Apparatus for detecting sensor error

What is claimed is: 1. A magnetic angle measurement system comprising: a first magnetic angle sensor having a first plurality of outputs comprising a first subset of outputs and a second subset of outputs, wherein the first subset of outputs is a different combination of the first plurality of outputs from the second subset of outputs; a second magnetic angle sensor having a second plurality of outputs; a first signal processing circuitry in a first signal processing path, the first signal processing circuitry configured to receive the first subset of outputs from the first magnetic angle sensor and determine first magnetic angle data based on the received first subset of outputs; a second signal processing circuitry in a second signal processing path configured to receive the second subset of outputs from the first magnetic angle sensor and determine second magnetic angle data based on the received second subset of outputs; a third signal processing circuitry in a third signal processing path configured to receive the second plurality of outputs from the second magnetic sensor and determine third magnetic angle data based on the received second plurality of outputs; and a processor configured to compare the first, second, and third magnetic angle data and determine a processing result based on the comparison, wherein fault tolerance resolution of the magnetic angle measurement system is based at least in part on the processing result. 2. The magnetic angle measurement system of claim 1 wherein determining the processing result comprises determining agreement between two of the first, second, and third magnetic angle data. 3. The magnetic angle measurement system of claim 2 wherein the processing result comprises one of the two magnetic angle data in agreement. 4. The magnetic angle measurement system of claim 1 wherein the first, second, and third signal processing paths are independent paths. 5. The magnetic angle measurement system of claim 1 further comprising fault detection circuitry configured to monitor the first, second, and third signal processing paths for faults. 6. The magnetic angle measurement system of claim 5 wherein determining the processing result comprises determining no agreement between the first, second and third magnetic angle data and determining that the faults exist on two of the three signal processing paths. 7. The magnetic angle measurement system of claim 6 wherein the processing result comprises the magnetic angle data from the processing path not having the fault. 8. The magnetic angle measurement system of claim 1 further comprising: a third magnetic angle sensor having a third plurality of outputs and a fourth magnetic angle sensor having a fourth plurality of outputs; a fourth signal processing circuitry in a fourth signal processing path configured to determine fourth magnetic angle data based on a first subset of the third plurality of outputs from the third magnetic angle sensor; a fifth signal processing circuitry in a fifth signal processing path configured to determine fifth magnetic angle data based on a second subset of the third plurality of outputs from the third magnetic angle sensor; and a sixth signal processing circuitry in a sixth signal processing path configured to determine sixth magnetic angle data based on the fourth plurality of outputs from the fourth magnetic sensor, wherein the processor is further configured to determine the processing result based on the comparison and the fourth, fifth, and sixth magnetic angle data. 9. The magnetic angle measurement system of claim 8 wherein determining the processing result comprises determining no agreement between the first, second and third magnetic angle data and determining that the fourth, fifth, and sixth magnetic angle data agree with one of the first, second and third magnetic angle data. 10. The magnetic angle measurement system of claim 9 wherein the processing result comprises the one of the first, second and third magnetic angle data in agreement with the fourth, fifth, and sixth magnetic angle data. 11. A method for controlling a motor, the method comprising: obtaining a first data from a first signal processing path, a second data from a second signal processing path, and a third data from a third signal processing path, the first data and the second data being associated with a first sensor having a plurality of outputs comprising a first subset of outputs and a second subset of outputs, the first subset of outputs is a different combination of the plurality of outputs from the second subset of outputs, the first data being generated by the first subset of outputs and the second data being generated by the second subset of outputs, the third data being associated with a second sensor that is different from the first sensor, and the first, second, and third signal processing paths being independent of each other; determining a first angle, a second angle, and a third angle from the first, the second, and the third data, respectively, comparing, with a processor, the first, second, and third angles; and controlling the motor based at least in part on the comparison. 12. The method of claim 11 wherein the controlling the motor based on the comparison comprises determining that two of the first, the second and the third angles match and controlling the motor using one of the two matching angles in response to the determining that two of the first, the second and the third angles match. 13. The method of claim 11 further comprising monitoring the first, second, and third signal processing paths to detect errors and causing an indication of an active fault flag in response to detecting the error, the active fault flag associated with the signal processing path having the detected error. 14. The method of claim 13 wherein the controlling the motor based on the comparison comprises determining that the first, second and third angles mismatch, determining that active fault flags are associated with two of the first, second, and third signal processing paths, and controlling the motor using the angle associated with the signal processing path not associated with the active fault flag in response to the determination that the active fault flag is associated with the two of the first, second, and third signal processing paths. 15. The method of claim 13 wherein the first sensor is an anisotropic magnetoresistive sensor and the second sensor is a tunneling magnetoresistive sensor. 16. The method of claim 11 further comprising: obtaining a fourth data from a fourth signal processing path, a fifth data from a fifth signal processing path, and a sixth data from a sixth signal processing path, the fourth and the fifth data being associated with a third sensor, the sixth data being associated with a fourth sensor that is different from the third sensor, and the fourth, fifth, and sixth signal processing paths being independent of each other; determining a fourth angle, a fifth angle, and a sixth angle from the fourth, the fifth, and the sixth data, respectively; and controlling the motor based on the comparison and the fourth, fifth, and sixth angles. 17. The method of claim 16 wherein controlling the motor comprises determining no agreement between the first, second and third angles and determining that the fourth, fifth, and sixth angles agree with one of the first, second and third angles. 18. A motor control system configured as part of a vehicle control system, the motor control system comprising: a shaft in communication with a ste