Acceleration sensing of fast roll and slow roll for vehicle

What is claimed is: 1. A method of operating at least one restraint device in a vehicle during a fast roll event or a slow roll event, the method comprising: sensing a lateral acceleration of the vehicle; sensing a vertical acceleration of the vehicle; sensing an angular rate of the vehicle determined about a longitudinal axis; integrating the lateral acceleration to obtain a roll rate velocity; predicting vehicle rollover from the angular rate and the vertical acceleration; when vehicle rollover is predicted, and when the lateral acceleration is greater than a fast lateral acceleration threshold and the roll rate velocity is greater than a fast roll rate velocity threshold, setting a fast roll event output, when the lateral acceleration is less than the fast lateral acceleration threshold and greater than a slow lateral acceleration threshold, and the roll rate velocity is greater than a slow roll rate velocity threshold, setting a slow roll event output, operating the restraint device of the vehicle in response to one of the fast roll event output and the slow roll event output, and providing a plausibility error when the lateral acceleration and the roll rate velocity do not result in either the fast roll event output or the slow roll event output. 2. The method according to claim 1 , wherein operating the at least one restraint device in response to the fast roll event output includes deploying a side airbag, deploying a side airbag inflatable curtain and operating a seat belt pretensioner. 3. The method according to claim 2 , wherein operating the restraint device in response to the slow roll event includes operating a seat belt pretensioner. 4. The method according to claim 3 , wherein operating the at least one restraint device in response to the slow roll event output is limited to operating the seat belt pretensioner. 5. The method according to claim 3 , wherein the slow roll event generally is a soil-tripped rollover event and the fast roll event generally is a curb-tripped rollover event, and wherein the sensing of the lateral acceleration includes determining the lateral acceleration from the slope of the roll rate velocity. 6. A control system for at least one restraint device in a vehicle, the system comprising: an angular rate sensor for providing an angular rate determined about a longitudinal axis of the vehicle; a vertical acceleration sensor for providing vertical acceleration of the vehicle; a lateral acceleration sensor for providing a lateral acceleration of the vehicle; and an electronic controller including a processor and a memory, the processor configured to: predict vehicle rollover based on the angular rate and the vertical acceleration, integrate the lateral acceleration to determine a roll rate velocity, when vehicle rollover is predicted, and when the lateral acceleration is greater than a fast lateral acceleration threshold and the roll rate velocity is greater than a fast roll rate velocity threshold, provide a fast roll event output, when the lateral acceleration is less than the fast lateral acceleration threshold and greater than a slow lateral acceleration threshold, and the roll rate velocity is greater than a slow roll rate velocity threshold, provide a slow roll event output, operate the at least one restraint device consisting of operating a seat belt pretensioner in response to the slow roll event output without deploying a side airbag or a side airbag inflatable curtain, and determine a plausibility error when the lateral acceleration and the roll rate velocity do not result in either the fast roll event output or the slow roll event output. 7. The control system according to claim 6 , the at least one restraint device including an inflatable side airbag; a side airbag inflatable curtain; a side airbag and inflatable curtain controller; and a seat belt pretensioner, wherein when vehicle rollover is predicted, operating the at least one restraint device in response to the fast roll event output includes deployment of the side airbag and deployment of the side airbag inflatable curtain by the side airbag and inflatable curtain controller, and operating of the seat belt pretensioner. 8. The control system according to claim 6 , wherein the slow roll event output generally corresponds to a soil-tripped rollover event and the fast roll event output generally corresponds to a curb-tripped rollover event. 9. A method of operating at least one restraint device in a vehicle during a fast roll event or a slow roll event, the method comprising: sensing an angular rate determined about a longitudinal axis of the vehicle with an angular rate sensor; sensing a vertical acceleration of the vehicle with a vertical acceleration sensor; sensing a lateral acceleration of the vehicle with a lateral acceleration sensor; integrating the lateral acceleration to obtain a roll rate velocity; predicting vehicle rollover from the angular rate and the vertical acceleration; when the lateral acceleration is greater than a fast lateral acceleration threshold and the roll rate velocity is greater than a fast roll rate velocity threshold, providing a fast roll event output; when the lateral acceleration is less than the fast lateral acceleration threshold and greater than a slow lateral acceleration threshold, and the roll rate velocity is greater than a slow roll rate velocity threshold, providing a slow roll event output; when vehicle rollover is predicted, operating the at least one restraint device in response to either the fast roll event or the slow roll event; and providing a plausibility error when the lateral acceleration and the roll rate velocity do not result in either the fast roll event or the slow roll event, and vehicle rollover is predicted. 10. The method according to claim 9 , wherein operating the at least one restraint device in response to the slow roll event output is limited to operating a seat belt pretensioner. 11. The method according to claim 9 , wherein operating the at least one restraint device in response to the fast roll event output includes operating a seat belt pretensioner, deploying a side airbag and deploying a side airbag inflatable curtain. 12. The method according to claim 9 , wherein the slow roll event generally is a soil-tripped rollover event and the fast roll event generally is a curb-tripped rollover event. 13. The method according to claim 9 , wherein the sensing of the lateral acceleration includes determining the lateral acceleration from a slope of the roll rate velocity.