Fiber-optic sensor and method

The invention claimed is: 1. A fiber optic sensor comprising: a light source, a polarizing element, a detector, a polarization maintaining (PM) fiber, and a sensing element, wherein the fiber optic sensor further comprises a cross-coupling element in an optical path between the polarizing element and the sensing element, with the cross-coupling element generating a defined cross-coupling between the two orthogonal polarizations of the fundamental mode in the PM fiber, and wherein the cross-coupling element and the sensing element are separated along the optical path, and further wherein the cross-coupling element is designed such that shifts in a sensor signal introduced by the wavelength dependence of the cross-coupling element balance signal shifts introduced by the wavelength dependence of further sensor elements; wherein the shifts introduced by the wavelength dependence of further sensor elements include shifts introduced by wavelength dependence of any or all of: the Verdet constant, of retarders or Faraday rotators in the optical path, or of the sensing element. 2. The fiber optic sensor of claim 1 , wherein the cross-coupling element and the sensing element are separated by at least one element selected from the group consisting of: at least a section of PM fiber, a retarder, a Faraday rotator, and combinations thereof. 3. The fiber optic sensor of claim 1 , wherein the cross-coupling element is a separate element present in addition to the PM fiber. 4. The fiber optic sensor of claim 1 , wherein the sensing element is sensitive to an external field selected from an electrical field, a magnetic field or a strain field. 5. The fiber optic sensor of claim 1 , wherein the cross-coupling element is designed such that shifts in the sensor signal introduced by the wavelength dependence of the cross-coupling balance signal shifts introduced by the wavelength dependence of the Faraday effect or the electro-optic effect. 6. The fiber optic sensor of claim 1 , wherein the cross-coupling element comprises an optical retarder or a Faraday rotator; or wherein the cross-coupling element comprises a retarder detuned from exact half-wave retardance or exact multiple-order half-wave retardance by a non-zero amount or phase β(λ o ); or wherein the cross-coupling element is a fiber retarder comprising a birefringent fiber, an elliptical core fiber or a microstructured birefringent fiber. 7. The fiber optic sensor of claim 1 , wherein one of: a) the principal optical axes of the PM fiber and the principal optical axes of the cross-coupling element are rotated against each other by an orientation angle ζ in the range of ±(45°±22.5°); and b) wherein the cross-coupling element is a halfwave retarder with principal axes forming an orientation angle ζ in the range of ±15° or in a range of 90° ±15° with respect to the principal axes of the PM fiber, and with a half wave retardance δ(T 0 ,λ 0 ) equal to an integer multiple of 180° within ±20° to achieve a sensor signal insensitive to temperature up to second order within a given temperature range. 8. The fiber optic sensor of claim 1 , comprising a retarder adjusted to compensate for shifts in the sensor signal caused by temperature changes of the cross-coupling element or of other optical elements in the sensor. 9. The fiber optic sensor of claim 1 , comprising a retarder adjusted to compensate for linearly temperature-dependent shifts in the sensor signal caused by temperature changes of any of the elements selected from the group consisting of: the cross-coupling element, the sensing element, and further optical elements in the fiber optic sensor. 10. The fiber optic sensor of claim 1 , wherein a quadratically temperature-dependent contribution from the cross-coupling element to the sensor signal counteracts a quadratically temperature-dependent contribution from other elements, to the sensor signal. 11. The fiber optic sensor of claim 1 , wherein one of: a) the cross-coupling element is temperature stabilized; and b) the cross-coupling element is located within a common housing with an opto-electronic module comprising at least an active or passive for modulating or biasing the differential phase of light waves. 12. The fiber optic sensor of claim 1 , wherein one of: a) the sensing element comprises one of a sensing fiber to be looped around a conductor and to be in operation exposed to a magnetic field of a current I in the conductor, and b) an electro-optical crystal or an electro-optic fiber or a fiber connected to piezo-electric material. 13. The fiber optic sensor of claim 1 , wherein one: of a) the sensing element is terminated with a reflective element, and b) the light source is not in thermal contact with active heating or cooling elements. 14. The fiber optic sensor of claim 1 , wherein the optical path with the cross-coupling element comprises one of: a) an optical phase modulator between the polarizing element and the sensing element, and b) an optical beam splitter between the polarizing element and the sensing element. 15. A method of measuring a current, a magnetic field, a voltage, an electric field, or a strain field, the method comprising: providing a fiber optic sensor including a light source, a polarizing element, a light detector, a polarization maintaining (PM) fiber, and a sensing element, wherein the fiber optic sensor further comprises a cross-coupling element in an optical path between the polarizing element and the sensing element, generating polarized light using the light source with the polarizing element, passing the light through the polarization maintaining (PM) fiber into the sensing element and from the sensing element back to the light detector to determine a signal indicative of a phase shift in the light, and characterized by using the cross-coupling element located in the optical path between the polarizing element and the sensing element to balance signal shifts introduced by the wavelength dependence due to other sensor elements by shifts in a sensor signal introduced by the wavelength dependence of the cross-coupling element, wherein the shifts introduced by the wavelength dependence of further sensor elements include shifts introduced by wavelength dependence of any or all of: the Verdet constant, of retarders or Faraday rotators in the optical path, or of the sensing element. 16. The method of claim 15 , further comprising tuning the cross-coupling between polarization states of the fundamental mode of the PM fiber by introducing in the cross-coupling element a phase shift of m·180°+β(λ 0 ) between the polarization states, wherein m is an integer including zero and β(λ 0 ) is not zero and is selected such that said cross-coupling balances a wavelength-dependent shift in a measured signal due to other sensor elements. 17. The method of claim 15 , further comprising reducing the temperature dependence of the cross-coupling element by providing a thermally stable environment or by using an athermal cross-coupling element; or wherein the cross-coupling element is a half wave retarder with principal optical axes forming an orientation angle ζ in the range of ±15° or in a range of 90°±15° with respect to the principal optical axes of the PM fiber, and with a half wave retardance δ(T 0, λ 0 ) equal to an integer multiple of 180° within ±20° to achieve a sensor signal insensitive to temperature up to second order within a given temperature range. 18. The method of claim 15 , further comprising using a retarder adjusted to compensate for shifts in the sensor signal induced by temperatu