Fiber optic sensor lead fiber noise cancellation
First Claim
1. An electro-optical system for the detection of a physical property manifest as a pressure effect by means of the interaction of the pressure effect on an optical waveguide, said system comprising:
- an optical sensor responsive to pressure effects to vary the optical transmission therethrough;
first and second optical waveguides having said optical sensor in light communicating relationship therebetween to define a first optical path from an end of said first waveguide through said sensor and then through said second waveguide to an end thereof;
a first partially reflecting means located in said first optical path between said first waveguide and said sensor to define a second optical path from the end of said first waveguide through said first waveguide and then by reflection from said first partially reflecting element back through said first waveguide to the end thereof;
said first and second waveguides adapted to experience the same environmental effects;
means for applying light of a first frequency to the end of said first waveguide to produce light along said first and second optical paths respectively appearing at said ends of said second and first waveguides;
said means for applying light also producing;
means for producing a first interference pattern resulting from light on said first path appearing at said end of said second waveguide combined with the light of said second frequency and for producing a second inteference pattern resulting from light on said second path appearing at said end of said first waveguide combined with the light of said second frequency;
first and second photodetector means for sensing the light in said first and second interference patterns respectively to produce first and second output signals; and
means responsive to said first and second output signals for providing an output indication of the pressure effects on said optical senses.
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Accused Products
Abstract
An optoacoustic hydrophone for detection of acoustic waves in a fluid such as sea water. The hydrophone includes an optical waveguide comprising a fiber optic input lead, a fiber optic sensor, and a fiber optic exit lead, an optical subassembly and a signal processor. A coherent light beam generated by the optical subassembly is transmitted through the input lead and the sensor which is disposed in the fluid. Acoustic waves in the fluid modulate the index of refraction of the fiber optic sensor thereby modulating the transmitted light beam. The modulated light beam is directed through the fiber optic exit lead to a focus on one of two photodetectors. The other photodetector is oriented for receipt of light reflected from a partially reflective mirror disposed between the input fiber optic lead and the fiber optic sensor. The two light beams impinging on respective photodetector are combined with unmodulated light beams of slightly different frequencies to produce an interference pattern at each photodetector. Each photodetectors produces an electrical signal representative of the interference pattern and the respective electrical signals are applied to a phase meter. The phase meter produces an output signal representative of the acoustic wave alone which corresponds to the difference between the two electrical signals provided by respective photodetectors. The disclosed optoacoustic hydrophone effectively cancels common mode lead noise resulting from towage of the optical waveguide through the fluid. Pressure effects in optical fibers created by other physical mechanisms are also sensed by the present apparatus.
67 Citations
5 Claims
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1. An electro-optical system for the detection of a physical property manifest as a pressure effect by means of the interaction of the pressure effect on an optical waveguide, said system comprising:
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an optical sensor responsive to pressure effects to vary the optical transmission therethrough; first and second optical waveguides having said optical sensor in light communicating relationship therebetween to define a first optical path from an end of said first waveguide through said sensor and then through said second waveguide to an end thereof; a first partially reflecting means located in said first optical path between said first waveguide and said sensor to define a second optical path from the end of said first waveguide through said first waveguide and then by reflection from said first partially reflecting element back through said first waveguide to the end thereof; said first and second waveguides adapted to experience the same environmental effects; means for applying light of a first frequency to the end of said first waveguide to produce light along said first and second optical paths respectively appearing at said ends of said second and first waveguides; said means for applying light also producing; means for producing a first interference pattern resulting from light on said first path appearing at said end of said second waveguide combined with the light of said second frequency and for producing a second inteference pattern resulting from light on said second path appearing at said end of said first waveguide combined with the light of said second frequency; first and second photodetector means for sensing the light in said first and second interference patterns respectively to produce first and second output signals; and means responsive to said first and second output signals for providing an output indication of the pressure effects on said optical senses. - View Dependent Claims (2, 3, 4, 5)
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Specification