Proximity sensor to sense rotating shaft position and velocity

What is claimed is: 1. A shaft monitoring system comprising: a rotatable shaft including a target element coupled thereto that rotates along with the shaft, the target element including a series of individual target sections arranged sequentially one after another; a proximity sensor located adjacent to the target element, the proximity sensor configured to measure an inductance of the target element based on one or both of the volume of the target element indicated by the individual target section sensed by the proximity sensor and a distance between the individual target section of the target element and the proximity sensor, and to generate a proximity sensor output signal based on the measured inductance; and a signal processing system in signal communication with the proximity sensor, the signal processing system configured to determine at least one of a position of the shaft, a rotational speed of the shaft, and a rotational direction of the shaft based on the proximity sensor output signal, wherein the individual target sections directly contact one another such that each of the different measured inductances corresponds to a respective rotational position of the shaft, and wherein the different measured inductances increase according to a positive constant slope defined as a change in the inductance of the target elements with respect to a change in the rotational position of the shaft in response to rotating the shaft in a first direction, and wherein the different measured inductances decrease according to a negative constant slope defined as a change in the inductance of the target elements with respect to a change in the rotational position of the shaft in response to rotating the shaft in a second direction opposite the first direction. 2. The shaft monitoring system of claim 1 , wherein the volume of the target element continuously changes as the target element extends from a first end of the target element to an opposing second end of the target element. 3. The shaft monitoring system of claim 2 , wherein a proximity of the volume with respect to the proximity sensor produces a respective measured inductance, and the respective measured inductance corresponds to a respective rotational position of the shaft. 4. The shaft monitoring system of claim 3 , wherein rotating the shaft rotates the target element and varies the volume of the target element aligned with the proximity sensor to change the measured inductance. 5. The shaft monitoring system of claim 4 , wherein the position of the shaft, the rotational speed of the shaft, and the rotational direction are determined in response to rotating the shaft. 6. The shaft monitoring system of claim 2 , wherein a minimum volume of the target element is at the first end and a maximum volume is located at the second end. 7. The shaft monitoring system of claim 6 , wherein the target element extends three-hundred and sixty (360) degrees from the first end to the second end to define a circumferential profile. 8. The shaft monitoring system of claim 1 , wherein the distance changes based on a rotational position of the shaft. 9. The shaft monitoring system of claim 8 , wherein rotating the shaft produces different distances between the target element and the proximity sensor to produce different measured inductances. 10. A method of monitoring a rotatable shaft, the method comprising: positioning a target element coupled to the rotatable shaft a distance away from a proximity sensor, the target element including a series of individual target sections arranged sequentially one after another; measuring, via the proximity sensor, an inductance based on one or both of a volume of the target element indicated by the individual target section sensed by the proximity sensor and a distance between the individual target section of the target element and the proximity sensor; generating a proximity sensor output signal based on the measured inductance; determining, via a signal processing system in signal communication with the proximity sensor, at least one of a position of the shaft, a rotational speed of the shaft, and a rotational direction of the shaft based on the proximity sensor output signal; determining a respective rotational position of the shaft based on a respective different measured inductance, wherein the individual target sections directly contact one another such that each of the different measured inductances corresponds to a respective rotational position of the shaft, and wherein the different measured inductances increase according to a positive constant slope defined as a change in the inductance of the target elements with respect to a change in the rotational position of the shaft in response to rotating the shaft in a first direction, and wherein the different measured inductances decrease according to a negative constant slope defined as a change in the inductance of the target elements with respect to a change in the rotational position of the shaft in response to rotating the shaft in a second direction opposite the first direction. 11. The method of claim 10 , wherein the volume of the target element continuously changes as the target element extends from a first end of the target element to an opposing second end of the target element. 12. The method of claim 11 , further comprising: producing a respective measured inductance based on a proximity of the volume with respect to the proximity sensor; and determining a respective rotational position of the shaft based on the respective measured inductance. 13. The method of claim 12 , further comprising: rotating the shaft so as to rotate the target element; and varying the volume of the target element aligned with the proximity sensor in response to rotating the target element to change the measured inductance. 14. The method of claim 13 , further comprising determine the position of the shaft, the rotational speed of the shaft, and the rotational direction in response to rotating the shaft. 15. The method of claim 11 , wherein a minimum volume of the target element is at the first end and a maximum volume is located at the second end. 16. The method of claim 15 , wherein the target element extends three-hundred and sixty (360) degrees from the first end to the second end to define a circumferential profile. 17. The method of claim 10 , further comprising changing the distance based on a rotational position of the shaft. 18. The method of claim 17 , further comprising producing different distances between the target element and the proximity sensor in response to rotating the shaft, and producing different measured inductances based on the different distances.