Fiber-optic current sensor with tolerance to connector misalignment

The invention claimed is: 1. A fiber-optic current sensor comprising a light source generating light with a coherence length Lc, a first beam splitter splitting the light from said light source into a first and a second branch, a second beam splitter combining the light from said first and second branches, a polarization-maintaining connecting fiber adapted to carry light in first and second, mutually orthogonal polarization modes and receiving light from said second beam splitter for a first passage through said connecting fiber, a sensor head, wherein said sensor head is adapted and structured to receive light waves from said first and said second polarization mode of said connecting fiber, to generate a current-dependent phase shift between said light waves, and to reflect said light waves back into said connecting fiber with switched polarizations for a second passage through said connecting fiber, a detector located to detect a light intensity resulting from the interference of said waves after their second passage through said connecting fiber, a first releasable connector in said first branch, and a second releasable connector in said second branch, wherein said first branch is adapted to carry light in a first and a second polarization mode between said first connector and a select one of said first or said second beam splitters, and wherein said second branch is adapted to carry light in a first and a second polarization mode between said second connector and said select beam splitter, wherein without angular misalignment of said connectors, light traveling towards the sensor head is in the first polarization modes of the first and second branches. 2. The sensor of claim 1 , wherein abs( L 11+ L 21− L 12− L 22)> Lc with L11 being an optical path length of the first polarization mode in the first branch between the first connector and the select beam splitter, L12 being an optical path length of the second polarization mode in the first branch between the first connector and the select beam splitter, L21 being an optical path length of the first polarization mode in the second branch between the second connector and the select beam splitter, and L22 being an optical path length of the second polarization mode in the second branch between the second connector and the select beam splitter. 3. The sensor of claim 2 , wherein said first branch comprises a first and a second birefringent fiber section connected under a mutual angle of 90° between their fast and slow principal axes. 4. The sensor of claim 3 , wherein said first and said second birefringent fiber sections meet at a location between said first connector and said select beam splitter. 5. The sensor of claim 3 , wherein said first and said second birefringent fiber sections meet at a location between said first connector and the beam splitter that is not the select beam splitter. 6. The sensor of claim 3 , wherein said first and said second birefringent fiber sections meet at said first connector. 7. The sensor of claim 3 , wherein the first releasable connector in the first branch and the second releasable connector in the second branch are arranged in positions such, that a first group of components comprising the sensor head and the second beam splitter is detachable from a second group of components comprising the light source, the detector and the first beam splitter by disconnecting the first releasable connector and the second releasable connector. 8. The sensor of claim 3 , comprising at least one phase modulator adapted to modulate a phase of the light in the first and/or in the second branch. 9. The sensor of claim 1 , comprising at least one phase modulator adapted to modulate a phase of the light in the first and/or in the second branch. 10. The sensor of claim 9 , wherein said phase modulator is arranged between said connectors and said first beam splitter. 11. The sensor of claim 10 , further comprising a modulator module integrating said first beam splitter, said modulator and at least one polarizer for polarizing the waves propagating from said modulator module towards said second beam splitter. 12. The sensor of claim 9 , further comprising a modulator module integrating said first beam splitter, said modulator and at least one polarizer for polarizing the waves propagating from said modulator module towards said second beam splitter. 13. The sensor of claim 1 , further comprising a cable assembly arranged between said connectors and said sensor head, wherein said cable assembly comprises said connecting fiber and said second beam splitter and ends in a first and a second connector member of said first and said second connector, respectively. 14. The sensor of claim 1 , further comprising a polarizer in said first and/or in said second branch between said connectors and said second beam splitter. 15. The sensor of claim 1 , further comprising a polarizer in said first and/or in said second branch between said connectors and said first beam splitter. 16. The sensor of claim 1 , further comprising a polarizer between said detector and said light source on the one side and said first beam splitter on the other side. 17. The sensor of claim 1 , wherein the first releasable connector in the first branch and the second releasable connector in the second branch are arranged in positions such, that the sensor head is detachable from the light source and/or from the detector by disconnecting the first releasable connector and the second releasable connector. 18. The sensor of claim 1 , wherein the first releasable connector in the first branch and the second releasable connector in the second branch are arranged in positions such, that a first group of components comprising the sensor head and the second beam splitter is detachable from a second group of components comprising the light source, the detector and the first beam splitter by disconnecting the first releasable connector and the second releasable connector. 19. The sensor of claim 1 , comprising at least one phase modulator adapted to introduce a differential phase modulation between the interfering light waves. 20. The sensor of claim 19 , further comprising a modulator module integrating said first beam splitter, said modulator and at least one polarizer for polarizing the waves propagating from said modulator module towards said second beam splitter. 21. A fiber-optic current sensor comprising a light source generating light with a coherence length Lc, a first beam splitter splitting the light from said light source into a first and a second branch, a second beam splitter combining the light from said first and second branches, a polarization-maintaining connecting fiber adapted to carry light in first and second, mutually orthogonal polarization modes and receiving light from said second beam splitter for a first passage through said connecting fiber, a sensor head, wherein said sensor head is adapted and structured to receive light waves from said first and said second polarization mode of said connecting fiber, to generate a current-dependent phase shift between said light waves, and to reflect said light waves back into said connecting fiber with switched polarizations for a second passage through said connecting fiber, a detector located to detect a light intensity resulting from the interference of said waves after their second passage through said connecting fiber, a first releasable connector in said first branch, a second re