern p (p.sub.1, p.sub.2 . . . p.sub.n), having a length t (t.sub.1, t.sub.2 . . . t.sub.n); c) each pattern (p.sub.1, p.sub.2 . . . p.sub.n) comprising a plurality of frequencies and a plurality of amplitudes having a rhythm, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially for more than 6 notes over length t; d) confirming by cross correlation that said plurality of patterns (p.sub.1, p.sub.2 . . . p.sub.n) do not substantially overlap such that they can be separated from each other, and if not, altering one or both of said patterns to maximize a separability of said patterns; e) applying said patterns to said reservoir; f) acquiring reflected and refracted signal data at one or more receivers; g) separating said signal data from each of said patterns to produce separated data; h) processing said separated data to produce processed data; i) displaying a graphical representation of said reservoir based on said processed data.

    15. The method of claim 14, wherein said separating step uses inversion.

    16. The method of claim 14, wherein said separating step uses an iterative adaptive subtraction method.

    17. The method of claim 14, wherein said patterns are applied to said reservoir simultaneously.

    18. The method of claim 14, wherein said patterns are applied to said reservoir sequentially.

    19. A plurality of seismic source songs for seismic surveying, said each seismic source song having a length and a series of notes having non-sequentially varying frequencies and a rhythm, wherein said plurality of frequencies does not vary sequentially over more than 6 notes, and wherein said plurality of seismic source songs are each unique and do not overlap for more than 4 notes in frequency or rhythm such that plurality of seismic source signals songs can be distinguished from each other.

    20. The plurality of seismic source songs of claim 19, which do not overlap in timbre.

    21. The plurality of seismic source songs of claim 19, which do not overlap in amplitude.

    22. The plurality of seismic source songs of claim 19, which do not overlap in phase.

    23. The plurality of seismic source songs of claim 19, which do not vary sequentially for more than 4 notes.

    24. The plurality of seismic source songs of claim 19, which do not overlap in harmonics.

    Description

    BRIEF DESCRIPTION OF THE DRAWINGS

    [0067] FIG. 1 is an elevation view of an electric seismic source vehicle.

    [0068] FIG. 2 is an enlarged fragmentary view of an electromechanical linear motor assembly for delivering seismic energy into the ground.

    [0069] FIG. 3 is an enlarged perspective fragmentary view of a grid of electro mechanical linear motor assemblies for cooperatively delivering seismic energy into the ground.

    [0070] FIG. 4 shows a single, linear sweep signal with unvarying amplitude.

    [0071] FIG. 5 shows a non-linear sweep signal. In this case the sweep has an exponential increase over time.

    [0072] FIG. 6 an envelope constrained chirp, wherein the chirp is constrained by the Blackman-Harris window.

    [0073] FIG. 7. The Kaiser window and plateau width parameters can be adjusted to produce a variety of chirp envelope shapes.

    [0074] FIG. 8 Exemplary song, plotted in 3 dimensions herein (frequency, time and amplitude).

    [0075] FIG. 9 Exemplary song.

    [0076] FIG. 10. Exemplary song.

    DETAILED DESCRIPTION

    [0077] The disclosure provides a new method for generating sweep-independent source signals for use in seismic surveying. The new methodology is called “WavSeis,” and preferably uses electric vibrators, which can produce high fidelity, complex signals more like a song than a simple frequency sweep or the very limited variations thereon that are currently available.

    Electric Vibrator

    [0078] Although the method can use any high fidelity signal generator, one suitable generator has been invented by the inventors herein, and it may be a preferred source. FIG. 1 illustrates an electric vibrator actuator vehicle 10 comprising a chassis 12, four wheels 15 and a driver's cab 18. The source 10 uses a diesel engine 21 to turn an electric generator 23 making electrical power for delivering acoustic energy into the ground. A large battery, capacitor bank or both 24 may be included to store energy for high load situations of high electrical demand or when there are problems with the generator 23, but the battery 24 could also provide the power to return to base for repair.

    [0079] In FIGS. 2 and 3, the acoustic energy delivery system 30 is carried under the chassis 12 and comprises a frame 32 including mounts for a number of linear motors 35. Each linear motor 35 includes a tubular body 36 and a rod 38 within the tubular body 36 that can extend telescopically from the lower end of the tubular body 36. A replaceable foot 39 is attached to the bottom end of the rod 38 for contacting the ground.

    [0080] In operation, the frame 32 is lowered to the ground and the linear motors 35 are actuated to lower the replaceable feet 39 into contact with the ground G. Once all of the replaceable feet 39 are in contact with the ground G, the linear motors 35 are activated in some desired order to thrust the rods 38 toward the ground G and thereby deliver an impulse into the earth. The linear motors 35 are quickly operated to recoil the rods 38 without disengaging contact with the ground G by the replaceable feet 39. By successive thrusts and recoils, acoustic energy is effectively delivered into the earth while the feet remain in contact with the ground G.

    [0081] Electric linear motors 35 do not suffer the limitations of the hydraulic pumping systems. Cycling electric power to the linear motors 35 allows controlled movement of the rods 38 within the tubular bodies 36 and with such instant response, that the impulse frequency range is greatly expanded. By using electrical control circuits that are commonly available for diesel electric train locomotives and hybrid cars, the power can be applied instantly with a very high degree of control and stabilization. Linear motors are highly controllable due to the ability to control the force and velocity of the rods 38 via changes in the voltage and amperage of the applied current. Also the back-EMF generated can be accurately used as a feedback circuit to compensate for variations in the wear patterns and ground impedance variations so that the combined chirp of the whole group of linear motors is consistent and repeatable.

    WavSeis Songs

    [0082] Exemplary songs are plotted in a 3D manner in FIGS. 8, 9 and 10.

    [0083] The present methods includes any of the following embodiments in any combination(s) of one or more thereof: [0084] A plurality of seismic source signals for seismic surveying, said each seismic source signal having a length t, a plurality of frequencies and a plurality of amplitudes at a plurality of times, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially by more than 6, 5, 4, or 3 notes or frequencies, and wherein said plurality of seismic source signals are each unique and do not substantially overlap in frequency and amplitude and rhythm such that they can be distinguished from each other. [0085] A plurality of n seismic source signals for seismic surveying, said each seismic source signal having a length t (t1, t2 . . . tn), and having a pattern p (p1, p2 . . . pn), comprising a plurality of frequencies and a plurality of amplitudes at a plurality of times, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially throughout said length, and wherein said plurality of seismic source signals patterns (p1, p2 . . . pn) do not substantially overlap in frequency, rhythm or amplitude such that they can be distinguished from each other. [0086] A plurality of seismic source songs for seismic surveying, said each seismic source song having a length and a series of notes having non-sequentially varying frequencies and a rhythm, wherein said plurality of frequencies does not vary sequentially (e.g. increasing or decreasing sequentially) over more than 6, 5, 4 or 3 notes, and wherein said plurality of seismic source songs are each unique and preferably do not overlap at all, or do not overlap for more than 1, 2, 3 or 4 notes in frequency or rhythm such that plurality of seismic source signals songs can be distinguished from each other. [0087] A plurality of plurality of seismic source signals as herein described, wherein said plurality of patterns were confirmed by cross correlation to not substantially overlap. [0088] A plurality of plurality of seismic source signals as herein described, which do not overlap in timbre, phase, harmonics, rhythm, pitch, etc, or at least do not overlap for more than 2 or 3 or 4 sequential notes. [0089] A method of acquiring seismic survey data, comprising: [0090] a) providing one or more electric or hydraulic vibratory sources; [0091] b) each vibratory source providing a different acoustic signal pattern p (p1, p2 . . . pn), having a length t (t1, t2 . . . tn); [0092] c) each pattern (p1, p2 . . . pn) comprising a plurality of frequencies and a plurality of amplitudes, wherein said plurality of frequencies and plurality of amplitudes do not vary sequentially over said entire length; [0093] d) confirming that said plurality of seismic source signals patterns (p1, p2 . . . pn) do not substantially overlap such that they can be separated from each other, and if not changing one ore more seismic source signals patterns or a portion thereof and repeating step d; [0094] e) applying said patterns to a reservoir, and [0095] f) acquiring reflected and refracted seismic signal data at one or more receivers; and,

    [0096] g) processing said signal data to create a seismic survey. [0097] A method as herein described, wherein confirming step d) uses cross-correlating two patterns and changing one of them to maximize the separability, and repeating for each pair of patterns. [0098] A method as herein described, wherein said processing includes separating reflected and refracted seismic signal data from each of said patterns. Preferably, the separating step uses inversion or the separating step uses an iterative adaptive subtraction method. [0099] A method of surveying a reservoir, comprising: [0100] a) providing one or more electric vibratory sources near a reservoir; [0101] b) each vibratory source providing a different acoustic signal pattern p (p1, p2 . . . pn), having a length t (t1, t2 . . . tn); [0102] c) each pattern (p1, p2 . . . pn) comprising a plurality of frequencies and a plurality of amplitudes having a rhythm, wherein said plurality of frequencies and plurality of amplitudes do not increase or decrease sequentially for more than 3 notes over length t; [0103] d) confirming by cross-correlation that said plurality of patterns (p1, p2 . . . pn) do not substantially overlap such that they can be separated from each other, and if not, altering one or both of said patterns to maximize a separability of said patterns; [0104] e) applying said patterns to said reservoir; [0105] f) acquiring reflected and refracted signal data at one or more receivers; [0106] g) separating said signal data from each of said patterns to produce separated data; [0107] h) processing said separated data to produce processed data; [0108] i) preparing a graphical representation of said reservoir based on said processed data. [0109] A method as herein described, wherein said patterns are applied to said reservoir simultaneously, or are applied to said reservoir sequentially.

    [0110] The following references are incorporated by reference in their entirety.

    [0111] Bagaini, Land Seismic Techniques for High Quality Data, Oilfield Review 22 (2): 28-39 (2010).

    [0112] Bagaini, Overview of Efficient Vibroseis Acquisition Methods, EAGE 68th Conference & Exhibition—Vienna, Austria, 12-15 Jun. 2006.

    [0113] CHIU, Stephen K., EICK, Peter, P., and EMMONS, Charles W., “High Fidelity Vibratory Seismic (HFVS): Optimal Phase Encoding Selection”, SEG/Houston 2005 Annual Meeting, p. 37-39.

    [0114] Huo S. & Wang Y. Improving adaptive subtraction in seismic multiple attenuation. GEOPHYSICS, 74 (4), V59-V67 (2009).

    [0115] Mandad, A., et al. Separation of blended data by iterative estimation and subtraction of blending interference noise. GEOPHYSICS, 76 (3), Q9-Q17 (2011).

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