Method for ascertaining the position of the center of gravity of a vehicle

The invention claimed is: 1. A method in which a position of a center of gravity of a moving motor vehicle is ascertained, the method comprising: determining, by a motor vehicle processor, at least one set of input variables received from vehicle sensors during one of a plurality of different types of steady-state driving maneuvers including a steady-state left-hand corner maneuver, a steady-state right-hand corner maneuver and a steady-state straight-ahead driving maneuver, the at least one set of input variables comprising at least a longitudinal acceleration of the motor vehicle, a lateral acceleration of the motor vehicle, a yaw rate of the motor vehicle, and at least one wheel rotational speed; selecting, by the motor vehicle processor, a selected one of a plurality of classifiers based on a corresponding one of the plurality of different types of steady-state driving maneuvers, the selecting including: a) selecting a steady-state left-hand corner classifier when the set of input variables correspond to a steady-state left-hand corner maneuver, the steady-state left-hand corner classifier providing a first probability distribution for center of gravity positions during the steady-state left-hand corner maneuver, the steady-state left-hand corner classifier indicating an estimated center of gravity position of the motor vehicle based on the at least one set of input variables and the first probability distribution, b) selecting a steady-state right-hand corner classifier when the set of input variables correspond to a steady-state right-hand corner maneuver, the steady-state right-hand corner classifier providing a second probability distribution for center of gravity positions during the steady-state right-hand corner maneuver, the steady-state right-hand corner classifier indicating an estimated center of gravity position of the motor vehicle based on the at least one set of input variables and the second probability distribution, and c) selecting a steady-state straight-ahead driving classifier when the set of input variables correspond to a steady-state straight-ahead driving maneuver, the steady-state straight-ahead driving classifier providing a third probability distribution for center of gravity positions during the straight-ahead driving maneuver, the steady-state straight-ahead driving classifier indicating an estimated center of gravity position of the motor vehicle based on the at least one set of input variables and the third probability distribution; calculating, by the motor vehicle processor, a plurality of estimated center of gravity positions based on the at least one set of input variables and based on the selected one of the plurality of classifiers; and controlling, by the motor vehicle processor, an operation of at least one of a braking system or a steering system of the motor vehicle based on the plurality of estimated center of gravity positions. 2. The method as claimed in claim 1 , wherein a non-linear assignment between sets of input variables and the plurality of center of gravity positions is learned using simulation data of a model of the motor vehicle. 3. The method as claimed in claim 1 , wherein the at least one set of input variables comprises a steering angle and/or the at least one set of input variables comprises an estimated value of a total mass of the motor vehicle and/or the at least one set of input variables comprises a measured or estimated roll angle. 4. The method as claimed in claim 1 , wherein a steady-state driving maneuver is identified if a vehicle speed and also the lateral acceleration and/or the yaw rate and/or the steering angle are constant over a predefined period of time, wherein: the vehicle speed is regarded as constant if a variance of the vehicle speed lies below a first threshold value, the lateral acceleration is regarded as constant if a variance of the lateral acceleration lies below a second threshold value, the yaw rate is regarded as constant if a variance of the yaw rate lies below a fourth threshold value, and the steering angle is regarded as constant if a variance of the steering angle lies below a third threshold value. 5. The method as claimed in claim 1 , wherein, by a classification method, at least two intermediate results are ascertained on the basis of different sets of input variables, and the estimated center of gravity position is calculated on the basis of the at least two intermediate results. 6. The method as claimed in claim 1 , wherein at least two sets of input variables are taken into consideration to determine each estimated center of gravity position of the plurality of estimated center of gravity positions, wherein a first set of input variables is ascertained during a first steady-state driving maneuver and a second set of input variables is ascertained during a second steady-state driving maneuver, and the first steady-state driving maneuver differs in type from the second steady-state driving maneuver. 7. The method as claimed in claim 1 , wherein, by a classification method, at least one probability distribution of the plurality of estimated center of gravity positions is determined, which assigns a probability value to each of the plurality of estimated center of gravity positions. 8. The method as claimed in claim 1 , wherein, in order to calculate each estimated center of gravity position of the plurality of estimated center of gravity positions, firstly a lateral coordinate and a longitudinal coordinate of the respective estimated center of gravity position are determined, and subsequently a vertical coordinate of the respective estimated center of gravity position is determined on the basis of the lateral and longitudinal coordinates. 9. The method as claimed in claim 1 , wherein a set of input variables comprising the roll angle is taken into consideration for determining a vertical coordinate of each estimated center of gravity position of the plurality of estimated center of gravity positions. 10. An electronic control unit, for a motor vehicle, comprising: a vehicle processor configured to: determine at least one set of input variables received from vehicle sensors during one of a plurality of different types of steady-state driving maneuvers including a steady-state left-hand corner maneuver, a steady-state right-hand corner maneuver and a steady-state straight-ahead driving maneuver, the at least one set of input variables comprising at least a longitudinal acceleration of the motor vehicle, a lateral acceleration of the motor vehicle, a yaw rate of the motor vehicle, and at least one wheel rotational speed; select a selected one of a plurality of classifiers based on a corresponding one of the plurality of different types of steady-state driving maneuvers, the selecting including: a) selecting a steady-state left-hand corner classifier when the set of input variables correspond to a steady-state left-hand corner maneuver, the steady-state left-hand corner classifier providing a first probability distribution for center of gravity positions during the steady-state left-hand corner maneuver, the steady-state left-hand corner classifier indicating an estimated center of gravity position of the motor vehicle based on the at least one set of input variables and the first probability distribution, b) selecting a steady-state right-hand corner classifier when the set of input variables correspond to a steady-state right-hand corner maneuver, the steady-state right-hand corner classifier providing a second probability distribution for center of gravity positions during the steady-state right-hand corner maneuver, the steady-state right-hand corner classifier indicating an estimated center of gravity position of the