USRE35023EExpiredUtility

Fiber optic gyro with a source at a first wavelength and a fiber optic loop designed for single mode operation at a wavelength longer than the first wavelength

31
Assignee: HONEYWELL INCPriority: Dec 21, 1990Filed: Mar 25, 1994Granted: Aug 22, 1995
Est. expiryDec 21, 2010(expired)· nominal 20-yr term from priority
Inventors:Carl M. Ferrar
G01C 19/721
31
PatentIndex Score
2
Cited by
10
References
10
Claims

Abstract

A low cost fiber optic gyro includes a Sagnac interferometer configured in a minimum reciprocal configuration and modified to use a 0.8 micron wavelength laser diode as the interferometer light source and 1.3 micron, single-mode fiber for the sensing coil.

Claims

exact text as granted — not AI-modified
.[.We claim:.].  .Iadd.What is claimed is: .Iaddend. 
     
       1. An interferometric rotation sensor, comprising: optical signal source means, for providing a source optical signal .Iadd.having a primary source optical signal wavelength.Iaddend.;   optical fiber sensing loop means, for providing, in .[.the.]. presence of .[.loop.]. rotation .Iadd.thereof.Iaddend., a Sagnac phase difference between two sensing loop optical signals propagating in counter circulating paths therethrough;   .[.integrated optic circuit (IOC) means, having a substrate with a waveguide array formed thereon, said waveguide array including.]. a bi-directional common path section responsive to said source optical signal, said .Iadd.bi-directional .Iaddend.common path .Iadd.section .Iaddend.having a single polarization mode filter and a single spatial mode filter formed therein to pass .[.select.]. .Iadd.selected .Iaddend.mode optical signals having a .[.desired.]. .Iadd.selected .Iaddend.spatial mode and a .[.desired.]. .Iadd.selected .Iaddend.polarization mode, .[.said waveguide means further including.]. .Iadd.a .Iaddend.beam splitter/combiner means for splitting said .[.select.]. .Iadd.selected .Iaddend.mode optical signal received from said .Iadd.bi-directional .Iaddend.common path .Iadd.section .Iaddend.into said two sensing loop optical signals for counter propagation through said sensing loop means, and for combining sensing loop optical signals received from said .Iadd.optical fiber sensing .Iaddend.loop .Iadd.means .Iaddend.into a common interference signal for return through said .Iadd.bi-directional .Iaddend.common path .Iadd.section.Iaddend., said interference signal amplitude being dependent on the magnitude of said Sagnac phase difference;   detector means, for sensing the amplitude of said interference signal; and   means for coupling said source optical signal to said .[.IOC means.]. .Iadd.bi-directional common path section .Iaddend.and for coupling said interference signal from said .[.IOC means.]. .Iadd.bi-directional common path section .Iaddend.to said detector means;   as characterized by:   .[.said optical signal source means comprising a laser diode having a source optical signal wavelength;.].   said .[.sensing loop.]. .Iadd.optical .Iaddend.fiber .Iadd.sensing loop means .Iaddend.comprising an optical fiber which is designed for single mode operation at a wavelength which is longer than said .Iadd.primary optical signal .Iaddend.source wavelength, and wherein said .[.sensing loop.]. .Iadd.optical .Iaddend.fiber .Iadd.sensing loop means .Iaddend.embodies a signal mode conversion characteristic therein, to prevent .[.sensing loop.]. cross coupling of all optical power from .[.the select.]. .Iadd.said selected .Iaddend.spatial mode to .[.undesired.]. .Iadd.other .Iaddend.spatial modes .Iadd.in said optical fiber sensing loop means. .Iaddend.   
     
     
       2. The rotation sensor of claim 1, wherein said .Iadd.optical fiber .Iaddend.sensing loop .Iadd.means .Iaddend.comprises .[.a.]. .Iadd.an optical .Iaddend.fiber coil configuration having a fiber winding geometry which causes said .Iadd.optical fiber .Iaddend.sensing loop .Iadd.means .Iaddend.to display inherent mode conversion characteristics. 
     
     
       3. The rotation sensor of claim 1, wherein said .Iadd.optical fiber sensing loop .[.coil configuration.]. .Iadd.means .Iaddend.comprises .Iadd.an optical fiber coil configuration having .Iaddend.a discrete mode conversion element positioned at one end .[.of said sensing loop coil.]. .Iadd.thereof.Iaddend.. 
     
     
       4. The rotation sensor of claim 3, wherein said discrete mode conversion element comprises a serpentine segment of fiber bends positioned at one end of the sensing loop coil. 
     
     
       5. The rotation sensor of claim 1, wherein said .Iadd.primary .Iaddend.source .Iadd.optical signal .Iaddend.wavelength is on the order of 0.8 microns and the .Iadd.optical fiber .Iaddend.sensing loop .Iadd.means .Iaddend.optical fiber is designed to operate as a wavelength on the order of 1.3 microns. 
     
     
       6. The rotation sensor of claim 1, further comprising depolarization means, at least one, located between the sensing loop coil and said .[.IOC combiner/splitter.]. .Iadd.beam splitter/combiner means.Iaddend., to prevent sensing loop cross coupling of all optical power from .[.the desired.]. .Iadd.said selected .Iaddend.polarization mode to .[.an undesired.]. .Iadd.another polarization .Iaddend.mode. 
     
     
       7. The rotation sensor of claim 6, wherein said depolarization means comprises a length of single mode fiber having high birefringence. 
     
     
       8. The rotation sensor of claim 1, further comprising: serrodyne modulation means, for applying a linear ramped phase modulation of said sensing loop optical signals, to provide a phase bias in opposition to the Sagnac phase difference; and   control circuitry, for continuously changing the value of the serrodyne modulation frequency in dependence on said interference signal amplitude so as to cause the phase bias to continuously null the Sagnac phase difference magnitude, whereby the nulling value of the serrodyne modulation frequency is proportional to said sensing loop rotation rate.   
     
     
       9. The rotation sensor of claim .[.6.]. .Iadd.11.Iaddend., further comprising discrete polarizer means, positioned between said means for coupling and said IOC .Iadd.bi-directional .Iaddend.common path .Iadd.section .Iaddend.waveguide segment, to increase the extinction ratio of said IOC single polarization .Iadd.mode .Iaddend.filter. 
     
     
       10. The rotation sensor of claim 5, wherein said .Iadd.primary .Iaddend.source .Iadd.optical signal .Iaddend.wavelength may range from 750 to 900 nanometers and the design wavelength of the sensing loop fiber may range from 1200 to 1600 nanometers. .Iadd.11. The rotation sensor of claim 1 further comprising said bi-directional common path section and said beam splitter/combiner means provided in a waveguide array formed on a substrate of an integrated optics chip (IOC) means. .Iaddend. .Iadd.12. The rotation sensor of claim 1 wherein said optical signal source means comprises a laser diode. .Iaddend.

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