Large surface magnetic field sensor array

What is claimed is: 1. A method of analyzing an electrical current over a target surface, comprising: providing a plurality of magnetic field sensors, each sensor operatively connected to an integrator; positioning the plurality of magnetic field sensors proximate the target surface; applying an electrical current to the target surface; sensing a change in magnetic field strength at one or more sensor locations; integrating the changes in magnetic field strength to derive a magnetic field strength value at each sensor location; inferring a current density over the target surface from the plurality of magnetic field strength values and corresponding sensor locations; interpolating magnetic field strength values between sensor locations; calculating virtual sensor locations corresponding to the interpolated magnetic field strength values; inferring a local virtual current value from each interpolated magnetic field strength value; and mapping the local virtual current values to the target surface using the corresponding virtual sensor locations. 2. The method of claim 1 wherein inferring a current density over the target surface comprises inferring a local current value from each magnetic field strength value, and mapping the local current values to the target surface using the corresponding sensor locations. 3. The method of claim 1 further comprising, prior to sensing a change in magnetic field strength at one or more sensor locations, calibrating each magnetic field sensor to compensate for individual sensor differences due to manufacturing tolerances. 4. The method of claim 3 wherein the magnetic field sensors each comprise a wire coil, and wherein the manufacturing tolerances include at least one of the type of wire in the coil, the number of turns of wire in the coil, and the area of the coil. 5. The method of claim 1 wherein the plurality of magnetic field sensors is positioned in a fixed array, and further comprising, prior to sensing a change in magnetic field strength at one or more sensor locations, calibrating the plurality of magnetic field sensors by: providing a proxy surface, formed of a dielectric material and including one or more conductors, the proxy surface approximating the geometry of the target surface; positioning the array of magnetic field sensors proximate the proxy surface; applying an electrical current through the conductors of the proxy surface; sensing a change in magnetic field strength at one or more sensor locations; integrating the changes in magnetic field strength to derive a magnetic field strength value at each sensor location; and calibrating the array of magnetic field sensors to compensate for individual sensor differences due to geometries of the proxy surface and sensor array. 6. The method of claim 1 wherein one or more magnetic field sensors comprise two or more wire coils oriented to sense changes in magnetic field strength in different directions, and wherein deriving a magnetic field strength value at each sensor location further comprises deriving a resultant magnetic field strength and direction for each magnetic field sensor by combining magnetic field strength values of the two or more wire coils and the wire coil orientations. 7. The method of claim 6 wherein the wire coil orientation directions are orthogonal to each other. 8. The method of claim 7 wherein one or more magnetic field sensors comprise three wire coils oriented to sense changes in magnetic field strength in three orthogonal directions. 9. The method of claim 1 wherein one or more magnetic field sensors comprise two wire coils oriented along the same direction but oppositely wound, and wherein deriving a magnetic field strength value at each sensor location comprises deriving the magnetic field strength from a common mode of the two wire coils, wherein extraneous magnetic fields are rejected. 10. An apparatus operative to analyze an electrical current over a target surface, comprising: a plurality of magnetic field sensors positioned at known locations in an array, each magnetic field sensor operative to sense a change in magnetic field strength; an integrator operatively connected to each magnetic field sensor and operative to derive a magnetic field strength value by integrating the connected sensor's output; and a data processing system operative to: receive an output of each integrator, infer a current density over the target surface from the plurality of magnetic field strength values and corresponding sensor locations; interpolate magnetic field strength values between sensor locations; calculate virtual sensor locations corresponding to the interpolated magnetic field strength values; infer a local virtual current value from each interpolated magnetic field strength value; and map the local virtual current values to the target surface using the corresponding virtual sensor locations. 11. The apparatus of claim 10 wherein one or more magnetic field sensors comprise two or more wire coils oriented to sense changes in magnetic field strength in different directions, and wherein the data processing system is further operative to derive a resultant magnetic field strength and direction for each magnetic field sensor by combining magnetic field strength values of the two or more wire coils and the wire coil orientations. 12. The apparatus of claim 11 wherein the wire coil orientation directions are orthogonal to each other. 13. The apparatus of claim 12 wherein one or more magnetic field sensors comprise three wire coils oriented to sense changes in magnetic field strength in three orthogonal directions. 14. The apparatus of claim 11 wherein the array of magnetic field sensors comprises: a substrate; and a plurality of mounting members affixed to the substrate at the known magnetic field sensor locations, each mounting member comprising at least two extension members on which wire coils are wound to form magnetic field sensors, wherein the plurality of mounting members are affixed to the substrate such that corresponding extension members are oriented in the same direction. 15. The apparatus of claim 14 wherein the extension members comprise corresponding pairs of extension members oriented 180° apart; the pairs of coils are wound in opposite directions on each extension member of a pair, the integrator is further operative to derive a magnetic field strength value at each sensor location from a common mode of each pair of wire coils, and wherein extraneous magnetic fields are rejected. 16. The apparatus of claim 10 wherein the array is sufficiently larger than the target surface that when the array is positioned proximate the target surface, a subset of magnetic field sensors are positioned beyond the outer edges of the target surface. 17. A non-transitory computer-readable medium storing program instructions operative to cause a data processing system to process magnetic field sensor array outputs to analyze an electrical current over a target surface by performing the steps of: sensing a change in magnetic field strength at one or more sensor locations on the array, when the magnetic field sensor array is positioned proximate the target surface and an electrical current is applied to the target surface; integrating the changes in magnetic field strength to derive a magnetic field strength value at each sensor location; and inferring a local current value from each magnetic field strength value; inferring a current density over the target surface by mapping the local current values to the target surface usi