Disturbance rejection for current-measurement systems

What is claimed is: 1. An in-hole sampled current-measurement system with uninterrupted short-circuit/overcurrent detection, system comprising: three or more magnetic-field sensors configured to be inserted into a hole in an electrical conductor, each sensor operative to generate a signal at an output in response to a magnetic-field strength at the sensor's location; a selection module coupled to each of the sensors' outputs to receive each of the sensors' respective signals representative of the magnetic-field strength at each of the sensors' respective locations; a control module operative to control the selection module to select a subset of the magnetic-field sensors at a scheduled time of a predetermined disturbance event, and to cause a set of the non-selected magnetic-field sensors, which are scheduled to receive a disturbance associated with the predetermined disturbance event, to be deselected at the scheduled time of the predetermined disturbance event; a continuous-measurement module coupled to the selection module to process the signals associated with the selected subset of the magnetic-field sensors to generate a continuous output signal representative of an electrical current in the electrical conductor; and a periodic-measurement module coupled to each of the three or more magnetic-field sensors' outputs to receive each of the three or more sensors' respective signals representative of the magnetic-field strength at each of the three or more sensors' respective locations, and operative to process the received three or more magnetic-field sensors' outputs to generate a periodic output signal representative of the electrical current in the electrical conductor. 2. The in-hole current-measurement system of claim 1 , further comprising a short circuit detector that generates an alarm signal if the continuous output signal exceeds a predetermined current threshold. 3. The in-hole sampled current-measurement system of claim 1 , wherein a set of three or more of the magnetic-field sensors are aligned on an axis configured to be mounted with at least a component of the aligned axis perpendicular to a direction of the electrical-current in the conductor when inserted into the hole in the electrical conductor. 4. The in-hole sampled current-measurement system of claim 2 , wherein each of the three or more magnetic-field sensors have a direction of magnetic sensitivity aligned perpendicular to both the aligned axis and the direction of electrical-current flow when inserted into the hole in the electrical conductor. 5. The in-hole sampled current-measurement system of claim 1 , wherein each of the three or more magnetic-field sensors comprises an Anisotropic Magneto-Resistive (AMR) sensor having a thin film of Permalloy, and further comprising an AMR Set/Reset (SR) module for aligning the magnetic domains of the thin film of Permalloy parallel to an easy axis, wherein an expected disturbance signal comprises either a Set pulse or a Reset pulse for aligning the magnetic domains of the thin film of Permalloy parallel to an easy axis of an AMR sensor. 6. An in-hole current-measurement system with uninterrupted short-circuit/overcurrent detection, system comprising: three or more magnetic-field sensors configured to be inserted into a hole in an electrical conductor, each sensor operative to generate a signal at an output in response to a magnetic-field strength at the sensor's location; a selection module coupled to each of the sensors' outputs to receive each of the sensors' respective signals representative of the magnetic-field strength at the sensor's location; a control module operative to control the selection module to select a subset of the magnetic-field sensors at a scheduled time of a predetermined disturbance event, and to cause a set of the non-selected magnetic-field sensors, which are scheduled to receive a disturbance associated with the predetermined disturbance event, to be deselected at the scheduled time of the predetermined disturbance event; a continuous-measurement module coupled to the selection module to process the signals associated with the selected subset of the magnetic-field sensors to generate a continuous output signal representative of an electrical current in the electrical conductor; and a periodic-measurement module coupled to each of the three or more magnetic-field sensors' outputs to receive each of the three or more sensors' respective signals representative of the magnetic-field strength at each of the three or more sensors' respective locations, and operative to process the received three or more magnetic-field sensors' outputs to generate a periodic output signal representative of the electrical current in the electrical conductor; wherein outputs of a first and second magnetic-field sensor are connected to a first amplifier; wherein outputs of the second and a third magnetic-field sensor are connected to a second amplifier; wherein outputs of the third and a fourth magnetic-field sensor are connected to a third amplifier; wherein the first and third amplifier are connected to mutually exclusive pairs of magnetic-field sensors. 7. The in-hole current-measurement system of claim 6 , further comprising a short circuit detector that generates an alarm signal if the continuous output signal exceeds a predetermined current threshold. 8. The in-hole current-measurement system of claim 6 , wherein the selected subset of sensor signals consists of two sensor signals and the generated continuous output signal is based upon a difference between the two signals of the two sensors of the selected subset. 9. The in-hole current-measurement system of claim 6 , wherein a set of three or more of the magnetic-field sensors are aligned on an axis configured to be mounted with at least a component of the aligned axis perpendicular to a direction of electrical-current flow of the conductor when inserted into the hole in the electrical conductor. 10. The in-hole current-measurement system of claim 9 , wherein each of the three or more the magnetic-field sensors have a direction of sensitivity aligned perpendicular to both the aligned axis and the direction of electrical-current flow when inserted into the hole in the electrical conductor. 11. The in-hole current-measurement system of claim 6 , wherein each of the three or more magnetic-field sensors comprises an Anisotropic Magneto-Resistive (AMR) sensor. 12. The in-hole current-measurement system of claim 11 , wherein each of the AMR sensors comprise a thin film of Permalloy. 13. The in-hole current-measurement system of claim 12 , wherein the predetermined disturbance event comprises either a Set pulse or a Reset pulse for aligning the magnetic domains of the thin film of Permalloy parallel to an easy axis of an AMR sensor. 14. A method of measuring current in a conductor, the method comprising: receiving signals from outputs of N magnetic-field sensors; retrieving coefficients corresponding to the N magnetic-field sensors; summing products of the coefficients and the sensors output values to calculate a raw current measurement; retrieving a calibration coefficient from a memory; multiplying the retrieved calibration coefficient by the calculated raw current measurement to calculate a measured electrical current; initializing both a time stamp and a first pair of AMR sensors of the N magnetic-field sensors; retrieving a delta time window length during which the first pair of AMR sensors will be disabled during a set/reset operation; sending a first signal to a fast analog multiplexor to select a second pair of AMR sensors of the N magnetic-field sen