A buoy is configured to record seismic signals while underwater. The buoy includes a body; a buoyancy system configured to control a buoyancy of the body to descend multiple times to a predetermined depth (H) and then resurface with a controlled speed; and a seismic sensor located in the body and co
A buoy is configured to record seismic signals while underwater. The buoy includes a body; a buoyancy system configured to control a buoyancy of the body to descend multiple times to a predetermined depth (H) and then resurface with a controlled speed; and a seismic sensor located in the body and configured to record the seismic signals. The seismic sensor is instructed to record the seismic signals as the buoy travels up and down between the water surface and the predetermined depth.
대표청구항▼
1. A buoy for recording seismic signals while underwater, the buoy comprising: a body;a buoyancy system configured to control a buoyancy of the body to descend multiple times to at least one predetermined depth (H) and then resurface with a controlled speed;a seismic sensor located on the body and c
1. A buoy for recording seismic signals while underwater, the buoy comprising: a body;a buoyancy system configured to control a buoyancy of the body to descend multiple times to at least one predetermined depth (H) and then resurface with a controlled speed;a seismic sensor located on the body and configured to record the seismic signals;a processor configured to instruct the seismic sensor to record the seismic signals at a predetermined time interval;an inertial device configured to determine a relative displacement of the buoy between consecutive recordings;a timing device configured to provide an accurate time such that the recorded seismic signals are associated with a corresponding time and a corresponding relative displacement; anda global positioning system configured to determine initial and final water surface absolute locations of the buoy, wherein the initial water surface absolute location of the buoy is measured by the global positioning system prior to descending to the at least one predetermined depth (H), and the final water surface absolute location is measured by the global positioning system after the buoy resurfaces,wherein the processor is configured to calculate absolute positions for each time when the seismic signals are recorded, based on the relative displacement from the inertial device, the accurate time from the timing device and the initial and final water surface absolute locations of the buoy, andwherein the seismic sensor is instructed to record the seismic signals as the buoy travels up and down between the water surface and the predetermined depth. 2. The buoy of claim 1, wherein the processor is connected to the seismic sensor and the buoyancy system. 3. The buoy of claim 2, wherein the processor is further configured to instruct the buoyancy system to achieve one or more speeds while descending and/or ascending. 4. The buoy of claim 1, wherein the inertial device receives the initial and final water surface absolute locations of the buoy from the global positioning device. 5. The buoy of claim 1, further comprising: a temperature sensor configured to measure a temperature inside the bouy,wherein the timing device is configured to receive the temperature and correct its oscillating to provide an accurate time. 6. The buoy of claim 5, wherein the timing device is a temperature-controlled crystal oscillator. 7. The buoy of claim 1, wherein the global positioning system is configured to determine a water surface absolute location of the buoy when activated by the processor. 8. The buoy of claim 1, wherein the processor is configured to calculate the absolute positions for each time when the seismic signals are recorded, based on input from the inertial device and the timing device. 9. The buoy of claim 8, wherein the processor is configured to correct the absolute positions associated with the recorded data based on the water surface absolute location for the buoy by comparing (i) a resurfacing position of the buoy calculated by the inertial device, and (ii) an actual resurfacing position of the buoy determined by the global positioning system. 10. The buoy of claim 1, further comprising: a beacon configured to emit a radio-frequency signal when surfacing. 11. A system for conducting a marine seismic survey, the system comprising: plural buoys configured to record seismic signals when launched in water;a launching vessel configured to hold and launch the plural buoys along a given path;a recovery vessel configured to recover the plural buoys after the buoys have recorded the seismic signals at plural depths and times,wherein at least one buoy includes,a body,a buoyancy system configured to control a buoyancy of the body to descend multiple times to a predetermined depth (H) and then resurface with a controlled speed,a seismic sensor located in the body and configured to record the seismic signals,a processor configured to instruct the seismic sensor to record the seismic signals at a predetermined time interval,an inertial device configured to determine a relative displacement of the buoy between consecutive recordings,a timing device configured to provide an accurate time such that the recorded seismic signals are associated with a corresponding time and a corresponding relative displacement, anda global positioning system configured to determine initial and final water surface absolute locations of the buoy, wherein the initial water surface absolute location of the buoy is measured by the global positioning system prior to descending to the at least one predetermined depth (H), and the final water surface absolute location is measured by the global positioning system after the buoy resurfaces,wherein the processor is configured to calculate absolute positions for each time when the seismic signals are recorded, based on the relative displacement from the inertial device, the accurate time from the timing device and the initial and final water surface absolute locations of the buoy, andwherein the seismic sensor is instructed to record the seismic signals as the buoy travels up and down between the water surface and the predetermined depth. 12. The system of claim 11, wherein the processor is connected to the seismic sensor and the buoyancy system. 13. The system of claim 12, wherein the processor is further configured to instruct the buoyancy system to achieve one or more speeds while descending and/or ascending. 14. The system of claim 11, wherein another buoy comprises: another inertial device configured to determine a relative displacement of the another buoy between a current position at which the seismic signals are recorded and a previous position at which the seismic signals were recorded,another timing device configured to provide an accurate time such that recorded seismic signals are associated with a corresponding time and a corresponding relative displacement, andanother global positioning system configured to determine a water surface absolute location of the another buoy. 15. The buoy of claim 11, wherein the processor is configured to correct the absolute positions of the recorded data based on the water surface absolute location of the buoy by comparing (i) a resurfacing position of the buoy calculated by the inertial device, and (ii) an actual resurfacing position of the buoy determined by the global positioning system. 16. The system of claim 11, further comprising: at least one source vessel. 17. A method for recording seismic signals with buoys, the method comprising: instructing at least one buoy to move up and down between a predetermined depth and the water surface;recording the seismic signals with the at least one buoy at various depths between the predetermined depth and the water surface during a single trip;time-stamping the seismic signals;recording relative displacements, based on an input from an inertial system, of the at least one buoy between consecutive recordings;determining initial and final water surface absolute locations of the buoy, wherein the initial water surface absolute location of the buoy is measured by a global positioning system prior to descending to the at least one predetermined depth, and the final water surface absolute location is measured by the global positioning system after the buoy resurfaces; andcalculating absolute positions for each time when the seismic signals are recorded based on the relative displacements, the time-stamping, and the initial and final water surface absolute locations of the buoy. 18. The method of claim 17, further comprising: correcting the absolute positions based on input from the global positioning system when a difference between (i) a resurfacing position of the buoy calculated by the inertial device, and (ii) an actual resurfacing position of the buoy determined by the global positioning system is larger than a given threshold. 19. The method of claim 17, further comprising: controlling a speed of the buoy in the water to minimize flow noise. 20. A computer readable medium including computer executable instructions, wherein the instructions, when executed by a processor, implement a method for recording seismic signals with buoys, the method comprising: instructing at least one buoy to move up and down between a predetermined depth and the water surface;recording the seismic signals with the at least one buoy at various depths between the predetermined depth and a water depth close to the water surface during a single trip;time-stamping the seismic signals;recording relative displacements, based on input from an inertial system, of the at least one buoy between consecutive recordings;determining initial and final water surface absolute locations of the buoy, wherein the initial water surface absolute location of the buoy is measured by a global positioning system prior to descending to the at least one predetermined depth, and the final water surface absolute location is measured by the global positioning system after the buoy resurfaces; andcalculating absolute positions for each time when the seismic signals are recorded based on the relative displacements, the time-stamping, and the initial and final water surface absolute locations of the buoy.
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이 특허에 인용된 특허 (5)
Bary, R?nate; Meynier, Patrick, Acquisition method and device for seismic exploration of a geologic formation by permanent receivers set on the sea bottom.
Sparks David C. (Lansing MI) Belfie Luke (Gilletts Lake MI) Bruder Dave (Jackson MI) Werner Christian T. (Clark Lake MI) Widenhofer James W. (Jackson MI), Buoyancy control system.
Vandenbroucke, Eric, Method and device intended for seismic exploration of an underwater subsurface zone using seismic receivers coupled with the water bottom.
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