Method and apparatus for monitoring speed and position of a rotating member

The invention claimed is: 1. A method for evaluating signal outputs from first and second rotational sensing devices monitoring a multi-tooth target wheel rotationally coupled to a rotatable member, the method comprising: monitoring, by a controller, signal outputs from the first and second rotational speed sensing devices; incrementing a first counter when the first rotational speed sensing device detects a falling edge of one of the teeth of the target wheel; incrementing a second counter when the second rotational speed sensing device detects a falling edge of one of the teeth of the target wheel; incrementing a third counter when either of the first and second rotational speed sensing devices detects either of a rising edge and a falling edge of one of the teeth of the target wheel; determining a direction of rotation of the rotatable member based upon the third counter; determining a rotational speed of the rotatable member based upon one of the first and second counters; and indicating that the rotatable member is at zero speed when the rotational speed is less than a threshold speed and the direction of rotation of the rotatable member changes between a positive direction and a negative direction. 2. The method of claim 1 , further comprising: determining a duty ratio; determining whether the duty ratio is invalid; and indicating that the rotatable member is at a zero speed when the rotational speed is less than a threshold speed and the duty ratio is determined invalid. 3. The method of claim 2 , wherein determining whether the duty ratio is invalid comprises: monitoring a first elapsed period of time between a first set of successive current pulses associated with rising or falling edges detected in either of the signal outputs from the first and second rotational speed sensing devices; monitoring a second elapsed period of time between a second set of successive current pulses associated with rising or falling edges detected in either of the signal outputs from the first and second rotational speed sensing devices; calculating a duty ratio between the first and second elapsed periods of time; and comparing the duty ratio to a duty ratio threshold. 4. The method of claim 3 , further comprising determining the duty ratio threshold based upon an ideal duty ratio of 1.0 when the second rotational sensing device is offset by 90° of a single tooth cycle in relation to the first sensing device, the ideal duty ratio of 1.0 adjusted based upon a maximum acceleration rate of the rotating member. 5. The method of claim 1 , wherein indicating that the rotatable member is at a zero speed when the rotational speed is less than a threshold speed and the direction of rotation of the rotatable member changes between a positive direction and a negative direction comprises indicating that the rotatable member is at a zero speed when the direction of rotation of the rotatable member changes between the positive direction and the negative direction during successive determinations of the direction of rotation of the rotatable member based upon the third counter. 6. The method of claim 1 , wherein monitoring signal outputs from the first and second rotational speed sensing devices comprises monitoring discrete signal outputs from the first and second rotational speed sensing devices. 7. A method for evaluating signal outputs from first and second rotational sensing devices monitoring a multi-tooth target wheel rotationally coupled to a rotatable member, the second rotational sensing device offset by 90° of a single tooth cycle in relation to the first sensing device, the method comprising: monitoring, by a controller, signal outputs from the first and second rotational speed sensing devices; incrementing a first counter when the first rotational speed sensing device detects a falling edge of one of the teeth of the target wheel; incrementing a second counter when the second rotational speed sensing device detects a falling edge of one of the teeth of the target wheel; incrementing a third counter when either of the first and second rotational speed sensing devices detects either of a rising edge and a falling edge of one of the teeth of the target wheel; determining a rotational speed of the rotatable member based upon one of the first and second counters; determining a duty ratio; determining whether the duty ratio is invalid; and indicating the rotatable member is at a zero speed when the rotational speed is less than a threshold speed and the duty ratio is invalid. 8. The method of claim 7 , wherein determining the duty ratio comprises: monitoring a first elapsed period of time between a first set of successive current pulses associated with rising or falling edges detected in one of the signal outputs from the first and second rotational speed sensing devices; monitoring a second elapsed period of time between a second set of successive current pulses associated with corresponding rising or falling edges detected in the one of the signal outputs from the first and second rotational speed sensing devices; and calculating a ratio between the first and second elapsed periods of time. 9. The method of claim 7 , wherein determining whether the duty ratio is invalid comprises comparing the duty ratio to a duty ratio threshold, the duty ratio threshold determined based upon an ideal duty ratio of 1.0 when the second rotational sensing device is offset by 90° of a single tooth cycle in relation to the first sensing device, the ideal duty ratio of 1.0 adjusted based upon a maximum acceleration rate of the rotating member. 10. The method of claim 7 , further comprising determining a direction of rotation of the rotatable member based upon the third counter. 11. The method of claim 7 , further comprising: determining a rotational speed of the rotatable member based upon one of the first and second counters; and indicating that the rotatable member is at zero speed when the rotational speed is less than a threshold speed and the direction of rotation of the rotatable member changes between a positive direction and a negative direction. 12. The method of claim 7 , wherein indicating the rotatable member is at a zero speed when the rotational speed is less than a threshold speed and the direction of rotation of the rotatable member changes between a positive direction and a negative direction comprises indicating the rotatable member is at a zero speed when the direction of rotation of the rotatable member changes between the positive direction and the negative direction during successive determinations of the direction of rotation of the rotatable member based upon the third counter. 13. The method of claim 7 , wherein monitoring signal outputs from the first and second rotational speed sensing devices comprises monitoring discrete signal outputs from the first and second rotational speed sensing devices. 14. A method for evaluating signal outputs from first and second rotational sensing devices monitoring a multi-tooth target wheel rotationally coupled to a rotatable member, the second rotational sensing device offset by 90° of a single tooth cycle in relation to the first sensing device, the method comprising: monitoring, by a controller, signal outputs from the first and second rotational speed sensing devices; incrementing a first counter when the first rotational speed sensing device detects a falling edge of one of the teeth of the target wheel; determining a rotational speed of the rotatable member based upon the first counter; incrementing a third counter when either of the first and second rotational speed sensing