Abstract:
A device for influencing the propulsion of a vehicle includes a first arrangement for measuring a transverse acceleleration variable describing the transverse acceleration acting upon the vehicle, a second arrangement for determining a variable describing the time behavior of the transverse accelaretion variable, a third arrangement for determining an intervention variable at least as a function of the transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable, and a fourth arrangement for carrying out at least engine interventions for influencing the propulsion as a function of the intervention variable.

Description:
FIELD OF THE INVENTION 
     The present invention relates to a device and a method for influencing the propulsion of a vehicle. 
     BACKGROUND INFORMATION 
     German Published Patent Application No. 1 902 944 concerns a control device for preventing motor vehicles from skidding during cornering. The motor vehicle contains an antilock braking system, measuring elements which measure the driving condition, and final control elements which are controllable via the measuring elements. The measuring elements include gyroscope, wheel sensors, steering sensors, and potentiometers. The measuring elements are connected to a programmed control unit which responds to limiting values of the transverse acceleration of the vehicle. The final control elements for controlling the braking system and a power-controlling element of an internal combustion engine can be tripped via the control unit for directional stability. The directional stability device becomes active already below the maximum permissible transverse acceleration for the intended vehicle design so that the vehicle cannot get into an unstable driving condition. It is believed that there is no provision for making allowance for a variable describing the time behavior of the transverse acceleration. 
     SUMMARY OF THE INVENTION 
     An object of the exemplary embodiment and/or exemplary method of the present invention is to improve existing devices or methods for influencing the propulsion of a vehicle to the effect that the time or dynamic response of the vehicle is also allowed for in the influencing of the propulsion. 
     The exemplary embodiment and/or exemplary method of the present invention is directed to a device and/or a method for influencing the propulsion of a vehicle. The device includes a first apparatus, arrangement or structure which is used to measure a transverse acceleration variable describing the transverse acceleration acting upon the vehicle. According to an exemplary embodiment of the present invention, the device contains a second apparatus, arrangement or structure which is used to determine a variable describing the time behavior of the transverse acceleration variable. Moreover, the device has a third apparatus, arrangement or structure which is used to determine an intervention variable at least as a function of the transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable. Furthermore, the device features a fourth apparatus, arrangement or structure which is used to carry out or perform at least engine interventions for influencing the propulsion, the engine interventions being carried out as a function of the intervention variable. 
     It is advantageous for the intervention variable to describe the throttle-valve angle to be adjusted, or the fuel injection quantity to be injected, or the ignition point to be adjusted. If the vehicle is equipped, for example, with an Otto spark ignition engine, then the throttle-valve angle or the ignition point (ignition angle) may be used as the intervention variable. In the case of a vehicle equipped with a diesel engine, the fuel injection quantity is usable. Ignition interventions permit a quick reduction of the engine torque. 
     The exemplary method according to the present invention can also be used for vehicles which are equipped with an electric motor. In this case, the electric current flowing through the motor is to be regarded as the intervention variable. 
     In addition to the engine interventions, it is also believed that it may be advantageous to carry out or perform interventions in the wheel brakes and/or in the clutch and/or in the transmission for influencing the propulsion of the vehicle. By appropriate interventions in the wheel brakes, the vehicular speed may be reduced. By interventions in the clutch, the drive train is opened for a short time as a result of which the driven wheels, being free from longitudinal forces, are able to transmit the maximum lateral force. As an intervention in the transmission, it is conceivable, for example, to shift up one gear to reduce the drive torque. The influencing of the propulsion torque can give rise to a limiting of, a reduction of or an increase in the propulsion torque. 
     The intervention variable is believed to be advantageously determined in such a manner that the vehicle is stabilized in the transverse direction by the engine intervention. Via the engine intervention and further interventions described above, the vehicle stability is influenced at the limit, thus supporting the driver in critical driving situations. In the propulsion case, the steerability of the vehicle is increased, the vehicle tends to understeer less strongly. In particular, the engine intervention is also intended to prevent the vehicle from tipping over about a vehicle axis oriented in the longitudinal direction of the vehicle. 
     In a first exemplary embodiment, a change variable describing the time-related change of the transverse acceleration variable is determined as the variable describing the time behavior of the transverse acceleration variable. 
     The exemplary device according to the present invention includes an apparatus, arrangement or structure which is used to determine a speed variable describing the vehicular speed. The intervention variable is determined as a function of this speed variable, of the transverse acceleration variable, and of the variable describing the time behavior of the transverse acceleration variable. For this end, the exemplary device according to the present invention advantageously has, in the third apparatus, arrangement or structure, a first determining apparatus, arrangement or structure which is used to determine a first value for the intervention variable as a function of the transverse acceleration variable and of the speed variable, and/or a second determining apparatus, arrangement or structure which is used to determine a second value for the intervention variable as a function of the variable describing the time behavior of the transverse acceleration variable and of the speed variable, and/or a third determining apparatus, arrangement or structure which is used to determine an incremental value for the intervention variable as a function of transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable. The intervention variable is determined as a function of the first or of the second value and/or of the incremental value. 
     The three above described determining apparatus, arrangement or structure are implemented as characteristic maps. That is, predetermined values for the intervention variable or the incremental value, respectively, are read out from the respective characteristic maps as a function of the input variables, namely the speed variable and/or transverse acceleration variable and/or the variable describing the time behavior of the transverse acceleration variable. These predetermined variables can be determined in the preliminary stages, for example, on the basis of road tests or by model calculations. The first value of the intervention variable has the character of a static intervention variable since, being determined on the basis of the transverse acceleration variable, it allows for the static behavior of the vehicle. If the first intervention variable is used to influence the throttle-valve position, then the first value of the intervention variable constitutes a static throttle-valve limitation. In a corresponding manner, the second value of the intervention variable constitutes a dynamic throttle-valve limitation since it goes back to the variable describing the time behavior of the transverse acceleration variable. Both values have a limiting character because they are used as intervention variable in the case where, on the basis of the driver&#39;s command, a throttle-valve angle would have to be adjusted which would result in an unstable vehicle behavior in the present vehicle situation. For this reason, a throttlevalve angle which goes back to the first or second value of the intervention variable is adjusted in lieu of the throttle-valve angle which goes back to the driver&#39;s command. 
     In the case of the influencing of the throttle-valve position, the incremental value has the character of a throttle-valve increase limitation. If, for example, the throttle-valve angle is adjusted according to one of the two values of the intervention variables and the intention is for the throttle-valve angle to be brought near the throttle-valve angle going back to the driver&#39;s command, then the increase in the throttle-valve angle is limited in its increment to produce a smooth increase in the propulsion torque. The incremental value has the same function also in the case in which the throttle-valve position is adjusted according to one of the two values of the intervention variables and the values of the intervention variables increase because of the vehicle behavior. 
     The use of characteristic maps has the advantage that the intervention variable is continuously determined as a function of the transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable. 
     The first value of the intervention variable advantageously depends on the transverse acceleration variable in such a way that this second value decreases as the value of the transverse acceleration variable increases and/or the first value of the intervention variable depends on the speed variable in such a way that this first value decreases as the value of the speed variable increases. The second value of the intervention variable advantageously depends on the variable describing the time behavior of the transverse acceleration variable in such a way that this second value decreases as the value of the variable describing the time behavior of the transverse acceleration variable increases and/or the second value of the intervention variable depends on the speed variable in such a way that this second value decreases as the value of the speed variable increases. The incremental value of the intervention variable advantageously depends on the transverse acceleration variable in such a way that this incremental value decreases as the value of the transverse acceleration variable increases and/or the incremental value of the intervention variable advantageously depends on the variable describing the time behavior of the transverse acceleration variable in such a way that this incremental value decreases as the value of the variable describing the time behavior of the transverse acceleration variable increases. It is particularly advantageous for the incremental value to assume a very small value, in particular the value zero, first of all, above a predefinable value of the transverse acceleration variable and, secondly, above a predefinable value of the variable describing the time behavior of the transverse acceleration variable. 
     It has turned out to be advantageous for the absolute value of the transverse acceleration variable and for the absolute value of the variable describing the time behavior of the transverse acceleration variable to be processed in the above mentioned determining apparatus, arrangement or structure. For this reason, the third apparatus, arrangement or structure have a first absolute-value generating apparatus, arrangement or structure which is used to generate the absolute value of the transverse acceleration variable. This absolute value is fed to the first and to the third determining apparatus, arrangement or structure. Moreover, the third apparatus, arrangement or structure has a second absolute-value generating apparatus, arrangement or structure which is used to generate the absolute value of the variable describing the time behavior of the transverse acceleration variable. This absolute value is fed to the second and to the third determining apparatus, arrangement or structure. 
     The third apparatus, arrangement or structure advantageously has selection apparatus, arrangement or structure which is used to determine a selection variable which has the character of a resulting throttle-valve limitation. The smaller of the two values for the intervention variable is selected as the selection variable. The intervention variable is determined as a function of this selection variable. 
     This procedure ensures that, at all events, the value of the intervention variable which describes or corresponds to the more critical vehicle condition is taken as the basis for the determination of the intervention variable. If, for example, a vehicle condition has a large transverse acceleration and a small time-related change of the transverse acceleration exists, then the first value determined for the intervention variable is smaller than the second value. Consequently, an engine intervention is required because of the transverse acceleration. The equivalent applies to a vehicle condition in which a small transverse acceleration but a large time-related change of the transverse acceleration exist. By this procedure, the intervention variable is believed to be advantageously limited as a function of the transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable to values at which the vehicle behavior is stable. 
     The device includes an apparatus, arrangement or structure which is used to determine at least a driver command variable describing the driver&#39;s command with regard to the propulsion of the vehicle. This driver command variable is allowed for in the determination of the intervention variable. In particular, the driver command variable is used as the maximum value for the intervention variable. The apparatus, arrangement or structure, which is used to determine the driver command variable, may include, for example, a sensor apparatus, arrangement or structure which is allocated to the accelerator and used for detecting the position of the accelerator. 
     The driver command variable is believed to be advantageously allowed for in the determination of the intervention variable in such a way that the engine interventions are carried out as a function of the driver command variable as long as the value of the driver command variable is smaller than the selection variable. It is believed that this measure better ensures that the vehicle is not accelerated beyond the driver&#39;s command. 
     For the determination of the intervention variable, the third apparatus, arrangement or structure have a fourth determining apparatus, arrangement or structure which is used to determine the intervention variable as a function of the selection variable and/or of the incremental value and/or of the driver command variable. 
     At least the selection variable is determined for consecutive time steps, i.e., it is available in a value-discrete form for discrete time steps. Against the background, the following cases are to be distinguished for the determination of the intervention variable: 
     if the driver command variable is smaller than the selection variable of the current time step, then the driver command variable is used as the intervention variable and/or 
     if the driver command variable is greater than the prevailing selection variable, and if the selection variable of the current time step is smaller than or equal to the selection variable of the previous time step, then the selection variable of the current time step is used as the intervention variable and/or 
     if the driver command variable is greater than the prevailing selection variable, and if the selection variable of the current time step exceeds the selection variable of the previous time step by a predefinable value, in particular by the incremental value, then the intervention variable is derived as the sum of the selection variable of the previous time step and the incremental value and/or 
     if the driver command variable is greater than the prevailing selection variable, and if the selection variable of the current time step exceeds the selection variable of the previous time step but not by a predefinable value, in particular not by the incremental value, then the selection variable of the current time step is used as the intervention variable. 
     As already explained, the time-related increase in the intervention variable is believed to be advantageously limited by an incremental value. 
     Furthermore, it is believed to be advantageous for the intervention variable to be corrected as a function of at least one variable. One approach for this is using, for example, an altitude variable which describes or corresponds to the geographical altitude of the vehicle. This correction takes into account that at greater altitudes, a smaller engine output is available. Applicable is, moreover, a slope variable describing the road gradient in the vehicle&#39;s longitudinal axis. This correction allows for the tractive resistances caused due to the slope. In this connection, moreover, variables can be taken into account as a function of which the intervention variable is corrected to the effect that an equivalent engine torque is adjusted in all operating points of the engine. 
     The advantageous refinement which is the basis of the first exemplary embodiment can be summarized again as follows: the device for influencing the propulsion of the vehicle includes a first apparatus, arrangement or structure which is used into measure a transverse acceleration variable describing the transverse acceleration acting upon the vehicle. Furthermore, the device contains a second apparatus, arrangement or structure which is used to determine a variable describing the time behavior of the transverse acceleration variable. Moreover, the device has a third apparatus, arrangement or structure which is used to determine a first intervention variable as a function of the transverse acceleration variable as well as a fourth apparatus, arrangement or structure which is used to determine a second intervention variable as a function of the variable describing the time behavior of the transverse acceleration variable. In addition, the device includes a fifth apparatus, arrangement or structure which is used to carry out or perform at least engine interventions for influencing the propulsion, the engine interventions being carried out or performed as a function of the first or of the second intervention variable. 
     In a second exemplary embodiment, a period duration variable is determined as the variable describing the time behavior of the transverse acceleration variable, the period duration variable describing the time interval of two zero crossings of the transverse acceleration variable with the same sign reversal, in particular with a sign reversal from positive to negative values of the transverse acceleration variable. 
     It has turned out to be advantageous for the behavior of the vehicle indicating instability or for the previously known behavior of the vehicle to be determined as a function of the amplitude of the transverse acceleration variable and as a function of the period duration of the transverse acceleration variable. This procedure is believed to be particularly suitable for recognizing oscillations in the transverse acceleration variable which may indicate unstable behavior. 
     For the above reasons, the third apparatus, arrangement or structure advantageously have a first apparatus, arrangement or structure which is used to determine an amplitude variable describing the distance between a minimum value and a maximum value of the transverse acceleration variable within one period of the transverse acceleration variable. If, for example, the transverse acceleration variable exhibits an oscillation, then the minimum value of the amplitude corresponds to a negative half wave, and the maximum value of the amplitude corresponds to a positive half wave. It offers itself to make allowance for the maximum values and minimum values since an unstable vehicle condition shows itself in large fluctuations of the transverse acceleration variable. The intervention variable is determined as a function of this amplitude variable. 
     Moreover, the third apparatus, arrangement or structure has a second apparatus, arrangement or structure which is used to determine a weighting variable for the intervention variable as a function of the variable describing the time behavior of the transverse acceleration variable and/or of the amplitude variable. In a third apparatus, arrangement or structure which is included in the third apparatus, arrangement or structure described above, the intervention variable is determined as a function of this weighting variable and of a pre-value for the intervention variable, the pre-value depending at least on the driver&#39;s command. 
     The weighting variable is believed to be advantageously a numerator variable which is incremented, in particular by  1 , if the amplitude variable is greater than a threshold value and if the period duration variable lies within a predefinable range of values. The numerator variable is believed to be advantageously limited to a maximum value. Moreover, the numerator variable is reset to a predefined value, in particular to zero, if the amplitude variable is smaller than the threshold value or if the numerator variable lies outside of the predefinable range of values. 
     Furthermore, it has turned out to be advantageous for the threshold value for the amplitude variable and/or for the range of values for the period duration variable to be predefined as a function of a speed variable describing the vehicular speed. This is useful against the background since the vehicle behavior changes, in terms of instability, to a great extent as a function of the vehicular speed. Thus, an adaptive evaluation is guaranteed. 
     The zero crossing of the transverse acceleration variable is believed to be advantageously determined as a function of the time-related change of the transverse acceleration variable. 
     The advantageous refinement which is the basis of the second exemplary embodiment can be summarized again as follows: the device for influencing the propulsion of the vehicle includes a first apparatus, arrangement or structure which is used to measure a transverse acceleration variable describing the transverse acceleration acting upon the vehicle. Furthermore, the device contains a second apparatus, arrangement or structure which is used to determine an indication variable which indicates whether the transverse acceleration variable exhibits a behavior indicating instability or a previously known behavior of the vehicle, in particular an oscillation. Moreover, the device has a third apparatus, arrangement or structure which is used to carry out or perform at least engine interventions for influencing the propulsion, the engine interventions being carried out or performed at least as a function of the indication variable. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows an arrangement of the exemplary device according to the present invention for carrying out the exemplary method according to the present invention. 
     FIG. 2 shows a block diagram of a first exemplary embodiment. 
     FIG. 3 shows a flow chart of a first exemplary embodiment. 
     FIG. 4 shows a block diagram of a second exemplary embodiment. 
     FIG. 5 shows a flow chart of a second exemplary embodiment. 
     FIG. 6 shows various signal patterns or patterns of variables. 
     FIG. 7 shows other various signal patterns or patterns of variables. 
    
    
     DETAILED DESCRIPTION 
     Block  101  represents a transverse acceleration sensor which is used to measure a transverse acceleration variable aq describing or corresponding to the transverse acceleration acting upon the vehicle. Transverse acceleration variable aq is fed to a block  105 . 
     Block  102  represents an arrangement of different apparatus, arrangement or structure which is used to determine different variables or signals denoted by Si 1 . These include, first of all, a driver command variable DKF describing the driver&#39;s command with regard to the propulsion of the vehicle and, secondly, an altitude variable, a slope variable, or variables as a function of which an intervention variable, as a function of which engine interventions are carried out or performed, is corrected to the effect that an equivalent engine torque is adjusted in all operating points of the engine. These variables or signals Si 1  are fed to block  105 . 
     Block  104  represents wheel-speed sensors which are used to determine wheel-speed variables nij. These wheel-speed variables nij are fed or provided, first of all, to a block  103  and, secondly, to block  105 . 
     At this point, the notation of the wheel-speed variables nij will be explained: index i indicates whether it is a wheel of the front axle (v) or a wheel of the rear axle (h). Index j indicates whether it is a right (r) or left (l) wheel. 
     In block  103 , a speed variable vf describing the vehicular speed is determined in a manner which is known per se. Speed variable vf is fed to block  105 . 
     Block  105  is a controller in which a control (that is, a closed-loop control) is executed, influencing the lateral dynamics of the vehicle. To determine the vehicle situation, transverse acceleration variable aq, wheel-speed variables nij, speed variable vf, variables or signals Si 1 , and, originating from block  106 , variables or signals Si 3  are fed to controller  105 . 
     To influence the lateral dynamics of the vehicle, controller  105  outputs signals or variables Si 2  as well as a further variable DKEG. Both signals or variables Si 2  and variable DKEG are fed to a block  106  which represents the actuator mechanism contained in the vehicle. 
     The actuator mechanism is, first of all, of the kind used for influencing the engine or the engine torque delivered by it. If the vehicle possesses an Otto spark ignition engine, the actuator mechanism has actuators for influencing the throttle-valve position or the throttle-valve angle, or actuators for influencing the ignition point (ignition angle). If the vehicle possesses a diesel engine, then the actuator mechanism has actuators for influencing the supplied fuel quantity. If the vehicle possesses an electric motor as driving motor, the actuator mechanism has actuators for influencing the current flowing through the motor. 
     In the present exemplary embodiments, first of all, the vehicle is assumed to possess an Otto spark ignition engine and, secondly, intervention variable DKEG, as a function of which engine interventions are carried out or performed for influencing the engine torque, is intended to describe the throttle-valve angle. At this point, it should be mentioned that, in the case of a diesel engine, intervention variable DKEG would describe the supplied fuel quantity, and, in the case of an electric motor, intervention variable DKEG would describe the current flowing through the motor. 
     Secondly, the actuator mechanism is of the kind which permits interventions in the clutch and which is used for influencing the power transmission between the engine and the driven wheels, or which permits interventions in the transmission. As an intervention in the transmission, it is conceivable, for example, to shift up one gear to reduce the drive torque. Moreover, interventions in the brakes of the vehicle are also conceivable. The influencing of the drive torque can give rise to a limiting of, a reduction, or an increase in the drive torque. The above described interventions influence the vehicle stability at the limit, thus supporting the driver in critical driving situations. In the propulsion case, the steerability of the vehicle is increased, the vehicle tends less strongly to understeer. 
     Fed to controller  105  are variables or signals Si 3  which originate from actuator mechanism  106  and which indicate the condition of the respective actuators and are allowed for in the closed-loop or open-loop control. 
     In the following, FIG. 2 will be described which shows components  201  of a first exemplary embodiment. These components  201  are used to determine an intervention variable DKEG as a function of which engine interventions are carried out or performed for influencing the propulsion. In the present exemplary embodiment, the engine intervention to be carried out or performed is intended to be a throttle-valve intervention. Therefore, intervention variable DKEG describes or corresponds to the throttle-valve intervention to be carried out or performed. 
     Transverse acceleration variable aq measured with the assistance of transverse acceleration sensor  101  is fed to both a block  202  and to a block  204 . Block  202  represents first absolute-value generating apparatus, arrangement or structure which is used to generate absolute value aqabs of transverse acceleration variable aq. Absolute value aqabs is fed or provided to both the first determining apparatus, arrangement or structure  203  and the third determining apparatus, arrangement or structure  208 . 
     Block  204  represents apparatus, arrangement or structure which is used to determine a variable daq describing the time behavior of transverse acceleration variable aq. In the present exemplary embodiment, variable daq represents a change variable describing the time-related change of the transverse acceleration variable. In the concrete case, this is the gradient or the time derivation of transverse acceleration variable aq which are determined in a known manner. Variable daq describing the time behavior of transverse acceleration variable aq is fed a block  205 . 
     Block  205  represents a second absolute-value generating apparatus, arrangement or structure which is used to generate absolute value daqabs of variable daq. The absolute value daqabs is fed or provided to both the second determining apparatus, arrangement or structure  206  and the third determining apparatus, arrangement or structure  208 . 
     In determining apparatus, arrangement or structure  203 ,  206 , and  208 , the variables output by them are determined as a function of the input variables fed to them, using characteristic maps. 
     Fed to a first determining apparatus, arrangement or structure  203 , in addition to absolute value aqabs of the transverse acceleration variable, is also speed variable vf. Using the first determining apparatus, arrangement or structure  203 , a first value DKEGKFAQ for the intervention variable is determined as a function of absolute value aqabs and of speed variable vf. That is, the first value of the intervention variable is determined as a function of transverse acceleration variable aq and of speed variable vf. In this context, the first value of the intervention variable depends on the transverse acceleration variable in such a way that this second value decreases as the value of the transverse acceleration variable increases. Besides, the first value of the intervention variable depends on the speed variable in such a way that this first value also decreases as the value of the speed variable increases. First value DKEGKFAQ for the intervention variable is fed to a block  207 . 
     Fed to the second determining apparatus, arrangement or structure  206 , in addition to absolute value daqabs of the variable describing the time behavior of the transverse acceleration variable, is also speed variable vf. Using the second determining apparatus, arrangement or structure  206 , a second value DKEGKFDAQ for the intervention variable is determined as a function of absolute value daqabs and of speed variable vf. That is, the second value of the intervention variable is determined as a function of variable daq describing the time behavior of the transverse acceleration variable and of speed variable vf. In this context, the second value of the intervention variable depends on the variable describing the time behavior of the transverse acceleration variable in such a way that this second value decreases as the value of the variable describing the time behavior of the transverse acceleration variable increases. Besides, the second value of the intervention variable depends on the speed variable in such a way that this second value decreases as the value of the speed variable increases. Second value DKEGKFDAQ is fed to a block  207 . 
     Both values DKEGKFAQ and DKEGKFDAQ for the intervention variable are determined as a function of the transverse acceleration variable or of the variable describing the time behavior of the transverse acceleration variable, and of speed variable vf in such a manner that, during the vehicle conditions described by these variables, an instability of the vehicle is reduced by the influencing of the propulsion going back to the intervention variable or that imminent instability does not come about or occur. 
     Block  207  represents selection apparatus, arrangement or structure which is used to determine a selection variable DKEGMIN. The smaller of the two values DKEGKFAQ and DKEGKFDAQ for the intervention variable is selected as the selection variable. Selection variable DKEGMIN is fed to a block  209 . 
     In a third determining apparatus, arrangement or structure  208 , an incremental value DDKEGKF for the intervention variable is determined as a function of absolute value aqabs of the transverse acceleration variable and of absolute value daqabs of the variable describing the time behavior of the transverse acceleration variable. That is, the incremental value is determined as a function of the transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable. In this context, the incremental value of the intervention variable depends on the transverse acceleration variable in such a way that this incremental value decreases as the value of the transverse acceleration variable increases. Besides, the incremental value of the intervention variable depends on the variable describing the time behavior of the transverse acceleration variable in such a way that this incremental value decreases as the variable describing the time behavior of the transverse acceleration variable increases. In particular, the incremental value assumes a very small value, in particular the value zero, first of all, above a predefinable value of the transverse acceleration variable and, secondly, above a predefinable value of the variable describing the time behavior of the transverse acceleration variable. Incremental value DDKEGKF is fed to block  209 . 
     Block  209  represents fourth determining apparatus, arrangement or structure which is used to determine intervention variable DKEG as a function of selection variable DKEGMIN, of incremental value DDKEGKF, and of a driver command variable DKF. Driver command variable DKF describes or corresponds to the driver&#39;s command with regard to the propulsion of the vehicle. To determine the driver command variable, provision is made for the apparatus, arrangement or structure  102 . The apparatus, arrangement or structure  102  include, for example, a sensor apparatus, arrangement or structure which is allocated to the accelerator and which is used for detecting the position of the accelerator. Originating from apparatus, arrangement or structure  102 , driver command variable DKF is fed to block  209 . 
     By using characteristic maps in determining apparatus, arrangement or structure  203 ,  206  and  208 , it is achieved that the intervention variable is continuously determined as a function of the transverse acceleration variable and of the variable describing the time behavior of the transverse acceleration variable. 
     The concrete procedure in determining intervention variable DKEG will be discussed in connection with FIG.  3 . It should be mentioned in advance, however, that driver command variable DKF is virtually used as the maximum value for the intervention variable. That is, as long as the value of driver command variable DKF is smaller than the value of the selection variable DKEGMIN, the engine interventions are carried out or performed as a function of driver command variable DKF. 
     FIG. 3, which shows the sequence of steps which are taken as the basis for the first exemplary embodiment, will be discussed in the following. 
     The exemplary method according to the present invention starts with a step  301  which is followed by a step  302 . At this point, it should be mentioned that selection variable DKEGMIN is determined for consecutive time steps. Consequently, it is available in a time-discrete and value-discrete form. In FIG. 3, the current time step is denoted by (n), and the previous time step is denoted by (n−1). 
     In step  302 , it is checked whether value DKEGMIN(n) of the selection variable of a current time step (n) (the verbal denomination of the time step will be dispensed with hereinafter) is smaller than driver command variable DKF. If, in step  302 , it is established that driver command variable DKF is smaller than value DKEGMIN(n) of the selection variable, then a step  309  is executed subsequent to step  302 , intervention variable DKEG being assigned the value of driver command variable DKF in step  309 . This assignment signifies that the driver&#39;s command is used as the maximum value for the intervention variable, as already explained above. It is believed that this is because in this case, it is to be assumed that no vehicle instability will occur in response to influencing the propulsion as a function of the driver&#39;s command. Subsequent to step  309 , a step  310  is executed. 
     If, however, in step  302 , it is established that driver command variable DKF is greater than value DKEGMIN(n) of the selection variable, then a step  303  is executed subsequent to step  302 . In step  303 , it is checked whether value DKEGMIN(n) of the selection variable is smaller than or equal to value DKEGMIN(n−1) of the selection variable. If this is the case, then a step  304  is executed subsequent to step  303 , intervention variable DKEG being assigned value DKEGMIN(n) in step  304 . Subsequent to step  304 , step  310  is executed. 
     If, however, in step  303 , it is established that value DKEGMIN(n) of the selection variable is greater than value DKEGMIN(n−1) of the selection variable, then a step  305  is executed subsequent to step  303 . In this step  305 , difference DIFF between value DKEGMIN(n) and value DKEGMIN(n−1) is generated. Subsequent to step  305 , step  306  is executed. In step  306 , it is checked whether variable DIFF is greater than or equal to incremental value DDKEGKF(n). If this is the case, then a step  308  is executed subsequent to step  306 . In this step  308 , intervention variable DKEG is assigned the sum from DKEGMIN(n−1) and DKEGMIN(n). Subsequent to step  308 , step  310  is executed. 
     If, however, in step  306 , it is established that difference DIFF is smaller than incremental value DDKEGKF(n), then a step  307  is executed subsequent to step  306 . In this step  307 , intervention variable DKEG is assigned value DKEGMIN(n). Subsequent to step  307 , step  310  is executed. 
     By the operations executed in steps  305 ,  306 ,  307 , and  308 , the following is implemented: if, because of the vehicle situation, a value DKEGMIN(n) for the selection variable is determined which is greater in comparison with value DKEGMIN(n−1) of the previous time step, then.the resulting increase in the intervention variable is limited. The increase limitation is carried out or performed in step  308  on the basis of incremental value DDKEGKF(n). That is, the timerelated increase in the intervention variable is limited by incremental value DDKEGKF. 
     Via the exemplary method shown in FIG. 3, a limitation of the intervention variable is carried out or performed in the case that, due to the driver&#39;s command, larger propulsion would have to be adjusted than is possible on the basis of the vehicle situation in view of stable vehicle behavior. That is, the intervention variable is limited as a function of the transverse acceleration variable and of the variable describing the time characteristic of the transverse acceleration variable to values at which the vehicle behavior is stable. 
     In step  310 , the throttle-valve is actuated according to intervention variable DKEG. Subsequent to step  310 , step  302  is executed again. 
     At this point, reference is made to FIG.  6 . FIG. 6 shows an exemplary pattern of transverse acceleration variable aq and of variable daq. Different interventions or the effects of different interventions can be inferred from FIG.  6 . 
     In the following, FIG. 4, which shows the arrangement taken as the basis for the second exemplary embodiment, is described. 
     In the second exemplary embodiment, a period duration variable aqperz is determined in block  402  as the variable describing the time behavior of the transverse acceleration variable, the period duration variable describing the time interval of two zero crossings of the transverse acceleration variable with the same sign reversal. For this, for example, sign reversals from positive to negative values of the transverse acceleration variable can be considered. The other sign reversal may also be taken into account or considered. To determine period duration variable aqperz, transverse acceleration variable aq is fed to block  402 . Period duration variable aqperz is fed to a block  403 . 
     Block  401  represents an apparatus, arrangement or structure which is used to determine an amplitude variable deltaaq describing the distance between a minimum value and a maximum value of the transverse acceleration variable within one period of the transverse acceleration variable. For this, transverse acceleration variable aq is fed to block  401 . Amplitude variable deltaaq is fed to a block  403 . If the transverse acceleration variable exhibits an oscillation, for example due to the vehicle behavior, then the maximum value represents the amplitude of the positive half wave and the minimum value represents the amplitude of the negative half wave. 
     Block  403  represents an apparatus, arrangement or structure which is used to determine a weighting variable aqresz for the intervention variable as a function of period duration variable aqperz and amplitude variable deltaaq. To determine weighting variable aqresz, moreover, a speed variable vf and transverse acceleration variable.aq are fed to block  403 . Weighting variable aqresz determined in block  403  is fed to a block  405 . 
     The determination of weighting variable aqresz will be discussed in detail in connection with FIG.  5 . At this point, reference is made just to variable Res which, originating from block  403 , is fed to blocks  401  and  402 , and which allows these two blocks to be initialized. 
     Block  405  represents an apparatus, arrangement or structure which is used to determine intervention variable DKEG as a function of weighting variable aqresz and of a pre-value depending at least on the driver&#39;s command. 
     Applicable as pre-value DKEGroh for the intervention variable is either the driver&#39;s command, i.e., driver command variable DKF itself. In this case, block  404  shown in FIG. 4 would not have any significance. Driver command variable DKF would be fed directly to block  405 . Or the value for the intervention variable determined with the assistance of apparatus, arrangement or structure  201  is applicable. In this case, block  404  would correspond to block  201 . 
     FIG. 5 which shows the concrete sequence of steps taken as the basis for the second exemplary embodiment will be described in the following. 
     The exemplary method of the second exemplary embodiment according to the present invention starts with a step  501  which is followed by a step  502 . In this step, both weighting variable aqresz and period duration variable aqperz are initialized. To this end, both variables are assigned the value zero. For this purpose, variable Res, originating from block  403 , is fed to blocks  401  and  402 , as indicated in FIG.  4 . 
     Subsequent to step  502 , a step  503  is executed in which period duration variable aqperz is increased by one (1). In connection with step  505 , which is still to be described, the time interval of two zero crossings of the transverse acceleration variable with the same sign reversal, i.e., in the case of an oscillation, the period duration, is determined by repeatedly executing step  503 . 
     Step  503  is followed by a step  504 . In this step, a maximum value aqmax and a minimum value aqmin of the transverse acceleration variable are determined. Subsequently, step  505  is executed. In this step, it is checked whether a zero crossing from positive to negative values is present for transverse acceleration variable aq. If this is the case, then a step  506  is subsequently executed. If, however, no corresponding zero crossing is present, then a step  512  is executed subsequent to step  505 . 
     The zero crossing of the transverse acceleration variable is determined, for example, as a function of the time-related change of the transverse acceleration variable. 
     In step  506 , it is checked whether amplitude variable deltaaq is greater than a threshold value S 1 . Amplitude variable deltaaq is determined in block  402  and corresponds, for example, to the absolute value of the difference generated from maximum value aqmax and minimum value aqmin. If amplitude variable deltaaq is greater than threshold value S 1 , which indicates that the vehicle performs, for example, a maneuver during which it oscillates in the transverse direction or is unstable, then a step  507  is executed subsequent to step  506 . If amplitude variable deltaaq is smaller than threshold value S 1 , then a step  513  is subsequently executed since in this case, no critical situation exists with regard to the handling properties of the vehicle. 
     In step  507 , it is checked whether period duration variable aqperz is greater than a threshold value S 2  and smaller than a threshold value S 3 , i.e., whether period duration variable aqperz lies within this range of values. If this is the case, then a step  508  is executed subsequent to step  507 . If this is not the case, then step  513  is subsequently executed. In this step  513 , weighting variable aqresz is reset, i.e., it is assigned the value zero, since it has been established, via the interrogations carried out or performed in steps  506  or  507 , that no critical vehicle conditions exist. Subsequent to step  513 , a step  511  is executed. 
     In step  508 , a weighting variable aqresz is increased by one (1) since both the amplitude condition interrogated in step  506  and the period duration condition interrogated in step  507  are fulfilled, which indicates that a critical vehicle condition exists. Subsequent to step  508 , a step  509  is executed. In this step, it is checked whether the weighting variable is greater than a threshold value S 4 . If this is the case, then a step  510  is subsequently executed in which the weighting variable is limited to a value S 4 −1. Subsequent to step  510 , step  511  is executed. If, however, it is established in step  509  that the weighting variable is smaller than threshold value S 4 , wherefore a limitation is not required, then step  511  is directly executed subsequent to step  509 . 
     In step  511 , period duration variable aqperz, minimum value aqmin, and maximum value aqmax are reset, i.e., they are assigned the value zero. Subsequent to step  511 , step  512  is executed. In this step, intervention variable DKEG is determined by weighting a pre-value DKEGroh for the intervention variable as a function of weighting variable aqresz. In this context, the weighting may be carried out or performed, first of all, directly by weighting factor aqresz. Secondly, weighting by a functionality f(aqresz) is also conceivable. In lieu of weighting the intervention variable, it is also conceivable to weight the transverse acceleration variable. 
     Subsequent to step  512 , step  503  is executed again. 
     Both threshold value S 1  for the amplitude variable and threshold values S 2  and S 3  defining the range of values for the period duration variable are predefined as a function of speed variable vf. 
     The steps shown in FIG. 5 are executed in blocks  401 ,  402 ,  403 , and  405 . 
     At this point, reference is made to FIG.  7 . FIG. 7 shows a pattern for transverse acceleration variable aq exhibiting an oscillation. The significance of variables aqmax, aqmin, deltaaq, aqperz, and aqresz can be gathered, by way of example, from FIG.  7 . 
     As already mentioned, the intervention variable can be corrected. In this context, it is conceivable, for example, to carry out or perform a correction as a function of an altitude variable describing the geographical altitude of the vehicle, and/or carry out or perform a correction as a function of slope variable describing the road gradient in the vehicle&#39;s longitudinal axis, and/or carry out or perform a correction as a function of variables as a function of which the intervention variable is corrected to the effect that an equivalent engine torque is adjusted in all operating points of the engine. 
     Depending on the type of engine with which the vehicle is equipped, as already mentioned, the intervention variable describes or corresponds to the throttle-valve angle to be adjusted, or the fuel injection quantity, or the ignition point to be adjusted, or the current flowing through the motor. 
     The influencing of the propulsion as a function of the intervention variable can result in limiting, reducing or increasing the drive torque. 
     In addition to the engine interventions, the interventions may also be carried out or performed in the wheel brakes and/or in the clutch and/or in the transmission for influencing the propulsion of the vehicle. That is, the devices or methods shown in the Figures can be used for all of these intervention variables in a corresponding manner. 
     It is believed that it may be advantageous for the lateral tire forces to be measured and allowed for in the determination of the intervention variable. 
     Usable as the variable describing the time behavior of the transverse acceleration variable is also a variable which describes or corresponds to the frequency of the transverse acceleration variable. 
     In the preceding embodiments, vehicle conditions or driving situations were described in which the vehicle behaves in an unstable manner, and which are intended to be recognized. Some will be listed in the following: slaloming, fishtailing, driving in a circle or cornering at a corresponding vehicular speed, evasive maneuvers, lane-changing maneuvers, VDA swerve section as well as skidding. These vehicle conditions or driving situations can also be detected, for example, via the steering angle, the yaw angle, the speed behavior or on the basis of speed differences.