Abstract: A method and a system for controlling a driving function of a vehicle, whereby in a first operating state, the driving function is controlled by a vehicle guidance system, and in a second operating state, the driving function is controlled by a command of a driver, a transition from the first operating state to the second operating state being accomplished with the aid of an orderly handover through a preset handover procedure when it is recognized that a predetermined first condition is fulfilled, or with the aid of a handover in a fallback solution when it is recognized that a predetermined second condition is fulfilled.

Abstract: A method for monitoring a setpoint trajectory to be traveled by a vehicle for being collision free, including carrying out a clearance measurement of vehicle surroundings with the aid of a surroundings sensor system to determine a clearance in the vehicle surroundings, carrying out an object measurement of the vehicle surroundings with the aid of the surroundings sensor system to determine objects in the vehicle surroundings, checking the setpoint trajectory for being collision free based on the determined clearance and the determined objects, and comparing particular results of the checks for being collision free to one another, an item of collision information being provided based on the comparison.

Abstract: A method for operating a control device of a motor vehicle driving by automation. The method includes determining a location of the motor vehicle, and acquiring driving-environment data of the motor vehicle, a control characteristic of the control device of the motor vehicle being formed in such a way that a driving behavior of at least one other road user is influenced in defined manner.

Abstract: A vehicle is operable in a first operating mode in which the vehicle travels autonomously inside the traffic lane based on a detection of lane markings of a traffic lane and in a second operating mode in which the vehicle autonomously follows a vehicle driving in front while ignoring lane markings, and a method of its operation includes operating the vehicle in a first of the two operating modes, detecting a vehicle environment, and switching from the first operating mode to the other of the two operating modes as a function of the detected vehicle environment. A device can execute the method and a computer program can be executed by a device for performing the method.

Abstract: A method for operating a vehicle includes: ascertaining a danger measure of a possible stop position for a safe parking of the vehicle; comparing the ascertained danger measure to a predetermined danger measure threshold value; and guiding the vehicle to the possible stop position in order to safely park the vehicle in the possible stop position only if the ascertained danger measure is less than or equal to the predetermined danger measure threshold value.

Abstract: An occupancy grid map for a vehicle includes several cells disposed in grid-like fashion. The cells of the occupancy grid map are adapted, as a function of a driving situation of the vehicle, to the driving situation. Areas of the cells are configured to be smaller in a region closer to the vehicle, and are configured to be larger in a region further away from the vehicle.

Abstract: A method for operating a vehicle, the vehicle being guided in fully automated fashion, and if an error is detected during the fully automated guidance, a safe state being selected from a plurality of safe states as a function of one parameter, the vehicle being guided in fully automated fashion into the selected safe state. Also described is an apparatus for operating a vehicle, as well as to a computer program.

Abstract: A method for monitoring a system of a vehicle which provides an at least partially automated driving function, including the following steps: checking setpoint driving state of the vehicle, predefined by the system, for plausibility, controlling the vehicle as a function of the predefined setpoint driving state in order to reach the predefined setpoint driving state when a result of the check is that the predefined setpoint driving state is plausible, or controlling the vehicle as a function of an emergency setpoint driving state in order to reach the emergency setpoint driving state when a result of the check is that the predefined setpoint driving state is implausible. Moreover, a corresponding device, a corresponding monitoring system, and a corresponding computer program are described.

Abstract: A method for creating an obstacle map of an area surrounding a motor vehicle on a road includes preparing a rasterized obstacle map, scanning an area surrounding the motor vehicle, dividing the surrounding into cells, recording those of the cells that are occupied by an obstacle, and identifying grid points of the obstacle map that correspond to occupied cells in the surrounding area. The dimensions of the cells are determined as a function of the position thereof relative to the course of the road.

Abstract: A highly automated driving function for controlling a motor vehicle includes a plurality of function components. A method for controlling the motor vehicle includes steps of executing the driving function using a first function component, comparing the behavior of the first function component to a specified behavior, ascertaining that the behavior of the first function component deviates from the specified behavior, ascertaining a first accident risk if the driving function continues to be executed with the aid of the first function component, ascertaining a second accident risk if the execution of the driving function continues with the aid of a second function component, and executing the driving function with the aid of the particular function component whose allocated accident risk is the lowest.

Abstract: A method for determining the position of a vehicle, including sensing of multiple objects in a surround field of the vehicle, detecting a sequence of the multiple sensed objects in a digital map and determining a position of the vehicle in the digital map based on a position of the detected sequence in the digital map. An apparatus for determining the position of a vehicle, as well as to a computer program are also described.

Abstract: A method for operating a vehicle including at least one assistance function or at least a partially automated driving function, including: ascertaining at least one safe driving state; capturing the current driving state; determining a permissible range for the current driving state of the vehicle from which at least one of the at least one safe driving state is attainable; operating the vehicle using an activable or active assistance function or an at least partially automated driving function within the specified permissible range.

Abstract: A method for a vehicle equipped with a surroundings sensor system for generating an evaluation signal representing the trafficability of at least one route section to be traveled by the vehicle, the evaluation signal being ascertained as a function of surroundings data which are gathered with the aid of the surroundings sensor system, the evaluation signal being further ascertained as a function of at least one piece of surroundings information from an elevation map representing the topology of the at least one route section and/or at least one movement value of the vehicle representing a pitch and/or roll angle.

Abstract: An apparatus for operating a vehicle, including a control device that is configured to guide the vehicle automatically; and a monitoring device that is configured to monitor the control device for a fault during automatic guidance of the vehicle by the control device, and upon recognition of a fault to take over automated guidance of the vehicle from the control device. A corresponding method and a computer program are also described.

Abstract: A method for operating a vehicle having a plurality of environmental sensors for acquiring a surrounding environment of the vehicle, including acquiring a surrounding environment of the vehicle using each of the environmental sensors, ascertaining of object data, corresponding to objects, for each environmental sensor, based on the raw data of the corresponding environmental sensor, fusion of the respective object data of the environmental sensors with one another, so that fused object data are ascertained, fusion of the respective raw data of the environmental sensors with one another, so that fused raw data are ascertained, ascertaining of raw object data, corresponding to objects, based on the fused raw data, comparison with one another of the fused object data and the raw object data, controlling of at least one vehicle system as a function of the comparison. A device for operating a vehicle and a computer program are also described.

Abstract: A sensor system for a vehicle for recognizing adjacent vehicles, situated in an adjacent lane, with protruding or exposed objects, is described which includes a first lateral LIDAR sensor. The first lateral LIDAR sensor is tilted about a first transverse axis with respect to the horizontal, so that the first detection range, with its front portion in the travel direction, detects a first upper spatial area laterally ahead of the vehicle, at a height above the installed position of the first lateral LIDAR sensor. The second lateral LIDAR sensor is tilted opposite to the tilt direction of the first LIDAR sensor about a second transverse axis with respect to the horizontal, so that the second detection range, with its rear portion in the travel direction, detects a second upper spatial area laterally behind the vehicle, at a height above the installed position of the second LIDAR sensor.

Abstract: A sensor system for a vehicle for detecting bridges and tunnels is described, which includes a lateral LIDAR sensor, which is located on a first side of the vehicle and has a detection area covering a lateral surrounding area of the vehicle, and a control unit for evaluating the measuring data from the lateral LIDAR sensor. The lateral LIDAR sensor is positioned rotated about a vertical axis so that part of the detection area of the lateral LIDAR sensor at the front in the travel direction detects an upper spatial area located at a predefined distance ahead of the vehicle. The lateral LIDAR sensor is tilted about its transverse axis with respect to the horizontal, so the detection area of the lateral LIDAR sensor detects the remote upper spatial area at a predefined height above the vehicle using its part which is at the front in the direction of travel.

Abstract: A method for monitoring a setpoint trajectory of a vehicle, including the following: recording the surroundings of the vehicle, ascertaining a clearance based on the recorded surroundings and checking the setpoint trajectory for freedom from collision, based on the clearance, in order to ascertain whether traveling on the setpoint trajectory would result in a collision or not. Also described is a device for monitoring a setpoint trajectory of a vehicle and a related computer program.

Abstract: A method for operating a vehicle includes: detecting an intended strategy of a vehicle occupant for a driving strategy of the vehicle; comparing the intended driving strategy to a number of multiple possible driving strategies for a current driving situation of the vehicle; and controlling the vehicle as a function of a driving strategy that is selected based on the comparison to the number of possible driving strategies.

Abstract: A method for operating a vehicle includes: ascertaining a danger measure of a possible stop position for a safe parking of the vehicle; comparing the ascertained danger measure to a predetermined danger measure threshold value; and guiding the vehicle to the possible stop position in order to safely park the vehicle in the possible stop position only if the ascertained danger measure is less than or equal to the predetermined danger measure threshold value.