A sea-floor electromagnetic measurement device for obtaining underwater measurements of earth formations including a central structure and arms attached to the central structure so that they can pivot relative to the central structure. An electrode is attached to the end of each of the arms or to th
A sea-floor electromagnetic measurement device for obtaining underwater measurements of earth formations including a central structure and arms attached to the central structure so that they can pivot relative to the central structure. An electrode is attached to the end of each of the arms or to the central structure, and/or magnetometers are attached to the arms. A method for undertaking sea-floor electromagnetic measurements of earth formations including measuring electric fields at a selected distance from a central structure of an electromagnetic measurement system. Magnetic fields are then measured at the same location.
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1. A sea-floor electromagnetic measurement device for obtaining underwater measurements of earth formations, comprising:a central structure; a plurality of arms having a first end and a second end, the second end pivotally coupled to the central structure, the first end being a free end; at least on
1. A sea-floor electromagnetic measurement device for obtaining underwater measurements of earth formations, comprising:a central structure; a plurality of arms having a first end and a second end, the second end pivotally coupled to the central structure, the first end being a free end; at least one electrode coupled to each of the arms; and at least two magnetometers coupled to ones of the arms, wherein the magnetometers are positioned a selected distance from the central structure so that magnetic fields produced by electric currents in the central structure do not substantially affect the measurements made by the magnetometers. 2. The measurement device of claim 1, wherein the plurality of arms comprises four arms arranged so as to form a cross dipole pattern.3. The measurement device of claim 1, wherein each electrode is disposed proximate the first end of each arm.4. The measurement device of claim 1, wherein each of the arms comprises a cross-section adapted to minimize drag when the measurement device is deployed in and retrieved from the sea.5. The measurement device of claim 1, wherein each of the arms comprises a substantial elliptical cross section.6. The measurement device of claim 1, wherein the arms are adapted to pivot in a vertical direction with respect to the central structure.7. The measurement device of claim 1, wherein the electrodes and the magnetometers are substantially dynamically decoupled from the central structure.8. The measurement device of claim 1, wherein each of the plurality of arms comprises a fiberglass rod.9. The measurement device of claim 1, wherein each magnetometer comprises a tiltmeter.10. The measurement device of claim 1 wherein the at least two magnetometers are positioned orthogonally with respect to each other.11. The measurement device of claim 1 wherein the magnetometers are pressure compensated.12. The measurement device of claim 1 wherein the magnetometers are dB/dt induction sensors.13. The measurement device of claim 1, wherein the at least two magnetometers are disposed proximate the first ends of adjacent arms.14. The measurement device of claim 13, wherein the at least two magnetometers are coupled to the arms by cables.15. The measurement device of claim 1, wherein to second end of each arm is pivotally coupled to the central structure with a hinge.16. The measurement device of claim 15, wherein each hinge is adapted to distribute torsional forces generated by motion of the arms relative to the central structure.17. The measurement device of claim 1, further comprising electronic circuitry adapted to control the measurement system and to record at least one of electric field measurements of the electrodes and magnetic field measurements of the magnetometers.18. The measurement device of claim 17 wherein the circuitry is adapted to transmit the at least one of electric and magnetic measurements to a remote location.19. The measurement device of claim 17 wherein the circuitry is adapted to record the at least one of electric and magnetic measurements in response to a remote location.20. The measurement device of claim 1 wherein each arm comprises a tube, the second end pivotally coupled to the central structure and the first end comprising an opening to allow the entrance of ocean water.21. The measurement device of claim 20 wherein each electrode is included inside each tube proximate to the second end thereof.22. The measurement device of claim 21 wherein each electrode is coupled to the central structure.23. A sea-floor electromagnetic measurement device for obtaining underwater measurements of earth formations, comprising:a central structure; a plurality of arms having a first end and a second end, the second end pivotally coupled to the central structure, the first end being a free end; and at least one of an electrode and a magnetometer coupled to each of the arms; and wherein the magnetometer is positioned a selected distance from the central structure so that magnetic fields produced by electric currents in the central structure do not substantially affect the measurements made by the magnetometer. 24. The measurement system of claim 23, wherein the plurality of arms comprises four arms arranged so as to form a cross dipole pattern.25. The measurement device of claim 23, wherein each electrode is disposed proximate the first end of each arm.26. The measurement device of claim 23, wherein each of the arms comprises a cross-section adapted to minimize drag when the measurement device is deployed in and retrieved from the set.27. The measurement device of claim 23, wherein each of the arms comprises a substantially elliptical cross-section.28. The measurement device of claim 23, wherein the arms are adapted to pivot in a vertical direction with respect to the central structure.29. The measurement device of claim 23, wherein the electrodes and the magnetometers are substantially dynamically decoupled from the central structure.30. The measurement system of claim 23, wherein each of the plurality of arms comprises a fiberglass rod.31. The measurement device of claim 23, wherein each magnetometer comprises a tiltmeter.32. The measurement device of claim 23, further comprising two magnetometers positioned orthogonally with respect to each other.33. The measurement device of claim 23 wherein the magnetometer is pressure compensated.34. The measurement device of claim 23 wherein the magnetometer is a dB/dt induction sensor.35. The measurement device of claim 23, wherein each magnetometer is disposed proximate the first ends of adjacent arms.36. The measurement device of claim 35, wherein each magnetometer is coupled to a corresponding one of the arms by cables.37. The measurement device of claim 23, wherein the second end of each of the arms is pivotally coupled to the central structure with a hinge.38. The measurement device of claim 37, wherein each hinge is adapted to distribute torsional forces generated by motion of the arms relative to the central structure.39. The measurement device of claim 23, further comprising electronic circuitry adapted to control the measurement device and to record at least one of electric field measurements of the electrodes and magnetic field measurements of the magnetometers.40. The measurement device of claim 39 wherein the circuitry is adapted to transmit the at least one of electric and magnetic fields measurements to a remote location.41. The measurement device of claim 39 wherein the circuitry is adapted to record the at least one of electric and magnetic fields measurements in response to a remote location.42. The measurement device of claim 23 wherein each arm comprises a tube, the second end pivotally coupled to the central structure and the first end comprising an opening to allow the entrance of ocean water.43. The measurement device of claim 42 wherein cash electrode is included inside each tube proximate to the second end thereof.44. The measurement device of claim 43 wherein each electrode is coupled to the central structure.45. A sea-floor electromagnetic measurement device for obtaining underwater measurements of earth formations, comprising:a central structure; at least one arm, having a first end and a second end, the second end pivotally coupled to the central structure, the first end being a free end; and at least one of an electrode and a magnetometer, coupled to the at least one arm; and wherein the magnetometer is positioned a selected distance from the central structure so that magnetic fields produced by electric currents in the central structure do not substantially affect the measurements made by the magnetometer. 46. The measurement device of claim 45, wherein the electrode is disposed proximate the first end of the at least one arm.47. The measurement device of claim 45, wherein the at least one arm comprises a cross-section adapted to minimize drag when the measurement device is deployed in and retrieved from the sea.48. The measurement device of claim 45, wherein the at lest one arm comprises a substantially elliptical cross-section.49. The measurement device of claim 45, wherein the at least one arm is adapted to pivot in a vertical direction with respect to the central structure.50. The measurement device of claim 45, wherein the electrode and the magnetometer are substantially dynamically decoupled from the central structure.51. The measurement device of claim 45, wherein the at least one arm comprises a fiberglass rod.52. The measurement device of claim 45, wherein the magnetometer comprises a tiltmeter.53. The measurement device of claim 45 wherein the magnetometer is pressure compensated.54. The measurement device of claim 45 wherein the magnetometer is a dB/dt induction sensor.55. The measurement device of claim 45, wherein the magnetometer is disposed proximate the first end of the at least one arm.56. The measurement device of claim 55, wherein the magnetometer is coupled to the arm by cables.57. The measurement device of claim 45, wherein the second end of the at least one arm is pivotally coupled to the central structure with a hinge.58. The measurement device of claim 57, wherein the binge is adapted to distribute torsional forces generated by motion of the arm relative to the central structure.59. The measurement device of claim 45 wherein the at least one arm comprises a tube, the second end pivotally coupled to the central structure and the first end comprising an opening to allow the entrance of ocean water.60. The measurement device of claim 59 wherein each electrode is included inside each tube proximate to the second end thereof.61. The measurement device of claim 60 wherein each electrode is coupled to the central structure.62. The measurement device of claim 45, further comprising electronic circuitry adapted to control the measurement device and to record at least one of electric field measurements of the electrodes and magnetic field measurements of the magnetometers.63. The measurement device of claim 62 wherein the circuitry is adapted to transmit the at least one of electric and magnetic fields measurements to a remote location.64. The measurement device of claim 62 wherein the circuitry is adapted to record the at least one of electric and magnetic fields measurements in response to a remote location.65. A method of undertaking sea-floor electromagnetic measurements, the method comprising:measuring components of magnetic fields at a location a selected distance from a central structure of an electromagnetic measurement system so that magnetic fields produced by electric currents in the central structure substantially do not affect the measurements made by a magnetometer; and measuring electric fields proximate the same location. 66. The method of claim 65 wherein the electric fields are cross dipole electric fields.67. The method of claim 65 wherein the components of magnetic fields are orthogonal.
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