Gain balanced nonlinear optical interferometer

We claim: 1. An optical device, comprising: a first nonlinear lightguide having a first length and being situated to receive seed probe light and pump light from respective light sources and being configured to form first mixed light comprising first probe, first pump, and first conjugate light components, the seed probe light undergoing a probe gain in the first nonlinear lightguide; a modulator situated to receive the first mixed light from the first nonlinear lightguide and output second mixed light comprising second probe, second pump, and second conjugate light components, wherein a given component among the second probe, second pump, and second conjugate light components incorporates a non-zero phase shift, representative of a sensed quantity, relative to a corresponding component among the first probe, first pump and first conjugate light components; and a second nonlinear lightguide having a second length, situated to receive the second mixed light from the modulator and apply phase-sensitive amplification on the second probe and second conjugate light components; wherein the second length is larger than the first length such that averaged phase-sensitive amplification applied by the second nonlinear lightguide matches the probe gain in the first nonlinear lightguide. 2. The optical device of claim 1 , further comprising: a photodetector coupled to an output of the second nonlinear lightguide and configured to measure at least one of the second probe light component or the second conjugate light component to determine the phase shift. 3. The optical device of claim 2 , further comprising: a controlled phase shifter coupled to the photodetector and situated in a path of one of the components of the first mixed light between the first and second nonlinear lightguides. 4. An optical sensing system comprising: the optical device of claim 3 ; a first laser as the light source from which the seed probe light is received; and a second laser as the light source from which the pump light is received. 5. An airborne monitoring system comprising: the optical sensing system of claim 4 situated on an aircraft, wherein the sensed quantity is a parameter of the aircraft to be monitored; and a fiber sensor coupled to the modulator, wherein the fiber sensor has intrinsic sensitivity to the parameter and provides the phase shift in the given component, wherein the phase shift varies responsive to variations in the parameter. 6. A down-hole environmental monitoring system comprising: the optical sensing system of claim 4 situated proximate to a petrochemical access shaft, wherein the sensed quantity is an environmental parameter to be monitored within the petrochemical access shaft; and a fiber sensor coupled to the modulator, wherein the fiber sensor has intrinsic sensitivity to the environmental parameter and provides the phase shift in the given component, wherein the phase shift varies responsive to variations in the environmental parameter. 7. An optical sensor comprising: the optical device of claim 2 ; and a circuit coupled to an output of the photodetector and configured to transform the determined phase shift into a representation of the sensed quantity. 8. The optical sensor of claim 7 , wherein the sensed quantity is a pressure wave and the optical sensor is a hydrophone. 9. The optical sensor of claim 7 , wherein the sensed quantity is an angular velocity and the optical sensor is a gyroscope. 10. The optical device of claim 1 , wherein: the sensed quantity is one or more of: temperature, strain, pressure, or angular velocity; and the phase shift is incorporated into the given component by an intrinsic fiber sensor that is sensitive to the sensed quantity. 11. The optical device of claim 1 , wherein at least one of the first or second nonlinear lightguides is an optical fiber. 12. The optical device of claim 1 , wherein at least one of the first or second nonlinear lightguides is a waveguide in a planar lightwave circuit. 13. The optical device of claim 1 , wherein the first and second nonlinear lightguides have matching cross-sectional structure and matching composition. 14. The optical device of claim 1 , wherein the probe gain is obtained by pump-degenerate four-wave mixing. 15. The optical device of claim 1 , wherein the modulator comprises: a splitter configured to separate the corresponding component from other components of the first mixed light; and a recombiner configured to merge the given component, with the phase shift incorporated, with other components of the second mixed light. 16. The optical device of claim 15 , wherein the splitter and the recombiner are implemented as an optical add-drop multiplexer (OADM). 17. The optical device of claim 15 , further comprising: a fiber sensor situated to transport the corresponding component from the splitter, develop the phase shift, and transport the given component, with the phase shift incorporated, to the recombiner. 18. The optical device of claim 15 , wherein the modulator further comprises: a first port for coupling the corresponding component from the splitter to an external fiber sensor; and a second port for coupling the given component, with the phase shift incorporated, from the external fiber sensor to the recombiner. 19. The optical device of claim 1 , wherein: the seed probe light is multiplexed between a plurality of wavelengths; the corresponding component of the first mixed light is correspondingly multiplexed between respective sensors for the plurality of wavelengths; and the sensed quantity is correspondingly multiplexed between a respective plurality of quantities detected by the respective sensors. 20. The optical device of claim 1 , wherein the given component is the second probe light component, the corresponding component is the first probe light component; and wherein the second pump and second conjugate light components have phase relationships with the first pump and first conjugate light components, respectively, that are independent of the phase shift representative of the sensed quantity. 21. The optical device of claim 1 , wherein the given component is the second conjugate light component, the corresponding component is the first conjugate light component; and wherein the second pump and second probe light components have phase relationships with the first pump and first probe light components, respectively, that are independent of the phase shift representative of the sensed quantity. 22. The optical device of claim 1 , wherein the given component is the second pump light component, the corresponding component is the first pump light component; and wherein the second probe and second conjugate light components have phase relationships with the first probe and first conjugate light components, respectively, that are independent of the phase shift representative of the sensed quantity. 23. The optical device of claim 1 , wherein a further component of the second mixed light, excluding the given component, and a further component of the first mixed light, excluding the corresponding component, have a phase relationship that is dependent on the phase shift representative of the sensed quantity. 24. The optical device of claim 1 , wherein the sensed quantity is an environmental parameter. 25. The optical device of claim 1 , wherein the light sources are lasers.