Electro-optic sensor system

We claim: 1. An electro-optical sensor comprising: an optical input configured to receive an optical carrier via an upstream fiber; an optical modulator configured to modulate an electrical signal onto the optical carrier to create an optical signal; an optical output configured to transmit the optical signal via a downstream fiber; a variation output configured to transmit variation data indicating variation in the received optical carrier to support compensation for corresponding variation in the optical signal; and an optical splitter integrated with the optical modulator or positioned between the optical input and the optical modulator, the optical splitter configured to forward the un-modulated portion of the received optical carrier to the variation output as variation data. 2. The electro-optical sensor of claim 1 , further comprising an optical to electrical (O/E) converter positioned between the optical splitter and the variation output, the O/E converter configured to convert the un-modulated portion of the received optical carrier into electrical variation data. 3. The electro-optical sensor of claim 1 , wherein the optical modulator is polarization sensitive, and wherein the optical splitter is configured to forward portions of the optical carrier with polarization incompatible to the optical modulator as the un-modulated portion of the received optical carrier. 4. An electro-optical sensor comprising: an optical input configured to receive an optical carrier via an upstream fiber; an optical modulator configured to modulate an electrical signal onto the optical carrier to create an optical signal; an optical output configured to transmit the optical signal via a downstream fiber; and a variation output configured to transmit variation data indicating variation in the received optical carrier to support compensation for corresponding variation in the optical signal, wherein the optical modulator is a directional coupler with a first output coupled to the optical output and a second output coupled to the variation output, and wherein the optical output and the variation output each contain a portion of the optical signal and a portion of the variation data. 5. An electro-optical sensor comprising: an optical input configured to receive an optical carrier via an upstream fiber; an optical modulator configured to modulate an electrical signal onto the optical carrier to create an optical signal; an optical output configured to transmit the optical signal via a downstream fiber; and a variation output configured to transmit variation data indicating variation in the received optical carrier to support compensation for corresponding variation in the optical signal, wherein the optical output and the variation output are a common output coupled to the downstream fiber, and wherein the electro-optical sensor further comprises a radio frequency (RF) generator for generating an RF signal for modulation onto the optical carrier along with the electrical signal, the RF signal operating at a different frequency than the electrical signal and acting as variation data upon passing across the downstream fiber. 6. An electro-optical sensor comprising: an optical input configured to receive an optical carrier via an upstream fiber; an optical modulator configured to modulate an electrical signal onto the optical carrier to create an optical signal; an optical output configured to transmit the optical signal via a downstream fiber; a compensation component configured to compensate for variation in the received optical carrier to mitigate corresponding variation in the optical signal; and an optical splitter integrated with the optical modulator or positioned between the optical input and the optical modulator, the optical splitter configured to forward an un-modulated portion of the received optical carrier to the compensation component as variation data. 7. The electro-optical sensor of claim 6 , wherein the compensation component includes a bias control unit configured to bias the optical modulator to compensate for variation in the received optical carrier. 8. The electro-optical sensor of claim 6 , wherein the compensation component includes a control modulator positioned between the optical input and the optical modulator, the control modulator configured to compensate for variation in the received optical carrier by maintaining a consistent optical carrier intensity incident to the optical modulator. 9. The electro-optical sensor of claim 6 , further comprising an optical to electrical (O/E) converter positioned between the optical splitter and the compensation component, the O/E converter configured to convert the un-modulated portion of the received optical carrier into electrical variation data for use by the compensation component. 10. The electro-optical sensor of claim 9 , wherein the optical modulator is polarization sensitive, and wherein the optical splitter is configured to forward portions of the optical carrier with polarization incompatible to the optical modulator as the un-modulated portion of the received optical carrier. 11. The electro-optical sensor of claim 10 , wherein the optical splitter is a polarizing beam splitter with a primary axis aligned with the optical modulator and a secondary axis aligned with the O/E converter.