Seismic acquisition system including a distributed sensor having an optical fiber
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01V-005/00
G01V-001/00
G01V-001/38
G01D-005/353
E21B-047/022
E21B-049/08
G01H-009/00
G01V-001/36
G01V-008/00
출원번호
US-0550251
(2014-11-21)
등록번호
US-9316754
(2016-04-19)
발명자
/ 주소
Kragh, Ed
Muyzert, Everhard
Robertsson, Johan
Miller, Douglas E.
Hartog, Arthur H.
출원인 / 주소
Schlumberger Technology Corporation
대리인 / 주소
Groesbeck, David J.
인용정보
피인용 횟수 :
2인용 특허 :
65
초록▼
A seismic acquisition system includes a distributed optical sensor (having an optical fiber) and an interrogation subsystem configured to generate a light signal to emit into the optical fiber. The interrogation subsystem receives, from the distributed optical sensor, backscattered light responsive
A seismic acquisition system includes a distributed optical sensor (having an optical fiber) and an interrogation subsystem configured to generate a light signal to emit into the optical fiber. The interrogation subsystem receives, from the distributed optical sensor, backscattered light responsive to the emitted light signal, wherein the backscattered light is affected by one or both of seismic signals reflected from a subterranean structure and noise. Output data corresponding to the backscattered light is provided to a processing subsystem to determine a characteristic of the subterranean structure.
대표청구항▼
1. A seismic acquisition system, comprising: a distributed optical sensor having an optical fiber for positioning outside a subterranean structure to be surveyed; andan interrogation subsystem configured to: generate a light signal to emit into the optical fiber;receive, from the distributed optical
1. A seismic acquisition system, comprising: a distributed optical sensor having an optical fiber for positioning outside a subterranean structure to be surveyed; andan interrogation subsystem configured to: generate a light signal to emit into the optical fiber;receive, from the distributed optical sensor, backscattered light responsive to the emitted light signal, wherein the backscattered light is affected by one or both of seismic signals reflected from the subterranean structure and noise; andoutput data corresponding to the backscattered light to a processing subsystem to determine a characteristic of the subterranean structure,wherein the distributed optical sensor and interrogation subsystem are configured to provide a spatial resolution having a predefined relationship to wavelength(s) of one or both of the seismic signals and the noise, andwherein the spatial resolution is less than the wavelength of the seismic signals. 2. The seismic acquisition system of claim 1, wherein the distributed optical sensor is arranged for use in one of land-based seismic surveying and marine seismic surveying. 3. The seismic acquisition system of claim 1, wherein the spatial resolution is greater than or equal to the wavelength of the noise. 4. The seismic acquisition system of claim 3, wherein the backscattered light provides a representation of the seismic signals with the noise attenuated. 5. The seismic acquisition system of claim 1, wherein the spatial resolution is less than a wavelength of the noise. 6. The seismic acquisition system of claim 5, wherein both the noise and the seismic signals are sampled in the backscattered light, the seismic acquisition system further comprising: a filter to attenuate the noise represented in the backscattered light. 7. The seismic acquisition system of claim 1, wherein the optical fiber is straight. 8. The seismic acquisition system of claim 1, wherein the optical fiber has curved portions, wherein the curved portions allow for detection of components of the noise and/or components of the seismic signals in plural multiple different directions. 9. The seismic acquisition system of claim 1, further comprising a streamer having the distributed optical sensor for towing through a body of water, wherein parts of the streamer have a diameter less than 4 centimeters. 10. The seismic acquisition system of claim 1, wherein the optical fiber is a first optical fiber dedicated to the distributed optical sensor, and the seismic acquisition system further comprises at least another optical fiber having regions of different sensitivities. 11. A seismic acquisition system, comprising: a distributed optical sensor having an optical fiber for positioning outside a subterranean structure to be surveyed; andan interrogation subsystem configured to: generate a light signal to emit into the optical fiber;receive, from the distributed optical sensor, backscattered light responsive to the emitted light signal, wherein the backscattered light is affected by one or both of seismic signals reflected from the subterranean structure and noise; andoutput data corresponding to the backscattered light to a processing subsystem to determine a characteristic of the subterranean structure,wherein the optical fiber has curved portions, wherein the curved portions allow for detection of components of the noise and/or components of the seismic signals in plural multiple different directions, and wherein the curved portions each has a curvature with a predefined relationship to wavelength(s) of one or both of the noise and the seismic signals. 12. The seismic acquisition system of claim 11, wherein the curvature is less than the wavelength of the seismic signals but greater than or equal to the wavelength of the noise, wherein the backscattered light provides a representation of the seismic signals with the component of the noise having a propagation direction in one of the multiple directions attenuated. 13. The seismic acquisition system of claim 11, wherein the curvature is less than the wavelength of the noise and the wavelength of the seismic signals, the seismic acquisition system further comprising: the processing subsystem to resolve the noise into two perpendicular components that include (1) the component having a propagation direction generally in one of the multiple directions, and (2) a component having a propagation direction generally in another of the multiple directions. 14. A method comprising: providing a distributed optical sensor having an optical fiber for performing a seismic survey of a subterranean structure;emitting light into the optical fiber;receiving backscattered light responsive to the emitted light from the optical fiber, wherein the backscattered light is affected by noise;processing, by a processing subsystem, data relating to the backscattered light, wherein the data relating to the backscattered light represents one of: (1) the noise, (2) the noise and seismic signals reflected from the subterranean structure, and (3) the seismic signals reflected from the subterranean structure with the noise attenuated; andderiving a propagation speed of the noise using the data corresponding to the backscattered light. 15. The method of claim 14, further comprising: providing seismic sensors;receiving seismic data from the seismic sensors; andusing, by the processing subsystem, the data corresponding to the backscattered light to remove the noise from the seismic data of the seismic sensors. 16. The method of claim 15, wherein the distributed optical sensor and the seismic sensors are provided as part of a streamer, the method further comprising: towing the streamer through a body of water. 17. The method of claim 15, wherein the distributed optical sensor and the seismic sensors are provided to perform land seismic acquisition. 18. The method of claim 15, wherein the distributed optical sensor and the seismic sensors are provided as part of a seabed cable.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (65)
Austad, Peter; Rustad, Rolf, Acoustic emitters for use in marine seismic surveying.
Roscigno, John A.; Hodgson, Craig W.; Frederick, Donald A.; Knaack, William C., Acoustic sensing system for downhole seismic applications utilizing an array of fiber optic sensors.
Wetzel, Rodney J.; Pai, Sudhir; Smith, David R.; Howard, Peter V.; Johnson, Craig D.; Danos, Jake A.; Bixenman, Patrick W., Intelligent well system and method.
Tubel Paulo S. (The Woodlands TX) Mullins ; II Albert A. (Humble TX) Jones Kevin R. (Humble TX) Richardson Frank D. (Huntsville TX), Method for controlling production wells having permanent downhole formation evaluation sensors.
Langeland Jan-Åge (Garnes NOX) ÅSheim Stein (Oslo NOX) Nordmoen Bjorn (Oslo NOX) Vigen Erik (Drammen NOX), Method for determining the position of seismic streamers in a reflection seismic measuring system.
Ramos Rogerio T. ; Madhavan Raghu ; Yamate Tsutomu ; Balkunas Stephen C. ; Schroeder Robert J., Methods and apparatus for mechanically enhancing the sensitivity of longitudinally loaded fiber optic sensors.
Chee,Soon Seong; Parmentier,Remy; Wu,Xu; Wilson,Colin; Igarashi,Juei, Optical fiber system and method for wellhole sensing of magnetic permeability using diffraction effect of faraday rotator.
Davidson, Kenneth C.; Kerr, John A.; MacKenzie, Roderick; Johnston, Alan J., System and technique for monitoring and managing the deployment of subsea equipment.
Hartog, Arthur H.; Brown, J. Ernest; Cook, John Mervyn; Elphick, Jonathan; Hammond, Paul S.; Johnson, Ashley Bernard, Systems and methods for distributed interferometric acoustic monitoring.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.