Fiber optic interferometric hydrophone

US 4,751,690 A
Filed: 05/12/1986
Issued: 06/14/1988
Est. Priority Date: 05/12/1986
Status: Expired due to Term

First Claim

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1. A fiber optic interferometric acoustic sensor for measuring an external acoustic field comprising:

means for providing a shell having at least two compartments, each of said at least two compartments having an associated opening in said means for providing a shell, said openings being in an opposed orientation in said means for providing a shell, said means for providing a shell also having a divider between said at least two compartments, said divider having an aperture;

means for providing a bendable beam contained within said means for providing a shell and extending through said aperture in said divider, said means for providing a bendable beam having a first end attached to an end of one of said compartments opposite said divider, having a second end attached to an end of the other of said compartments opposite said divider, and having its midpoint attached to said divider; and

first and second optical fibers attached to opposite sides of said means for providing a bendable beam, said first and second optical fibers extending through said first and second compartments of said means for providing a shell, and crossing over to opposite sides of said means for providing a bendable beam at said divider;

the external acoustic field moving said first and second optical fibers and said means for providing a bendable beam such that said first optical fiber is stretched and said second optical fiber is compressed and vice versa, thereby changing the optical path lengths of both of said first and second optical fibers.

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Abstract

A fiber optic interferometric hydrophone is based on the change in optic path length of optic fibers bonded to both sides of a bending beam which acts as an acoustically sensitive diaphragm.

The bending beam is segmented into an even number of segments, acoustic windows are arranged such that opposite sides of the beam see the acoustic field in adjacent segments, and the optic fibers cross from one side of the beam to the other to maintain the phase of strain signal for the two fibers, one on each side, along the full length of the bending beam. The fringe sensitivity of the interferometer is multiplied by two since both interferometer legs are strained by the acoustic field, and of opposite sign, and further multiplied by the number of segments compared to a single simple beam bender of the dimensions of one segment. This configuraion has the further advantages of cancelling out lateral acceleration noise, and of providing a larger transducer for integrating low level sounds, both of which improve the signal-to-noise level. The small lateral dimensions of such a hydrophone are advantageous in towed arrays. Ancillary equipment such as light source, and detectors, and mechanical packaging for various purposes, are well known in the art.

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16 Claims

1. A fiber optic interferometric acoustic sensor for measuring an external acoustic field comprising:
- means for providing a shell having at least two compartments, each of said at least two compartments having an associated opening in said means for providing a shell, said openings being in an opposed orientation in said means for providing a shell, said means for providing a shell also having a divider between said at least two compartments, said divider having an aperture;
  
  means for providing a bendable beam contained within said means for providing a shell and extending through said aperture in said divider, said means for providing a bendable beam having a first end attached to an end of one of said compartments opposite said divider, having a second end attached to an end of the other of said compartments opposite said divider, and having its midpoint attached to said divider; and
  
  first and second optical fibers attached to opposite sides of said means for providing a bendable beam, said first and second optical fibers extending through said first and second compartments of said means for providing a shell, and crossing over to opposite sides of said means for providing a bendable beam at said divider;
  
  the external acoustic field moving said first and second optical fibers and said means for providing a bendable beam such that said first optical fiber is stretched and said second optical fiber is compressed and vice versa, thereby changing the optical path lengths of both of said first and second optical fibers.
- View Dependent Claims (2, 3, 4)
- - 2. The sensor described in claim 1 wherein said sensor further comprises means for sealing said aperture in said divider such that said compartments are acoustically isolated, said means for sealing also attaching said means for providing a bendable beam and said first and second optical fibers to said divider.
  - 3. The sensor described in claim 1, wherein said sensor further comprises:
    - diaphragms over said openings in said means for providing a shell, said diaphragms responsive to the external acoustic field; and
      
      driving pins attached to said diaphragms and to said means for providing a bendable beam such that the external acoustic field is transferred from said diaphragms to said means for providing a bendable beam by said driving pins.
  - 4. The sensor described in claim 1, wherein said means for providing a shell comprises an even numbered plurality of said compartments separated by a plurality of said dividers with said means for providing a bendable beam and said first and second optical fibers extending through each of said compartments, said first and second optical fibers crossing over to opposite sides of said means for providing a bendable beam at each of said dividers between said compartments, said openings in said means for providing a shell associated with said compartments being in an alternating opposed orientation in said means for providing a shell.

5. A fiber optic interferometric acoustic sensor for measuring an external acoustic field comprising:
- means for producing source light in a predetermined frequency range;
  
  means for splitting the source light, said means for splitting having an input for receiving the source light and having first and second output ports for outputting split source light;
  
  means for recombining light, said means for recombining having first and second input ports and having at least one output port for outputting received light;
  
  means for optically detecting the received light and for producing an information signal indicative thereof;
  
  first and second optical fibers, each having a predetermined length and a midpoint, and each having a first end optically connected, respectively, to said first and second output ports of said means for splitting the source light and each having a second end optically connected respectively to said first and second input ports of said means for recombining light, said first and second optical fibers attached longitudinally in a predetermined plane, the orientation of said first and second optical fibers between said first ends and the midpoint being opposite the orientation of said first and second optical fibers between said second ends and the midpoint; and
  
  means for supporting said first and second optical fibers near said first ends and also near said second ends, and at the midpoint which is substantially equidistant from either end of said first and second optical fibers, said means for supporting forming at least first and second compartments about said first and second optical fibers and including a divider at the midpoint of said first and second optical fibers, said divider having an aperture through which said first and second optical fibers pass, said means for supporting having a first opening in said plane of said first and second optical fibers over said portion of said fibers between said first ends and the midpoint and having a second opening in said plane opposed to said first opening over said portion of said first and second optical fibers between said second ends and the midpoint;
  
  said first and second openings in said supporting means permitting the external acoustic field to move said first and second optical fibers such that either said first optical fiber is stretched and said second optical fiber is compressed or vice versa, thereby changing the optical path lengths of both of said first and second optical fibers.
- View Dependent Claims (6, 7, 8)
- - 6. The sensor described in claim 5, wherein said means for supporting comprises an even numbered plurality of said compartments separated by a plurality of said dividers with said first and second optical fibers extending through each of said compartments, said first and second optical fibers crossing over to an opposite orientation at each of said dividers between said compartments, said openings in said means for supporting associated with said compartments being in an alternating opposed orientation in said means for supporting.
  - 7. The sensor described in claim 5, wherein said sensor further comprises means for providing a bendable beam, said first and second optical fibers being attached to opposite sides of said means for providing a bendable beam between first and second ends thereof, said means for providing a bendable beam having said first end attached to an end of one of said compartments opposite said divider, having said second end attached to an end of said other compartment opposite said divider, and having its midpoint attached to said divider, said means for providing a bendable beam being responsive to the external acoustic field.
  - 8. The device described in claim 7 wherein said first and second optical fibers are attached to opposed sides of said means for providing a bendable beam.

9. A fiber optic interferometric acoustic sensor for measuring an external acoustic field comprising:
- means for producing source light in a predetermined frequency range;
  
  an optical coupler having an input for receiving the source light, having first and second ports for outputting split source light and for receiving reflected light and having an output for outputting a received light recombined by the coupler from the received reflected light;
  
  means for optically detecting the received light and for producing an information signal indicative thereof;
  
  first and second optical fibers, each having a predetermined length and a midpoint, each having a first end optically connected, respectively, to said first and second ports of said optical coupler, and each having a second end including a means for reflecting light attached thereto, said first and second optical fibers attached longitudinally in a predetermined plane, the orientation of said first and second optical fibers between said first ends and the midpoint being opposite the orientation of said first and second optical fibers between said second ends and the midpoint; and
  
  means for supporting said first and second optical fibers near said first ends and also near said second ends, and at the midpoint which is substantially equidistant from either end of said first and second optical fibers, said means for supporting forming first and second compartments about said first and second optical fibers and including a divider at the midpoint of said first and second optical fibers, said divider having an aperture through which said first and second optical fibers pass, said means for supporting having a first opening in said plane of said first and second optical fibers over said portion of said fibers between said first ends and the midpoint and having a second opening in said plane opposed to said first opening over said portion of said first and second optical fibers between said second ends and the midpoint;
  
  said first and second openings in said supporting means permitting the external acoustic field to move said first and second optical fibers such that either said first optical fiber is stretched and said second optical fiber is compressed or vice versa, thereby changing the optical path lengths of both of said first and second optical fibers.
- View Dependent Claims (10, 11, 12)
- - 10. The sensor described in claim 9, wherein said means for supporting comprises an even numbered plurality of said compartments separated by a plurality of said dividers with said first and second optical fibers extending through each of said compartments, said first and second optical fibers crossing over to an opposite orientation at each of said dividers between said compartments, said openings in said means for supporting associated with said compartments being in an alternating opposed orientation in said means for supporting.
  - 11. The sensor described in claim 9, wherein said sensor further comprises means for providing a bendable beam, said first and second optical fibers being attached to opposite sides of said means for providing a bendable beam between first and second ends thereof, said means for providing a bendable beam having said first end attached to an end of one of said compartments opposite said divider, having said second end attached to an end of said other compartment opposite said divider, and having its midpoint attached to said divider, said means for providing a bendable beam being responsive to the external acoustic field.
  - 12. The device described in claim 11, wherein said first and second optical fibers are attached to opposed sides of said means for providing a bendable bea

13. A fiber optic interferometric acoustic sensor for measuring an external acoustic field, comprising:
- a shell structure having at least two compartments, each of said at least two compartments being substantially acoustically isolated and having an associated opening in said shell structure, the associated openings of adjacent ones of said at least two compartments being oriented in opposite directions with respect to each other;
  
  a bendable beam housed within said shell structure, said bendable beam having sides and extending through all of said at least two compartments;
  
  a first optical fiber coupled to said bendable beam along said at least two compartments, said first optical fiber being coupled to opposite sides of said bendable beam in adjacent ones of said at least two compartments; and
  
  a second optical fiber coupled to said bendable beam along said at least two compartments, said second optical fiber being coupled to said bendable beam on the side of said bendable beam opposite said first optical fiber in each of said at least two compartments, the external acoustic field impinging upon said first and second optical fibers and said bendable beam to stretch one of said first and second optical fibers and to compress the other of said first and second optical fibers so as to alter the optical path length of both of said first and second optical fibers.
- View Dependent Claims (14, 15, 16)
- - 14. The fiber optic interferometric acoustic sensor as set forth in claim 13, wherein said shell structure further includes a divider positioned between adjacent ones of said at least two compartments, said divider having an aperture through which said bendable beam and said first and second optical fibers extend.
  - 15. The fiber optic interferometric acoustic sensor as set forth in claim 14, further comprising means for sealing the apertures in said divider to acoustically isolate said at least two compartments, said means for sealing surrounding said bendable beam and said first and second optical fibers.
  - 16. The fiber optic interferometric acoustic sensor as set forth in claim 13, further comprising:
    - means for providing split source light to said first and second optical fibers; and
      
      means for optically detecting light carried by said first and second optical fibers.

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Current Assignee
GOI Acquisitions LLC
Original Assignee
Gould, Inc. (Transdigm Group Incorporated)
Inventors
Krueger, Helmut H. A.
Primary Examiner(s)
Buczinski, Stephen C.
Assistant Examiner(s)
Koltak, Melissa L.

Application Number

US06/861,947
Time in Patent Office

764 Days
Field of Search

367/149, 367/140, 73/800, 73/657, 350/96.1, 356/345
US Class Current

367/149
CPC Class Codes

G01H 9/004 using fibre optic sensors l...

H04R 23/008 using optical signals for d...

Fiber optic interferometric hydrophone

First Claim

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Abstract

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16 Claims

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Fiber optic interferometric hydrophone

First Claim

4 Assignments

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0 Petitions

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Accused Products

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Abstract

44 Citations

16 Claims

Specification

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Solutions

Use Cases

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