Method, controller and system for monitoring brake operation

I claim: 1. A method of monitoring brake operation on a vehicle comprising: receiving a brake demand signal indicative of a brake demand; receiving a plurality of wheel speed signals from individual wheel speed sensors associated with individual wheel ends of the vehicle; determining a master value based on the plurality of wheel speed signals over an initiation time period for comparison with the plurality of wheel speed signals; determining a baseline calibration of each of the plurality of wheel speed signals over a calibration time period by comparing each of the individual wheel speed signals individually to the master value and storing the difference between each of the individual wheel speed signals and the master value as the baseline calibration for each of the individual wheel speed signals; determining if a long-term time period has elapsed since the brake demand signal indicated brake demand; determining the vehicle is not accelerating; calculating a difference of each individual wheel speed signal from the baseline calibration over a second time period equal to the calibration time period wherein the long-term time period has elapsed; comparing the difference to a long-term threshold; determining a long-term fault exists when the difference of an individual wheel speed signal is greater than or equal to the long-term threshold; and transmitting a brake control signal to at least one brake control device to modify the brake control at the individual wheel end associated with the wheel speed signal having the long-term fault. 2. The method as in claim 1 , further comprising: receiving at least one stability signal of the vehicle; wherein determining a master value occurs in response to an acceleration of the vehicle being about zero, the brake demand signal indicating no braking, and the at least one stability signal indicating no cornering. 3. The method as in claim 1 , wherein the master value comprises one of the average of the plurality of wheel speed signals, the mode of the plurality of wheel speed signals, and the vehicle speed as determined by another controller on the vehicle. 4. The method as in claim 1 , further comprising informing an operator of the vehicle of the long-term fault. 5. The method as in claim 1 , wherein the long-term time period is between about twenty minutes and about sixty minutes. 6. The method as in claim 1 , wherein transmitting a brake control signal to at least one brake control device to modify the brake control at the individual wheel end associated with the wheel speed signal having the long-term fault results in a reduction of a braking control pressure delivered by the brake control device. 7. A controller for monitoring brake operation of a vehicle comprising: a plurality of wheel speed inputs for receiving individual wheel speed sensor signals, each of the plurality of wheel speed inputs correlated with a specific wheel location; a brake demand input; an output for communicating a brake control signal to at least one brake control device; and a processing unit comprising control logic, wherein the processing unit is in communication with the plurality of wheel speed inputs, the brake demand input and the output, the control logic capable of: receiving a brake demand signal indicative of a brake demand; receiving signals from a plurality of wheel speed signals; determining a master value based on the plurality of wheel speed signals over an initiation time period for comparison with the plurality of wheel speed signals; determining a baseline calibration of each of a plurality of wheel speed signals over a calibration time period by comparing each of the individual wheel speed signals individually to the master value for the calibration time period and storing the difference between each of the individual wheel speed signals and the master value as the baseline calibration for each of the individual wheel speed signals; determining if a long-term time period has elapsed since receiving the brake demand signal; calculating a difference of each individual wheel speed signal from the baseline calibration over a second time period equal to the calibration time period wherein the long term time period has elapsed; comparing the difference to a long-term threshold; determining a long-term fault exists when the difference of an individual wheel speed signal is greater than or equal to the long-term threshold; and transmitting a brake control signal at the output to modify the brake control at a brake control device at a specific wheel location associated with the individual wheel speed sensor signal having the long-term fault. 8. The controller as in claim 7 , wherein the controller further comprises a plurality of stability sensor inputs for receiving stability signals; and the control logic is further capable of receiving at least one stability signal indicative of the cornering of the vehicle, wherein the determining a master value occurs in response to the acceleration of the vehicle being about zero, the brake demand signal indicates no braking and the at least one stability signal indicate no cornering. 9. The controller as in claim 8 , wherein the stability signal is received from at least one of a lateral acceleration sensor, a yaw rate sensor and a steering angle sensor. 10. The controller as in claim 7 , wherein the control logic is further capable of performing at least one of anti-lock braking and stability control functions. 11. The controller as in claim 7 , further comprising a communication port for receiving and transmitting a plurality of messages on a serial communications bus, the plurality of messages including at least vehicle speed and the long-term fault. 12. The controller as in claim 11 , wherein the master value comprises one of the average of the plurality of wheel speed signals, the mode of the plurality of wheel speed signals, and the vehicle speed as determined by another controller on the vehicle. 13. The controller as in claim 11 , wherein determining a master value comprises determining an individual wheel speed signal as one that is equal to an overall vehicle velocity as determined by a source other than the wheel speed sensor signals. 14. The controller as in claim 13 , wherein the source other than the wheel speed sensor signals is a vehicle velocity as determined by one of an engine controller, a radar controller and the anti-lock brake controller. 15. The controller as in claim 7 , wherein the brake control signal transmitted to the brake control device at the specific wheel location associated with wheel speed sensor signal having the long-term fault is different than a brake control signal transmitted to any other brake control device at a specific wheel location without a long-term fault. 16. The controller as in claim 7 , further comprising: an indicator output, wherein the control logic transmits a signal to the indicator output in response to determining a long-term fault exists. 17. The controller as in claim 7 , wherein the long-term time period is between about twenty minutes and about sixty minutes. 18. A controller for monitoring brake operation of a vehicle comprising: control logic, wherein the control logic is in communication with a plurality of wheel speed sensors and a brake demand sensor, the control logic capable of: receiving a brake demand signal from the brake demand sensor; receiving a plurality of wheel speed signals from the plurality of wheel speed sensors; determining a master value based on the plurality of wheel speed si