Enhancement of dynamic range of electrode measurements

What is claimed is: 1. A method comprising: controlling current in a set of three current electrodes to inject current into a formation around a pipe in a wellbore, the three current electrodes disposed on the pipe in the wellbore such that two current electrodes of the three current electrodes inject current and the third current electrode is operatively arranged as a current return, the three current electrodes associated with a set of two monitor electrodes, the two monitor electrodes being two current electrodes of the set of three current electrodes or two electrodes different from the set of three current electrodes, interrogating an optical fiber, the optical fiber extending along the longitudinal axis of the pipe with a portion of the optical fiber associated with the set of three current electrodes in a sensing operation using the set of three current electrodes; determining progression of waterflood with respect to the wellbore from controlling the current and interrogating the optical fiber over time; and operating a processor to determine waterflood distance and resistivity that minimizes misfit between bucked measurements and synthetic data, the synthetic data generated using a model that includes simulation of operation of the set of three current electrodes in the formation, the bucked measurements generated using the controlling of the current of the set of three current electrodes and interrogating the optical fiber over time. 2. The method of claim 1 , wherein controlling current in the set of three current electrodes includes: using three separate power lines coupled to the set of three current electrodes from a surface, each power line coupled to a respective one of the three current electrodes; using a single power line and a return coupled to downhole electronics from the surface, the downhole electronics operable to control currents to and from the formation from the three current electrodes; or exciting the three current electrodes in the set of three current electrodes simultaneously with multiple frequencies. 3. The method of claim 1 , wherein interrogating the optical fiber includes: interrogating the portion of the optical fiber with the portion of the optical fiber coated with an electrostrictive material over a length of the optical fiber between the injection and return current electrodes of the set of three current electrodes. 4. The method of claim 1 , wherein interrogating the optical fiber includes interrogating the portion of the optical fiber with the portion of the optical fiber coupled to an electro-optic transducer disposed along the pipe, the electro-optic transducer coupled to the two monitor electrodes. 5. The method of claim 4 , wherein controlling the current and interrogating the optical fiber over time includes: setting a main current in the formation from one of the three current electrodes; adjusting a bucking current in the formation from a one of the other two current electrodes in the set of three current electrodes such that a voltage difference between the two monitor electrodes coupled to the electro-optic transducer is zero at a given baseline time where the waterflood is far away from the wellbore; and measuring the voltage difference between the two monitor electrodes coupled to the electro-optic transducer as the waterflood approaches the wellbore. 6. The method of claim 4 , wherein controlling the current and interrogating the optical fiber over time includes: setting a main current in the formation from one of the three current electrodes; adjusting a bucking current in the formation from a one of the other two current electrodes in the set of three current electrodes such that a voltage difference between the two monitor electrodes coupled to the electro-optic transducer is zero; and measuring the adjusted bucking current as the waterflood approaches the wellbore. 7. The method of claim 1 , wherein controlling the current includes: monitoring a signal level due to the waterflood to determine a point at which the signal level reaches saturation; adjusting a bucking current from one of the three current electrodes such that a signal level due to the waterflood is reduced to a minimal level at the point at which the signal level reaches saturation; or controlling current in a plurality of sets of three current electrodes, including the set of three current electrodes, with the current electrodes of the sets of three current electrodes disposed on the pipe at different azimuthal positions at substantially a same axial position along a longitudinal axis of the pipe to determine direction of the waterflood as the waterflood progresses. 8. The method of claim 1 , wherein the method includes monitoring progression of waterflood to the wellbore from a plurality of injector wells. 9. The method of claim 1 , wherein the bucked measurements include voltage measurements using a baseline bucking scheme or current measurements using a continuous bucking scheme. 10. A non-transitory machine-readable storage device having instructions stored thereon, which, when executed by one or more processors of a machine, cause the machine to perform operations, the operations comprising: controlling current in a set of three current electrodes forming a bi-pole to inject current into a formation around a pipe in a wellbore, the three current electrodes disposed on the pipe in the wellbore such that two current electrodes of the three current electrodes inject current and the third current electrode is operatively arranged as a current return, the three current electrodes associated with a set of two monitor electrodes, the two monitor electrodes being two current electrodes of the set of three current electrodes or two electrodes different from the set of three current electrodes, interrogating an optical fiber, the optical fiber extending along the longitudinal axis of the pipe with a portion of the optical fiber associated with the set of three current electrodes in a sensing operation using the set of three current electrodes; determining progression of waterflood with respect to the wellbore from controlling the current and interrogating the optical fiber over time; and operating a processor to determine waterflood distance and resistivity that minimizes misfit between bucked measurements and synthetic data, the synthetic data generated using a model that includes simulation of operation of the set of three current electrodes in the formation, the bucked measurements generated using the controlling of the current of the set of three current electrodes and interrogating the optical fiber over time. 11. A system comprising: a set of electrodes disposed on a pipe in a wellbore, the set having three current electrodes operable to inject current into a formation around the pipe in the wellbore with one of the three current electrodes of the set operatively arranged as a return, the set arranged to include two monitor electrodes, the two monitor electrodes being two current electrodes of the three current electrodes or two electrodes different from the three current electrodes; an optical fiber extending along the longitudinal axis of the pipe with a portion of the optical fiber associated with the set of electrodes in a sensing operation of the set of electrodes; a set of processors arranged to control the injection of current by the three current electrodes, to control interrogation of the optical fiber over time, and to determine progression of waterflood with respect to the wellbore; and the processors being further arranged to determine watt Mood distance and resistivity that minimizes misfit between bucked measurements and synthetic data,