Temperature compensated torque sensor

What is claimed is: 1. A magnetostrictive sensor comprising: a sensor head including, a driving pole having a driving coil coupled thereto that is configured to generate a first magnetic flux for impinging a target in response to receipt of a driving current; a sensing pole having a sensing coil coupled thereto that is configured to, output a first signal based at least upon a second magnetic flux resulting from interaction of the first magnetic flux with the target; and output a second signal based upon heat received from the target; and a controller in electrical communication with the sensor head and configured to: transmit the driving current to the driving coil; receive the first and second signals; determine a force applied to the target based upon the first signal; determine a temperature of the target based upon the second signal; and adjust the force determined from the first signal based upon the temperature determined from the second signal. 2. The magnetorestrictive sensor of claim 1 , wherein the first signal does not interfere with the second signal. 3. The sensor of claim 1 , wherein the sensing coil is positioned at about a free end of the sensing pole. 4. The sensor of claim 1 , wherein the force is a torque. 5. The sensor of claim 1 , wherein the sensing coil is in electrical communication with a first circuit configured to receive the first signal and a second circuit configured to receive the second signal. 6. The sensor of claim 5 , wherein the first signal is a first alternating current and the second signal is a second alternating current having a frequency less than the first signal such that the second alternating current is substantially independent of an inductance of the sensing coil. 7. The sensor of claim 5 , wherein the first signal is a first alternating current and the second signal is a direct current. 8. A magnetostrictive sensor, comprising: a sensor head extending between a proximal end and a distal end that contains, a driving pole having a driving coil coupled thereto that is configured to generate a first magnetic flux extending through the distal end of the sensor head for impinging a target in response to receipt of a driving current; a sensing pole having a sensing coil coupled thereto that is configured to output a first signal based at least upon a second magnetic flux resulting from interaction of the first magnetic flux with the target; and a temperature sensor including a continuous length of electrically conductive wire that forms an open-sided shape extending within a plane defined by the distal end of the sensor head, wherein the temperature sensor is secured to the distal end of the sensor head and is configured to output a second signal based upon heat received from the target. 9. The sensor of claim 8 , wherein the temperature sensor is configured to avoid magnetically interfering with each of the driving coil and the sensing coil. 10. The sensor of claim 8 , wherein the open-sided shape does not overlie either of the driving pole and the sensing pole along a longitudinal axis of the sensor head. 11. The sensor of claim 8 , wherein the open-sided shape is positioned on an inner face of the distal end of the sensor head. 12. The sensor of claim 8 , wherein the open-sided shape is positioned on an outer face of the distal end of the sensor head. 13. The sensor of claim 8 , wherein the distal end of the sensor head is laminated and wherein the open-sided shape is positioned between layers of the laminated distal end of the sensor head. 14. The sensor of claim 8 , including a controller in electrical communication with the sensor head and configured to: transmit the driving current to the driving coil; receive the first and second signals; determine a force applied to the target based upon the first signal; determine a temperature of the target based upon the second signal; and adjust the force determined from the first signal based upon the temperature determined from the second signal. 15. The sensor of claim 8 , wherein the force is a torque. 16. A sensing method, comprising: generating a first magnetic flux with a driving coil coupled to a driving pole of a magnetostrictive sensor; directing the first magnetic flux through a ferromagnetic target and a sensing pole of the magnetostrictive sensor; detecting, by a sensing coil coupled to the sensing pole of the magnetostrictive sensor, a second magnetic flux resulting from interaction of the first magnetic flux with the target; outputting, by the sensing coil, a first signal based at least upon a second magnetic flux resulting from interaction of the first magnetic flux with the target; outputting, by the sensing coil, a second signal based upon heat received from the target; determining a force applied to the target based upon the first signal; determining a temperature of the target based upon the second signal; and adjusting the force determined from the first signal based upon the temperature determined from the second signal. 17. The method of claim 16 , wherein the target is rotating and the first signal represents a torque applied to the target. 18. The method of claim 17 , wherein the torque represented by the first signal and the temperature represented by the second signal are detected approximately concurrently and at about a same region of the target. 19. The method of claim 16 , wherein the sensing coil is distanced from the target. 20. The method of claim 19 , wherein the sensing coil is positioned at about a free end of the sensing pole.