Non-invasive, opto-acoustic water current measurement system and method
First Claim
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1. A method of measuring water current, comprising the steps of:
- transmitting a beam of optical radiation to be incident at a target location on the surface of a body of water at an angle with respect to the surface, said beam being modulated by an acoustic frequency wherein, as said beam transits the water, energy from said beam is absorbed by the water thereby generating acoustic radiation in the water that propagates away from said beam as said beam transits the water such that a portion of said acoustic radiation propagates to the surface and experiences a Doppler shift in frequency relative to said acoustic frequency due to current in the water through which said portion transits wherein said portion exhibits a Doppler-shifted frequency; and
measuring said Doppler-shifted frequency associated with said portion of said acoustic radiation as an indication of water current.
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Abstract
A method and system are provided for measuring water current. An acoustically-modulated beam of radiation is transmitted to a target location on the surface of a body of water. As the beam transits the water, acoustic radiation propagates away from the beam towards the surface and experiences a Doppler shift in frequency relative to the acoustic frequency used for modulation. The Doppler shift is caused by current in the water through which the acoustic radiation transits. The Doppler-shifted frequency is measured as an indication of water current.
14 Citations
19 Claims
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1. A method of measuring water current, comprising the steps of:
- transmitting a beam of optical radiation to be incident at a target location on the surface of a body of water at an angle with respect to the surface, said beam being modulated by an acoustic frequency wherein, as said beam transits the water, energy from said beam is absorbed by the water thereby generating acoustic radiation in the water that propagates away from said beam as said beam transits the water such that a portion of said acoustic radiation propagates to the surface and experiences a Doppler shift in frequency relative to said acoustic frequency due to current in the water through which said portion transits wherein said portion exhibits a Doppler-shifted frequency; and
measuring said Doppler-shifted frequency associated with said portion of said acoustic radiation as an indication of water current. - View Dependent Claims (2, 3, 4, 5, 6, 8, 9, 10)
transmitting a plurality of beams of radiation to be incident on the surface at positions surrounding said target location, wherein a corresponding plurality of return beams are generated at the surface, and wherein at least one of said plurality of return beams is modulated by said portion of said acoustic radiation at said Doppler-shifted frequency;
detecting said plurality of return beams;
determining said Doppler-shifted frequency using said at least one of said plurality of return beams; and
determining a difference between said Doppler-shifted frequency and said acoustic frequency, wherein said difference is indicative of water current.
- transmitting a beam of optical radiation to be incident at a target location on the surface of a body of water at an angle with respect to the surface, said beam being modulated by an acoustic frequency wherein, as said beam transits the water, energy from said beam is absorbed by the water thereby generating acoustic radiation in the water that propagates away from said beam as said beam transits the water such that a portion of said acoustic radiation propagates to the surface and experiences a Doppler shift in frequency relative to said acoustic frequency due to current in the water through which said portion transits wherein said portion exhibits a Doppler-shifted frequency; and
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3. A method according to claim 2 wherein said steps of transmitting and detecting are carried out for each of said plurality of beams one at a time.
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4. A method according to claim 2 wherein said step of transmitting is carried out simultaneously for more than one of said plurality of beams.
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5. A method according to claim 1 wherein said angle is in the range of approximately 30-45°
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6. A method according to claim 1 wherein said plurality of beams are distributed evenly throughout a 360°
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8. A method according to claim 1 wherein said step of measuring comprises the steps of:
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transmitting a plurality of beams of radiation to be incident on the surface at positions surrounding said target location, each of said plurality of beams having a wavelength greater than 1000 nanometers, wherein a corresponding plurality of return beams are generated at the surface, and wherein at least one of said plurality of return beams is modulated by said portion of said acoustic radiation at said Doppler-shifted frequency;
detecting said plurality of return beams;
determining said Doppler-shifted frequency using said at least one of said plurality of return beams; and
determining a difference between said Doppler-shifted frequency and said acoustic frequency, wherein said difference is indicative of water current.
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9. A method according to claim 8 wherein said steps of transmitting and detecting are carried out for each of said plurality of beams one at a time.
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10. A method according to claim 8 wherein said step of transmitting is carried out simultaneously for more than one of said plurality of beams.
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7. A method of measuring water current, comprising the steps of:
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transmitting a beam of optical radiation through the air to be incident at a target location on the surface of a body of water at an angle with respect to the surface, said beam having a wavelength in the range of 600-900 nanometers and being modulated by an acoustic frequency wherein, as said beam transits the water, energy from said beam is absorbed by the water thereby generating acoustic radiation in the water that propagates approximately perpendicularly away from said beam as said beam transits the water such that a portion of said acoustic radiation propagates to the surface and experiences a Doppler shift in frequency relative to said acoustic frequency due to current in the water through which said portion transits wherein said portion exhibits a Doppler-shifted frequency; and
measuring said Doppler-shifted frequency associated with said portion of said acoustic radiation as an indication of water current. - View Dependent Claims (11, 12)
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13. A system for measuring water current, comprising:
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means for transmitting a beam of optical radiation to be incident at a target location on the surface of a body of water at an angle with respect to the surface, said beam being modulated by an acoustic frequency wherein, as said beam transits the water, energy from said beam is absorbed by the water thereby generating acoustic radiation in the water that propagates away from said beam as said beam transits the water such that a portion of said acoustic radiation propagates to the surface and experiences a Doppler shift in frequency relative to said acoustic frequency due to current in the water through which said portion transits wherein said portion exhibits a Doppler-shifted frequency; and
means for measuring said Doppler-shifted frequency associated with said portion of said acoustic radiation as an indication of water current. - View Dependent Claims (14, 15, 16, 17, 18, 19)
means for transmitting a plurality of beams of radiation to be incident on the surface at positions surrounding said target location, wherein a corresponding plurality of return beams are generated at the surface, and wherein at least one of said plurality of return beams is modulated by said portion of said acoustic radiation at Doppler-shifted frequency;
means for detecting said plurality of return beams;
means for determining said Doppler-shifted return using said at least one of said plurality of return beams; and
means for determining a difference between said Doppler-shifted frequency and said acoustic frequency, wherein said difference is indicative of water current.
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18. A system as in claim 17 wherein said means for transmitting said plurality of beams includes a laser producing said plurality of beams, wherein each of said plurality of beams has a wavelength of greater than 1000 nanometers.
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19. A system as in claim 17 wherein said means for transmitting said plurality of beams comprises:
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a transmitter for transmitting at least one of said plurality of beams; and
means coupled to said transmitter for rotating said transmitter in a plurality of discrete steps, each of said plurality of discrete steps being indicative of a compass heading.
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Specification