Apparatus and method for determining load weight

We claim: 1. A controller for determining a load weight associated with a plurality of pneumatically independent circuits of a vehicle suspension system, the controller adapted to: identify each of the respective pneumatically independent circuits, in turn, as a currently selected one of the pneumatically independent circuits; measure a respective pneumatic pressure of the currently selected one of the pneumatically independent circuits; determine a calculated pneumatic pressure based on the respective measured pneumatic pressures of the pneumatically independent circuits; determine the load weight based on the calculated pneumatic pressure; and control an operation of a function of an associated vehicle based on the load weight. 2. The controller for determining a load weight as set forth in claim 1 , the controller further adapted to: determine the calculated pneumatic pressure as an average of the respective measured pneumatic pressures of the pneumatically independent circuits. 3. The controller for determining a load weight as set forth in claim 1 , the controller further adapted to: determine the calculated pneumatic pressure after measuring the respective pneumatic pressures in each of the pneumatically independent circuits. 4. The controller for determining a load weight as set forth in claim 1 , wherein: the function is at least one of a roll stability function, an antilock braking function, a lift axle function, a load imbalance reporting function and a load distribution reporting function. 5. The controller for determining a load weight as set forth in claim 4 , wherein the function is a roll stability function, the controller further adapted to: control the operation of the roll stability function by setting a threshold of a parameter, based on the load weight, at which an automated braking associated with the roll stability function occurs. 6. The controller for determining a load weight as set forth in claim 5 , the controller further adapted to: decrease the threshold of the parameter at which the automated braking occurs as the load weight increases. 7. The controller for determining a load weight as set forth in claim 6 , wherein: the parameter is a lateral acceleration of the associated vehicle. 8. The controller for determining a load weight as set forth in claim 6 , the controller further adapted to: linearly decrease the threshold of the parameter at which the automated braking occurs as the load weight increases. 9. The controller for determining a load weight as set forth in claim 8 , the controller further adapted to: linearly decrease the threshold of the parameter at which the automated braking occurs from about 4.0 m/s 2 at a load weight of about 20% of a maximum rated load weight of the associated vehicle to about 2.5 m/s 2 at a load weight of about 80% of a maximum rated load weight of the associated vehicle. 10. The controller for determining a load weight as set forth in claim 1 , the controller further adapted to: independently control each of the plurality of respective valves, in turn, to fluidly communicate the currently selected one of the pneumatically independent circuits with a pressure sensor while the other pneumatically independent circuits are fluidly isolated from the pressure sensor, the pressure sensor measuring the respective pneumatic pressure of the currently selected one of the pneumatically independent circuits. 11. A vehicle system, comprising: a plurality of pneumatically independent circuits of an associated suspension system; an automated braking system including a plurality of respective automatically controlled brakes; and a controller for controlling the operation of the automated braking system, the controller adapted to: identify each of the respective pneumatically independent circuits as a currently selected one of the pneumatically independent circuits; measure a respective pneumatic pressure of the currently selected one of the pneumatically independent circuits; determine a calculated pneumatic pressure based on the respective measured pneumatic pressures of the pneumatically independent circuits; determine the load weight based on the calculated pneumatic pressure; and control an operation of a function of an associated vehicle based on the load weight. 12. The system as set forth in claim 11 , the controller further adapted to: cyclically identify each of the respective pneumatically independent circuits as the currently selected one before repeating the cycle. 13. The system as set forth in claim 12 , the controller further adapted to: determine the calculated pneumatic pressure after each of the cycles. 14. The system as set forth in claim 12 , the controller further adapted to: determine the load weight as an average of the respective calculated pneumatic pressures identified during a single cycle. 15. The system as set forth in claim 11 , the controller further adapted to: control the operation of the automated braking system by setting a threshold of a lateral acceleration of a roll stability function, based on the load weight, at which the automated braking system engages. 16. A method for controlling an operation of a function of an associated vehicle, the method comprising: identifying each of a plurality of respective pneumatically independent circuits, in turn, as a currently selected one of the pneumatically independent circuits; measuring a respective pneumatic pressure of the currently selected one of the pneumatically independent circuits; determining a calculated pneumatic pressure based on the respective measured pneumatic pressures of the pneumatically independent circuits; determining the load weight based on the calculated pneumatic pressure; and controlling an operation of a function of an associated vehicle based on the load weight. 17. The method for controlling an operation of a function of an associated vehicle as set forth in claim 16 , wherein the determining step includes: determining the calculated pneumatic pressure as an average of the respective measured pneumatic pressures of the pneumatically independent circuits. 18. The method for controlling an operation of a function of an associated vehicle as set forth in claim 16 , wherein: the controlling step includes: controlling a roll stability function of the associated vehicle based on the load weight; the method further includes: controlling the operation of the roll stability function by setting a threshold of a parameter, based on the load weight, at which an automated braking associated with the roll stability function occurs. 19. The method for controlling an operation of a function of an associated vehicle as set forth in claim 18 , wherein setting a threshold of a parameter includes: setting the threshold of a lateral acceleration of the associated vehicle. 20. The method for controlling an operation of a function of an associated vehicle as set forth in claim 19 , further including: linearly decreasing the threshold of the later acceleration at which the automated braking occurs from about 4.0 m/s 2 at a load weight of about 20% of a maximum rated load weight of the associated vehicle to about 2.5 m/s 2 at a load weight of about 80% of a maximum rated load weight of the associated vehicle.