Abstract: The power train (1) includes a controlled drive source (3), a clutch (6), an automatically shifting transmission (7) and a data transmission device (2). The power train contains an additional drive source (12) and is fitted with a control system by means of which a correction value (K pid) for the drive source torque is generated on the basis of the comparison of the actual behavior of the drive train with a modeled behavior of a drive train fitted with a hydrodynamic torque converter. The behavior of a torque converter is simulated by a regulating circuit (21-27).

Abstract: A data storage system for a motor vehicle has at least two control units (1) for controlling one or several vehicle components each, at least two memories (2) for storing data that characterize the route to be traveled on in future, and an interface (3) to a data source (4). Every control unit (1) inquires with the data source (4) a subset of the route data contained therein via the interface (3) and stores the route data transmitted in response in the memory (2) associated with the respective control unit (1).

Abstract: The power train (1) includes a controlled drive source (3), a clutch (6), an automatically shifting transmission (7) and a data transmission device (2). The power train contains an additional drive source (12) and is fitted with a control system by means of which a correction value (K pid) for the drive source torque is generated on the basis of the comparison of the actual behavior of the drive train with a modeled behavior of a drive train fitted with a hydrodynamic torque converter. The behavior of a torque converter is simulated by a regulating circuit (21–27).

Abstract: The power train (1) includes a controlled drive source (3), a clutch (6), an automatically shifting transmission (7) and a data transmission device (2). The power train contains an additional drive source (12) and is fitted with a control system by means of which a correction value (K pid) for the drive source torque is generated on the basis of the comparison of the actual behavior of the drive train with a modeled behavior of a drive train fitted with a hydrodynamic torque converter. The behavior of a torque converter is simulated by a regulating circuit (21-27).

Abstract: A torque set value is determined in a pedal interpretation unit (20) from a parameter which characterizes the drivers command. Operating parameters for the vehicle are evaluated and classified in a driver and situation recognition unit (21). A set operating status for the drivetrain is fixed in a status manager (22), depending upon the torque set value and the output signals from the driver and situation recognition unit. Control signals for remote control units (2, 5, 8) for the drive units and for the gearbox (7) are then generated in a torque manager (23), dependent upon the torque set value and the set operating status.

Abstract: A control unit (14) for regulating the transmission ratio of a transmission (8) which is located in a drive train together with a motor (1), in order to obtain braking assistance through the braking torque of the motor (1) is disclosed. The control unit comprises several signal inputs for receiving the desired braking torque (MSET) and the number of revolutions (nACT) of the motor (1) and/or the vehicle speed; a calculation unit for determining the suitable transmission ratio (ü) of the transmission (8) for achieving the desired braking torque in accordance with the desired braking torque (MSET) and the number of revolutions (nACT) or the vehicle speed; and a signal output for outputting a control signal (ü) which determines the transmission ratio of the transmission (8). An electrical generator (5) which feeds a battery (6) and which has an additional braking torque is located in the drive train.

Abstract: The power train (1) includes a controlled drive source (3), a clutch (6), an automatically shifting transmission (7) and a data transmission device (2). The power train contains an additional drive source (12) and is fitted with a control system by means of which a correction value (K pid) for the drive source torque is generated on the basis of the comparison of the actual behavior of the drive train with a modeled behavior of a drive train fitted with a hydrodynamic torque converter. The behavior of a torque converter is simulated by a regulating circuit (21-27).

Abstract: A method and device for starting an internal combustion engine in a manner which reduces the emissions occurring during starting. The method and device involving setting the throttle valve in an intake duct, accelerating the engine via a crank shaft starter alternator to a desired rotational speed, determining the suction-pipe pressure in the intake duct downstream of the throttle valve, and enabling fuel injection when the suction-pipe pressure undershoots a predetermined threshold value.

Abstract: A data storage system for a motor vehicle comprises at least two control units (1) for controlling one or several vehicle components each, at least two memories (2) for storing data that characterize the route to be traveled on in future, and an interface (3) to a data source (4). Every control unit (1) inquires with the data source (4) a subset of the route data contained therein via the interface (3) and stores the route data transmitted in response in the memory (2) associated with the respective control unit (1).

Abstract: A torque set value is determined in a pedal interpretation unit (20) from a parameter which characterises the drivers command. Operating parameters for the vehicle are evaluated and classified in a driver and situation recognition unit (21). A set operating status for the drivetrain is fixed in a status manager (22), depending upon the torque set value and the output signals from the driver and situation recognition unit. Control signals for remote control units (2, 5, 8) for the drive units and for the gearbox (7) are then generated in a torque manager (23), dependent upon the torque set value and the set operating status.

Abstract: An operating strategy for the components of the drive train is defined as a function of data which characterizes a route to be traveled along. Depending on the operating strategy and the route data, expected energy consumption and a time period for which the energy can be made available are calculated. If the time period is detected as being sufficient, the drive train is controlled in accordance with the operating strategy. If the calculated time period is detected as not being sufficient, an alternative operating strategy is defined and the resulting time period is checked again.

Abstract: The invention relates to a method for starting an internal combustion engine and to a corresponding starter device. The aim of the invention is to improve the carburetion in the range of the desired idle speed. To this end, the internal combustion engine is brought to a high speed (>800 rpm) using a crankshaft-starter generator (KSG). The throttle valve is adjusted to a defined value, preferably it is kept closed. Due to the higher air mass flow of the internal combustion engine the suction pressure (MAP) decreases quickly. Fuel injection is only released when the suction pressure (MAP) has fallen below a predetermined threshold value (MAP_SW).

Abstract: A method of determining setpoint values in motor vehicles that have at least two drive assemblies. Torque setpoint values are determined in separate evaluation branches for each of the drive assemblies as a function of a variable that characterizes the driver's requirement and as a function of operating variables of the motor vehicle. The specific strengths and weaknesses of the respective drive assembly are taken into account directly in the respective evaluation branch.

Abstract: A control unit (14) for regulating the transmission ratio of a transmission (8) which is located in a drive train together with a motor (1), in order to obtain braking assistance through the braking torque of the motor (1) is disclosed. The control unit comprises several signal inputs for receiving the desired braking torque (MSET) and the number of revolutions (NACT) of the motor (1) and/or the vehicle speed; a calculation unit for determining the suitable transmission ratio (ü) of the transmission (8) for achieving the desired braking torque in accordance with the desired braking torque (MSET) and the number of revolutions (NACT) or the vehicle speed; and a signal output for outputting a control signal (ü) which determines the transmission ratio of the transmission (8). An electrical generator (5) which feeds a battery (6) and which has an additional braking torque is located in the drive train.

Abstract: A method for driving a drive assembly in a drive system having an automatic transmission and an automatic clutch optionally coupling the drive assembly to the automatic transmission in order to transmit torque includes the following steps. Sensing whether a procedure, in particular a gearshift operation, is to be conducted. After the procedure has been sensed, predefining, for at least one time segment of the procedure which is to be carried out a prediction profile for an operational variable that characterizes the operating state of the drive assembly. And, driving the drive assembly based on the predefined prediction profile of the operational variable to minimize a deviation between the operational variable and the prediction profile.

Abstract: In a drive train having an engine which is controlled by an engine controller and a transmission which is controlled by a transmission controller, an intervention signal is transferred to the engine controller from the transmission controller via a data link. The intervention signal has values by means of which operating states of the drive train are specified during the driving mode of the motor vehicle and during the gear shift operations of the transmission.

Abstract: An operating strategy for the components of the drive train is defined as a function of data which characterizes a route to be traveled along. Depending on the operating strategy and the route data, expected energy consumption and a time period for which the energy can be made available are calculated. If the time period is detected as being sufficient, the drive train is controlled in accordance with the operating strategy. If the calculated time period is detected as not being sufficient, an alternative operating strategy is defined and the resulting time period is checked again.

Abstract: In a drive train (1) having an engine (18) which is controlled by an engine controller (2) and a transmission (26) which is controlled by a transmission controller (3), an intervention signal (ES) is transferred to the engine controller from the transmission controller via a data link (4). The intervention signal has values by means of which operating states (phases 0-IV) of the drive train (1) are specified during the driving mode of the motor vehicle and during the gear shift operations of the transmission (26).

Abstract: A method for driving a drive assembly in a drive system having an automatic transmission and an automatic clutch optionally coupling the drive assembly to the automatic transmission in order to transmit torque includes the following steps. Sensing whether a procedure, in particular a gearshift operation, is to be conducted. After the procedure has been sensed, predefining, for at least one time segment of the procedure which is to be carried out a prediction profile for an operational variable that characterizes the operating state of the drive assembly. And, driving the drive assembly based on the predefined prediction profile of the operational variable to minimize a deviation between the operational variable and the prediction profile.

Abstract: A method of determining setpoint values in motor vehicles that have at least two drive assemblies. Torque setpoint values are determined in separate evaluation branches for each of the drive assemblies as a function of a variable that characterizes the driver's requirement and as a function of operating variables of the motor vehicle. The specific strengths and weaknesses of the respective drive assembly are taken into account directly in the respective evaluation branch.