System and method for determining angular position in rotating machines

What is claimed is: 1. A system for determining angular position comprising: a first body including a shaft, a flat disk having a circumference, and a track having segments arranged around the shaft at a diameter of the track in a repeating sequence, the track located on the disk, the segments defined by ridges and grooves alternating around and extending from the circumference, the ridges being spiral shaped and identical, wherein a ridge-groove pair of the ridges and grooves defines one of the segments; and a second body, including a sensor facing the track, wherein the first and second bodies rotate relative to each other about an axis, wherein the track includes a height in each of the segments between a peak of a respective one of the ridges of the respective segment and a bottom of a respective one of the grooves of the respective segment, wherein the track and the sensor face each other; wherein the sensor is configured to generate an output that is decoupled from the diameter of the track and is related to the repeating sequence of segments, wherein an amplitude of the output is related to the height, wherein a period of the output is related to the repeating sequence of segments, wherein the sensor is a magnetic sensor. 2. The system of claim 1 , wherein the track extends three-hundred-sixty degrees around the shaft. 3. The system of claim 1 , wherein the sensor is a first sensor and comprising a second sensor, wherein the first sensor and the second sensor face the track and are disposed relative to one another with a tangential spacing to create concurrent sine and cosine outputs in response to relative movement of the track. 4. The system of claim 1 , comprising a printed circuit card assembly, with the sensor disposed on the printed circuit card assembly, wherein a magnet is disposed on an opposite side of the printed circuit card assembly from the sensor. 5. The system of claim 4 , wherein the sensor is configured to generate a sinusoidal output as a result of the repeating sequence of segments varying a magnetic field generated by the magnet. 6. The system of claim 1 , wherein the track is annular in shape the ridges rising from the flat disk toward the sensor in a direction parallel to the shaft. 7. The system of claim 1 , wherein the track comprises a part of the first body with the sensor facing in a direction parallel to the axis and at the track. 8. The system of claim 1 , comprising a motor containing the first and second bodies, wherein the period is related to the repeating sequence of the segments by being defined by a total number of the ridges and the grooves, wherein the total number corresponds to a number of poles of the motor. 9. The system of claim 1 , comprising a printed circuit card assembly carrying the sensor; and a magnet disposed on an opposite side of the printed circuit card assembly from the sensor and configured to generate a magnetic field, wherein the sensor is configured to sense a variation in the magnetic field caused by rotation of the track. 10. The system of claim 1 , wherein the first body is a rotor of an electrical machine having a number of pole pairs, and wherein the ridges and grooves together comprise the number, so that the sensor generates the output useable to commutate the electrical machine. 11. A method for determining angular position comprising: arranging a flat disk having a repeating sequence of segments in a track disposed at a diameter around a shaft of a first body, the disk having a circumference, the segments defined by ridges and grooves alternating around and extending from the circumference, the ridges being spiral shaped and identical, with a ridge-groove pair of the ridges and grooves defining one of the segments, the track including a height in each of the segments between a peak of a respective one of the ridges of the respective segment and a bottom of a respective one of the grooves of the respective segment; positioning a sensor on a second body, the sensor facing the track; configuring the first and second bodies to rotate relative to each other about an axis; mounting the track and the sensor to face each other; generating, by the sensor, an output that is decoupled from the diameter of the track, has an amplitude related to the height, and has a period related to a number of the repeating sequence of segments, wherein the sensor is a magnetic sensor. 12. The method of claim 11 , wherein the track extends three-hundred-sixty degrees around the shaft, and comprising configuring the track so that as the ridges pass the sensor, the output of the sensor varies sinusoidally. 13. The method of claim 12 , comprising aligning a magnet with the sensor, with the sensor disposed between the track and the magnet. 14. The method of claim 12 , comprising positioning the sensor on a printed circuit card assembly and positioning a magnet on an opposite side of the printed circuit card assembly from the sensor. 15. The method of claim 14 , comprising: varying a magnetic field generated by the magnet by movement of the repeating sequence of segments; and the movement of the repeating sequence of segments causes the output of the sensor to be sinusoidal. 16. The method of claim 12 , comprising: positioning the sensor on the printed circuit card assembly; and configuring the track with an annular shape. 17. The method of claim 11 , wherein the track extends three-hundred sixty degrees around the shaft. 18. The method of claim 11 , comprising: positioning a magnet on an opposite side of the printed circuit card assembly from the sensor; and sensing, by the sensor, a variation in a magnetic field generated by the magnet, the variation caused by rotation of the track. 19. A system for determining angular position of an electrical machine, the system comprising: a rotor including a shaft, a flat disk having a circumference, and a track having segments arranged around the shaft at a diameter of the track in a repeating sequence, the track located on the disk, the segments defined by ridges and grooves alternating around and extending from the circumference, the ridges being spiral shaped and identical, wherein a ridge-groove pair of the ridges and grooves defines one of the segment, wherein the rotor is configured to rotate about an axis, wherein the track includes a height in each of the segments between a peak of a respective one of the ridges of the respective segment and a bottom of a respective one of the grooves of the respective segment; a stator of the electrical machine; and a printed circuit board assembly stationary relative to the stator, the printed circuit board assembly encircling the shaft, including driver electronics of the electrical machine, and including a sensor facing the track, wherein the track and the sensor face each other in directions that are parallel to the axis, wherein the sensor is configured to generate an output that is decoupled from the diameter of the track and is related to the repeating sequence of segments, wherein a period of the output is related to the repeating sequence of the segments, wherein the sensor is a magnetic sensor.