초록 ▼

A control system ( 18 ) for an automotive vehicle ( 10 ) having a vehicle body includes a sensor system ( 16 ) having housing ( 52 ) oriented within the vehicle body. Positioned within the housing ( 52 ) are a roll angular rate sensor ( 31 ), a yaw angular rate sensor ( 30 ), a pitch angular rate se

A control system ( 18 ) for an automotive vehicle ( 10 ) having a vehicle body includes a sensor system ( 16 ) having housing ( 52 ) oriented within the vehicle body. Positioned within the housing ( 52 ) are a roll angular rate sensor ( 31 ), a yaw angular rate sensor ( 30 ), a pitch angular rate sensor ( 32 ), a lateral acceleration sensor ( 27 ), a longitudinal acceleration sensor ( 28 ), and a vertical acceleration sensor ( 29 ). The vehicle ( 10 ) also has a safety system ( 38 ). The controller ( 26 ) determines a roll misalignment angle, a pitch misalignment angle and a yaw misalignment angle as a function of the sensor outputs of the roll rate, the pitch rate, the yaw rate, the lateral acceleration, the longitudinal acceleration and the vertical acceleration. The motion variables the vehicle along the vehicle body-fixed frames, including the roll rate, the pitch rate, the yaw rate, the lateral acceleration, the longitudinal acceleration and the vertical acceleration, are then compensated based on the detected sensor misalignments and the sensor outputs of the roll rate, the pitch rate, the yaw rate, the lateral acceleration, the longitudinal acceleration and the vertical acceleration. The controller ( 26 ) generates a control signal for controlling the safety system in response to the compensated roll rate, pitch rate, yaw rate, lateral acceleration, longitudinal acceleration and vertical acceleration.

대표청구항 ▼

1. A method for controlling a vehicle dynamics control system comprising:determining a roll misalignment angle;determining a pitch misalignment angle;determining a yaw misalignment angle; andactivating a safety system as a function of said roll misalignment angle, the pitch misalignment angle and th

1. A method for controlling a vehicle dynamics control system comprising:determining a roll misalignment angle;determining a pitch misalignment angle;determining a yaw misalignment angle; andactivating a safety system as a function of said roll misalignment angle, the pitch misalignment angle and the yaw misalignment angle. 2. A method as recited in claim 1 further comprising measuring a roll rate, measuring a yaw rate, measuring a pitch rate, and generating a corrected roll rate, a corrected yaw rate and a corrected pitch rate as a function of said roll misalignment angle, the pitch misalignment angle and the yaw misalignment angle. 3. A method as recited in claim 1 further comprising measuring a lateral acceleration, a longitudinal acceleration, and a vertical acceleration, and generating a corrected lateral acceleration, a corrected longitudinal acceleration and a corrected vertical acceleration as a function of said roll misalignment angle, the pitch misalignment angle and the yaw misalignment angle. 4. A method as recited in claim 1 further comprising determining a global roll angle as a function of the roll misalignment angle. 5. A method as recited in claim 1 further comprising determining a global pitch angle as a function of the pitch misalignment angle. 6. A method as recited in claim 1 further comprising determining a global yaw angle as a function of the yaw misalignment angle. 7. A method as recited in claim 1 wherein determining a roll misalignment angle comprises determining a roll misalignment angle as a function of a yaw rate from a yaw rate sensor, a pitch rate from a pitch rate sensor, and at least one of an acceleration from an acceleration sensor, a pitch angle or a roll angle. 8. A method as recited in claim 1 wherein determining a pitch misalignment angle comprises determining a pitch misalignment angle as a function of a yaw rate from a yaw rate sensor, a roll rate from a roll rate sensor and at least one of a lateral acceleration from a lateral acceleration sensor, a roll angle or a pitch angle. 9. A method as recited in claim 1 wherein determining a yaw misalignment angle comprises determining a yaw misalignment angle as a function of a yaw rate from a yaw rate sensor, a lateral acceleration from a lateral acceleration sensor, and a longitudinal acceleration from a longitudinal acceleration sensor. 10. A method as recited in claim 1 wherein determining a roll misalignment angle comprises measuring a yaw rate from a yaw rate sensor, a vertical acceleration from a vertical acceleration sensor, a pitch rate from a pitch rate sensor and a vehicle speed from a vehicle speed sensor in accordance with the equationand low-pass filtering Δθ x . 11. A method as recited in claim 1 wherein determining roll misalignment angle comprises measuring a yaw rate from a yaw rate sensor, measuring a pitch rate from a pitch rate sensor, calculating a roll angle and calculating a pitch angle in accordance with the followingand low-pass filtering Δθ x . 12. A method as recited in claim 1 wherein determining a pitch misalignment angle comprises measuring a yaw rate from a yaw rate sensor, measuring a roll rate from a roll rate sensor, measuring vehicle speed from a vehicle speed sensor, measuring a lateral acceleration from a lateral acceleration sensor, and calculating a roll angle in accordance with the followingand low-pass filtering Δθ y . 13. A method as recited in claim 1 wherein determining a pitch misalignment angle comprises measuring a yaw rate from a yaw rate sensor, measuring a roll rate from a roll rate sensor, and calculating a roll angle and calculating a pitch angle, in accordance with the followingand low-pass filtering Δθ y . 14. A method as recited in claim 1 wherein determining a yaw misalignment angle comprises measuring a yaw rate from a yaw rate sensor, measuring a lateral acceleration from a lateral acceleration sensor, measuring a longitudinal accel eration from a longitudinal acceleration sensor, and calculating a roll angle, in accordance with the followingand low-pass filtering Δθ z . 15. A method for controlling a vehicle dynamics control system comprising:determining a roll misalignment angle;determining a global roll angle as a function of the roll angle misalignment;determining a pitch misalignment angle;determining a global pitch angle as a function of the pitch angle misalignment;determining a yaw misalignment angle;determining a global yaw angle as a function of the yaw angle misalignment; andactivating a safety system in response to said global roll angle, said global pitch angle, and said global yaw angle. 16. A control system for an automotive vehicle having a vehicle body comprising:a sensor system having a housing oriented within the vehicle body;a roll angular rate sensor positioned within the housing generating a roll angular rate signal corresponding to roll angular motion of the sensor housing;a yaw angular rate sensor positioned within the housing generating a yaw rate signal corresponding to a yaw motion of the sensor housing;a pitch angular rate sensor positioned within the housing generating a pitch rate signal corresponding to a pitch motion of the sensor housing;a lateral acceleration sensor positioned within the housing generating a lateral acceleration signal corresponding to a lateral acceleration of the sensor housing;a longitudinal acceleration sensor positioned within the housing generating a longitudinal acceleration signal corresponding to the longitudinal acceleration of the sensor housing;a vertical acceleration sensor positioned within the housing generating a vertical acceleration signal corresponding to the vertical acceleration of the sensor housing;a wheel speed sensor generating a wheel speed signal corresponding to a wheel speed of the vehicle;a safety system; anda controller coupled to said roll angular rate sensor, said yaw angular rate sensor, said pitch angular rate sensor, said lateral acceleration sensor, said longitudinal acceleration sensor, said vertical acceleration sensor and said wheel speed sensor, said controller determining a roll misalignment angle; determining a pitch misalignment angle; determining a yaw misalignment angle as a function of said roll rate, said pitch rate, said yaw rate, said lateral acceleration, said longitudinal acceleration and said vertical acceleration, said controller generating a control signal for controlling said safety system in response to said roll misalignment angle, said pitch misalignment angle and said yaw misalignment angle. 17. A system as recited in claim 16 wherein said controller generates a corrected roll rate signal, a corrected yaw rate signal and a corrected pitch rate signal as a function of said roll misalignment angle, the pitch misalignment angle and the yaw misalignment angle, said controller generating said control signal as a function of the corrected roll rate signal, the corrected yaw rate signal and a corrected pitch rate signal. 18. A system as recited in claim 16 wherein said controller generates a corrected lateral acceleration, a corrected longitudinal acceleration and a corrected vertical acceleration as a function of said roll misalignment angle, the pitch misalignment angle and the yaw misalignment angle, said controller generating said control signal as a function of the corrected lateral acceleration, the corrected longitudinal acceleration and the corrected vertical acceleration.