Abstract: A method for driving a vehicle on an opposite lane in a controlled manner includes detecting, with a surroundings sensor system, surroundings of the vehicle and receiving, with a control device, measurement data of the surroundings sensor system. The method includes identifying at least one course of a road, and at least one course of at least one road user in the surroundings based on the received measurement data and planning a trajectory of the vehicle within the at least one course of a road. The method further includes identifying a section of the road wherein when driving on the section of road the opposite lane is cut across by the vehicle, and determining a first stop position for the vehicle prior to entering the identified section of road. The method then checks whether the opposite lane can be driven on in the identified section.

Abstract: A method and device for determining the location of a vehicle, including reading in first position data values which represent a position of an environmental feature in the environment of the vehicle, controlling a lighting unit of the vehicle as a function of the read-in first position data values, to adjust an illumination of the environmental feature, and determining second position data values, which represent a position of the vehicle, based on the position of the environmental feature, whose illumination is adjusted by the lighting unit of the vehicle.

Abstract: A method is described for determining a pose of a vehicle that is driving in an at least partially automated manner, with the aid of different landmark types, and in order to determine the pose of the vehicle, a vehicle control system processes landmark data of the detected landmark types with the aid of at least one detector algorithm. At least one detection algorithms is selected and used for processing the landmark data of certain landmark types as a function of environmental influences.

Abstract: A method for determining an attitude of an at least partially autonomously moving vehicle using landmarks, a back-end server being provided, by which landmark data of the landmarks are transmitted from a map to a vehicle control system of the vehicle. According to the system and method, landmark data to be transmitted are selected as a function of environmental influences and a transmission of landmark data from the back-end server to the vehicle control system is limited to the selection made.

Abstract: A method initiates a reaction of a first vehicle to a person in the environment of a second vehicle. The person is on a road on which the first vehicle is travelling and the second vehicle is detected. Measurement data determined by at least one sensor unit are received by a control unit. The control unit carries out a classification and registers the evaluated data as a person and as a second vehicle. Motion vectors of the person are determined and the expected movement of the person is calculated. A position and width of the vehicle doors of the second vehicle are determined or estimated on the basis of the measurement data. A probability of the person opening a vehicle door is calculated. A reaction of the first vehicle is initiated by the control unit depending on the calculated probability.

Abstract: A method for adjusting a safety distance between a first vehicle and a second vehicle preceding the first vehicle at a bunched traffic site by at least one control device is disclosed which includes receiving measurement data of at least one sensor unit with the at least one control device. The method includes evaluating the measurement data of the at least one sensor unit with the at least one control device to identify a bunched traffic site in front of the second vehicle and identifying a safety distance of the first vehicle from the second vehicle, wherein the identified safety distance accounts for a possible reverse motion of the second vehicle. The method further includes establishing the identified safety distance with the at least one control device based upon the identified bunched traffic site. A control device, a computer program and a machine-readable storage medium are further disclosed.

Abstract: A method for monitoring the environment of a vehicle includes evaluating physical measurement data obtained from the environment of the vehicle to determine whether at least one person is approaching the vehicle, how many people approach the vehicle may also be recorded. The method includes evaluating physical measurement data obtained from the environment of the vehicle to determine whether at least one person is moving away from the vehicle and, if appropriate, the number of people that are moving away from the vehicle is also recorded. The method further includes carrying out a check as to whether the number of people that have moved away from the vehicle corresponds to the number of people that have previously approached the vehicle. In response to the check resulting in a difference, it is determined that the vehicle is in an unsafe state.

Abstract: A method for detecting a light-emitting object at a traffic junction for a vehicle, the method including a reading in in which the light signal is read in which represents at least one chronologically changing light range of a light-emitting object. Furthermore, the method includes determining in which a driving parameter of the light-emitting object is determined using the light signal. Finally, the method includes providing, a detection signal being provided using the driving parameter and the detection signal representing a presence and/or an approach of the light-emitting object.

Abstract: A method and a device for determining a highly precise position and for operating an automated vehicle, including: detecting surroundings data values, the surroundings data values representing surroundings of the automated vehicle, the surroundings encompassing at least two surroundings features, determining a pattern, as a function of the at least two surroundings features, reading in map data values, the map data values representing a map, the map representing at least the surroundings of the automated vehicle, the map encompassing a reference pattern, determining the highly precise position of the automated vehicle, proceeding from a comparison of the pattern to the reference pattern, and operating the automated vehicle, as a function of the highly precise position.

Abstract: A method for determining a pose of an at least semi-autonomously driving vehicle with the aid of landmarks, the vehicle including detectors, with which the landmarks are detected, and a back-end server being provided, with which the landmark data of the landmarks are transmitted from a map to a vehicle control system of the vehicle, the method including at least the following steps: —communicating detection reports relating to detected landmarks from the vehicle control system to the back-end server, —sending data relating to environmental influences from an information service to the back-end server, which environmental influences have an effect on the detection of landmarks with the aid of the detectors of the vehicle, —statistically evaluating environmental influences on specific types of landmarks and —selecting landmarks as a function of the statistical evaluation and of instantaneous environmental influences and —transmitting the selection of landmarks from the back-end server to the vehicle control sys

Abstract: A method and a device for operating an automated vehicle, including: determining a position of the automated vehicle, detecting at least one surroundings feature in the surroundings of the automated vehicle, reading in a planning map depending on the position of the automated vehicle, the planning map being configured for determining a first driving function for operating the automated vehicle, determining a validity of the planning map depending on the position of the automated vehicle depending on the at least one surroundings feature, and operating the automated vehicle depending on the validity of the planning map.

Abstract: A method for localizing a more highly automated vehicle (HAF), in particular a highly automated vehicle, in a digital map. The method includes: ascertaining a global pose estimation for the HAF using a localization module of a vehicle system of the HAF, the global pose estimation comprising a position and orientation of the HAF; transmitting at least one landmark position and at least one associated landmark property to the vehicle system; ascertaining a relative position of the landmark position concerning the HAF at least partially on the basis of the pose estimation and the landmark position; performing at least one sensor measurement and checking that the at least one landmark property is detectable at the relative position; and outputting an error indicator as the result of the checking. A corresponding system and a computer program are also described.

Abstract: A method/system for calibrating a vehicle sensor, including detecting data about the vehicle's surroundings using the sensor, and ascertaining stationary structures using the detected first data pieces. Stationary structures are selected for later calibration, and potential parking positions are determined. A parking position is selected from the potential parking positions so that after parking, stationary structures selected for a calibration of the sensor are in the sensor's field of vision. The vehicle is parked, and the position of the stationary structures selected for the calibration of the sensor is stored. After the vehicle start, second data pieces about the vehicle's surroundings are detected using the sensor, and instantaneous positions of the selected stationary structures are ascertained using the detected second data pieces. The instantaneous position are compared with the stored positions, and deviations between the instantaneous positions and the stored positions determined.

Abstract: The disclosure describes a method for operating an automated vehicle comprising: receiving environmental data; ascertaining a driving area that is to be traveled on by the vehicle, and a prohibited area that is not to be traveled on by the vehicle, based on the environmental data; determining whether a bottleneck exists in which the driving area is in an at least partially blocked state by a further road user or an obstacle, such that it is not possible, exclusively using the driving area, for the automated vehicle and/or the further road user to pass or for the automated vehicle to pass by the obstacle; ascertaining a trajectory in which the vehicle at least partially uses the prohibited area if a bottleneck exists; and emitting an actuation signal for operating the automated vehicle based on ascertained trajectory.

Abstract: A method and device for operating at least two automated vehicles including picking up signals, which are transmitted in each case from the at least two automated vehicles; inputting a map as a function of the signals, determining a common driving strategy for the at least two automated vehicles in a way that optimizes a localization potential of the at least two automated vehicles on the basis of the map and as a function of the signals, and providing the common driving strategy for operating the at least two automated vehicles. A vehicle device for operating an automated vehicle, which includes a transmitter and receiver device, and a control unit is also provided.

Abstract: A method for locating a vehicle, including the following steps: sensorial detection of first surroundings objects by the vehicle; locating the vehicle by reconciling data of the sensorially detected first surroundings objects with map data of a first digital map, in the case in which reconciliation of the data of the first surroundings objects with the map data of the first digital map to a defined extent is not possible, a second digital map for a local surroundings of the vehicle being created and location of the vehicle being carried out using the second digital map, data from second surroundings objects of an ascertaining device, which are conveyed from the ascertaining device to the vehicle, being used for creation of the second digital map.

Abstract: A method and a device for determining a highly-precise position and for operating an automated vehicle, including receiving map data values from an external server, which represent a map, the map including weather-specific surroundings features, determining a weather-specific surroundings condition, detecting surroundings data values, the surroundings data values representing the surroundings of the automated vehicle, the surroundings including dynamic surroundings features, determining the highly-precise position based on a comparison between the weather-specific surroundings features and the dynamic surroundings features depending on the weather-specific surroundings condition, and operating the automated vehicle, depending on the highly-precise position.

Abstract: The disclosure relates to a method for the situational transmission of surroundings data of a vehicle, comprising the steps: determining a driving situation of the vehicle; determining relevant surroundings data from recorded surroundings data based on the driving situation, wherein the relevant surroundings data are a subset of the recorded surroundings data that are relevant to the driving situation; and providing the relevant surroundings data to an external data processing device.

Abstract: The disclosure relates to a a method for automating driving of a vehicle into a stopping position. The method includes receiving and processing vehicle environment signals, and generating control signals configured to at least partly automate the driving of the vehicle into the stopping position. The processing includes detecting an entry/exit area to be used for boarding/disembarking of a wheelchair user, checking whether the entry/exit area has spatial dimensions required for for the boarding/disembarking, checking whether the entry/exit area is independently traversable by the wheelchair user, and determining a stopping position adjacent to the entry/exit area for stopping the vehicle in response to recognizing that (i) the entry/exit area has the spatial dimensions required for the at least one of the boarding and the disembarking of the wheelchair user and (ii) the entry/exit area is independently traversable by the wheelchair user.

Abstract: The disclosure relates to an improved way to avoid or clear a traffic jam. In particular, the disclosure relates to a method for the operation of a vehicle in which at least partial intersection by a dynamic object with a first section of the traffic area occupied by the vehicle is predicted, wherein the vehicle is in a waiting situation waiting for a release for onward travel. Then a trajectory of the vehicle is determined, which at least clears or avoids the intersection by the dynamic object with the first section of the traffic area. Further, the disclosure relates to a device for the operation of a vehicle, a program element and a computer-readable medium with such a program element.