Fault current sensor with adjacent phase fault immunity

The invention claimed is: 1 . A fault current sensor system, comprising: a current sensor to detect a current in a monitored conductor in proximity to an adjacent conductor, the current sensor comprising: a first coil segment to generate a first voltage signal via a first port in response to current induced within the first coil segment, wherein the first coil segment is configured to be positioned proximate the monitored conductor in a first location that is between the monitored conductor and the adjacent conductor, and a second coil segment to generate a second voltage signal via a second port in response to current induced within the second coil segment, wherein the second coil segment is configured to be positioned in a second location relative to the monitored conductor that is approximately opposite the first location of the monitored conductor; and a supervision subsystem to evaluate magnitudes and phase angles of the first and second voltage signals to generate a supervisor signal that indicates that the first and second voltage signals are one of: invalid for fault detection of the monitored conductor, in response to a determination that the current in the adjacent conductor is inducing currents within the first and second coil segments that exceed a threshold value, and valid for fault detection of the monitored conductor, in response to a determination that the current in the adjacent conductor is inducing currents within the first and second coil segments that are less than a threshold value. 2 . The system of claim 1 , wherein the current sensor is configured to be positioned such that a distance between the monitored conductor and the first coil segment is approximately equal to a distance between the monitored conductor and the second coil segment, and wherein a distance between the adjacent conductor and the first coil segment is less than a distance between the adjacent conductor and the second coil segment. 3 . The system of claim 1 , wherein each of the first and second coil segments has a curved crescent shape, and the first and second coil segments are arranged to form at least a portion of a circle to be positioned around the monitored conductor. 4 . The system of claim 1 , wherein each coil segment comprises a segment of a current transformer (CT) and a resistor. 5 . The system of claim 1 , wherein each coil segment comprises a Rogowski coil segment. 6 . The system of claim 5 , wherein each of the first and second Rogowski coil segments is straight. 7 . The system of claim 5 , wherein the first Rogowski coil segment comprises a first helically coiled wire with a first center return and the second Rogowski coil segment comprises a second helically coiled wire with a second center return, wherein the first port comprises a first terminal connected to an end of the first helically coiled wire and a second terminal connected to an end of the first center return, and wherein the second port comprises a third terminal connected to an end of the second helically coiled wire and a fourth terminal connected to an end of the second center return. 8 . The system of claim 7 , wherein the first center return and the second center return are electrically connected, such that the second terminal of the first port and the fourth terminal of the second port are shared and form a center tap in a common center return. 9 . The system of claim 1 , further comprising a first integrator device connected to the first port of the first coil segment and a second integrator device connected to the second port of the second coil segment. 10 . The system of claim 1 , wherein the supervision subsystem evaluates the magnitudes and phase angles of the first and second voltage signals by: calculating an operate quantity based on a product of: (a) the magnitude of the first voltage signal, (b) the magnitude of the second voltage signal, and (c) a cosine function of a difference between (i) the phase angle of the second voltage signal and (ii) the phase angle of the first voltage signal; and comparing the operate quantity with a threshold load value. 11 . The system of claim 10 , wherein the threshold load value corresponds to a minimum load current expected in the monitored conductor. 12 . The system of claim 1 , further comprising: a fault indicator subsystem to generate a fault signal to indicate a fault in the monitored conductor based on both (1) the supervisor signal indicating that the first and second voltage signals are valid for the monitored conductor, and (2) a sum of the magnitudes of the first and second voltage signals exceeding a fault threshold value. 13 . The system of claim 12 , wherein the fault indicator subsystem comprises a differential amplifier to add phase-aligned magnitudes of the first and second voltage signals. 14 . The system of claim 12 , wherein the fault indicator subsystem is configured to ignore the first and second voltage signals in response to the supervisor signal indicating that the first and second voltage signals are invalid for the monitored conductor. 15 . The system of claim 12 , wherein the fault indicator subsystem is configured to generate a suspected adjacent-conductor fault signal in response to the supervisor signal indicating that the first and second voltage signals are invalid for the monitored conductor. 16 . A fault indication system for a three-phase power system, comprising: a current sensor to detect a current in a monitored phase line in proximity to an adjacent phase line, the current sensor comprising: a first Rogowski coil segment to generate a first voltage signal via a first port in response to current induced within the first Rogowski coil segment, wherein the first Rogowski coil segment is configured to be positioned proximate the monitored phase line in a first location that is between the monitored phase line and the adjacent phase line, and a second Rogowski coil segment to generate a second voltage signal via a second port in response to current induced within the second Rogowski coil segment, wherein the second Rogowski coil segment is configured to be positioned in a second location relative to the monitored phase line that is approximately opposite the first location of the monitored phase line; a supervision subsystem to evaluate magnitudes and phase angles of the first and second voltage signals to generate a supervisor signal that indicates that the first and second voltage signals are one of: invalid for fault detection of the monitored phase line, and valid for fault detection of the monitored phase line; and a fault indicator subsystem to generate a fault signal to indicate a fault in the monitored phase line in response to the supervisor signal indicating that the first and second voltage signals are valid and that a sum of the magnitudes of the first and second voltage signals exceeds a fault threshold value. 17 . The system of claim 16 , wherein the fault indicator subsystem comprises a differential amplifier to add phase-aligned magnitudes of the first and second voltage signals. 18 . The system of claim 16 , wherein the fault indicator subsystem is configured to generate an adjacent-phase fault signal in response to the supervisor signal indicating that the first and second voltage signals are invalid for the monitored phase line. 19 . The system of claim 16 , wherein the first Rogowski coil segment comprises a first helically coiled wire with a first center return and the second Rogowski coil segment c