Method and system for adaptively controlling distance and speed and for stopping a motor vehicle, and a motor vehicle which works with same

The invention claimed is: 1. A method for stopping a motor vehicle that includes a surroundings control unit and a brake control unit, the method comprising: measuring, by the surroundings control unit including one or more surrounding sensors, a separation distance to an obstruction, in particular to a vehicle traveling ahead, determining, by the surroundings control unit, a traveling speed of the motor vehicle, regulating, by the surroundings control unit, the separation distance to the obstruction when the traveling speed exceeds a handover threshold value, and stopping the motor vehicle, by the brake control unit when the traveling speed is less than or equal to the handover threshold value, wherein, as a function of the measured separation distance, the surroundings control unit predefines for the brake control unit a target distance the motor vehicle travels at the end of which the vehicle should be stationary, and wherein the brake control unit adjusts the speed of the motor vehicle as a function of a traveling distance covered by the motor vehicle in order to stop the motor vehicle at the predefined target distance. 2. The method as claimed in claim 1 , wherein the brake control unit, during the stopping process, regulates the deceleration and/or the traveling speed of the vehicle as a function of the traveling distance covered. 3. The method as claimed in claim 2 , wherein the brake control unit is connected to at least one wheel rotational speed sensor, and in that, as a measure of the traveling distance covered, pulse-like signals from the at least one wheel rotational speed sensor are counted. 4. The method as claimed in claim 2 , wherein the relationship between deceleration and/or traveling speed and the traveling distance covered is regulated on the basis of a predefined mathematical function, in particular a third-order to eighth-order polynomial. 5. The method as claimed in claim 4 , wherein the predefined mathematical function is selected as a function of the traveling speed and a predefined target distance at the time of the handover from the first control unit to the second control unit. 6. The method as claimed in claim 4 , wherein the predefined mathematical function is selected such that the relationship 2v 2 +3xa≧0 between traveling speed v and traveling distance covered x is satisfied, wherein a represents the deceleration, that is to say the change in the vehicle speed with respect to time. 7. The method as claimed in claim 1 , wherein during the stopping of the motor vehicle by means of the brake control unit, a measurement of the separation distance to the obstruction is performed by the surroundings control unit, in particular at predefined time intervals, wherein the predefined target distance is adapted as a function of the measured separation distance. 8. The method as claimed in claim 7 , wherein the stopping process is terminated if a restart of the vehicle traveling ahead is identified, in particular if the separation distance has increased by more than a predefined minimum separation distance in a time interval, and in that, in this case, separation-distance regulation is performed by the surroundings control unit. 9. The method as claimed in claim 1 , wherein the motor vehicle has a hydraulic service brake system and an electrically actuable parking brake system, and in that a handover from the service brake system to the parking brake system is performed if predefined conditions are met, in particular if a predefined stoppage duration is exceeded. 10. An electronic control unit of a brake system for a motor vehicle, comprising: an interface to a vehicle data bus, an interface to at least one wheel rotational speed sensor, and means for driver-independent activation of at least one brake actuator, including: one or more surrounding sensors, for measuring a separation distance to an obstruction, in particular to a vehicle traveling ahead, a stopping distance regulator which, when the traveling speed is less than or equal to a handover threshold value, adjusts the deceleration and/or the speed of the motor vehicle as a function of the traveling distance covered by the motor vehicle in order to stop the motor vehicle at a predefined target distance the motor vehicle travels at the end of which the motor vehicle should be stationary. 11. The electronic control unit as claimed in claim 10 , wherein the stopping distance regulator comprises a pilot controller and a main regulator, wherein at least one parameter of the stopping distance regulator is predefined as a function of the present speed of the vehicle and the predefined target distance. 12. The electronic control unit as claimed in claim 10 , wherein the at least one parameter is predefined on the basis of a predefined mathematical function that describes the target relationship between deceleration and/or vehicle speed and the traveling distance covered. 13. A motor vehicle, comprising an electronic brake control unit as claimed in claim 10 , further comprising a hydraulic and/or electromechanical brake system which is connected to the brake control unit and which permits a build-up of braking force independently of a driver, and comprising an electronic surroundings control unit which is equipped with at least one forward-facing surroundings sensor, wherein the brake control unit and the surroundings control unit are connected to one another via a vehicle data bus and carry out a method for stopping a motor vehicle which has an electronic surroundings control unit for evaluating the data from one or more surroundings sensors and which has an electronic brake control unit for activating a brake system, which electronics surroundings control unit and electronic brake control unit exchange information and/or commands via a data connection, in particular a vehicle data bus. 14. The motor vehicle as claimed in claim 13 , wherein the brake control unit is connected to at least one rotation-direction-detecting wheel rotational speed sensor which is assigned in particular to a non-driven wheel. 15. The motor vehicle as claimed in claim 14 , further comprising an electronic parking control unit which is equipped in each case with at least one forward-facing and at least one rearward-facing surroundings sensor, wherein the parking control unit is connected to the brake control unit and preferably to the surroundings control unit via a vehicle data bus, and wherein the parking control unit and/or the surroundings control unit can predefine for the brake control unit a target distance for the stopping of the vehicle.