Abstract: A system includes a first computer and a second computer. The first computer is programmed to receive a request from the second computer to move a vehicle from a first location to a second location and synchronize a timer stored in each of the computers. The first computer determines a route including waypoints from the first location to the second location and determines predicted travel times for legs of the route. The predicted travel times include a first predicted travel time for a first leg defined from the first location to a first waypoint included in the waypoints and the first computer transmits the route and the travel times to the second computer. The second computer is programmed to determine an elapsed time of travel and predict a location of the vehicle based on the elapsed time of travel and the first predicted travel time.

Abstract: A system for controlling autonomously-controllable vehicle functions of an autonomous vehicle cooperating with partner subjects includes a database device with information on communication signals from partner subjects, action objectives, and scenarios, and has an autonomous vehicle with autonomously controllable vehicle functions communicatively connected to the database device. The autonomous vehicle includes a control device with a programmable unit and a surround sensor device. The control device receives sensor signals acquired by the surround sensor device of a surrounding area of the vehicle and communication signals originating from at least one partner subject. The control device determines a situation context based on the database information, and converts the captured communication signals into control signals for the autonomously controllable vehicle functions based on the situation context.

Abstract: A system includes a first computer and a second computer. The first computer is programmed to receive a request from the second computer to move a vehicle from a first location to a second location and synchronize a timer stored in each of the computers. The first computer determines a route including waypoints from the first location to the second location and determines predicted travel times for legs of the route. The predicted travel times include a first predicted travel time for a first leg defined from the first location to a first waypoint included in the waypoints and the first computer transmits the route and the travel times to the second computer. The second computer is programmed to determine an elapsed time of travel and predict a location of the vehicle based on the elapsed time of travel and the first predicted travel time.

Abstract: A computer includes a processor and a memory storing instructions executable by the processor to identify a current location of the vehicle in a map of a stopping area, collect data to calibrate a sensor while the vehicle is moving in the stopping area, calibrate the sensor based on the collected data, and actuate one or more vehicle components to move the vehicle to a stopping location in the stopping area based on the location of the vehicle in the map and data collected by the calibrated sensor.

Abstract: While operating a vehicle on a travel path, a width of the travel path is determined based on a map. Upon detecting a presence or an absence of a target vehicle in the travel path, a lateral position for the vehicle on the travel path is determined based on the width of the travel path and the presence or absence of the target vehicle. The vehicle is controlled to operate according to the determined lateral position on the travel path and a speed of the vehicle that is based on the determined lateral position on the travel path.

Abstract: A method for operating a motor vehicle (2) with a parking assistant (4), which is operable in an in-vehicle operating mode (SM) and a remote parking operating mode (RM), with the steps: (S100) reading data (D) indicative of a parking situation of a detected parking space (6), (S200) evaluating the data (D) to determine an output signal (AS) indicative of the in-vehicle operating mode (SM) or the remote parking operating mode (RM), and (S300) outputting the output signal (AS).

Abstract: A method is provided for the automatic unparking of a motor vehicle, with which a parking trajectory is determined on the basis of directly collected data about the motor vehicle surroundings and additionally on the basis of data relating to the motor vehicle surroundings and obtained during the movement of the motor vehicle to the parking position and stored on a memory device of the motor vehicle. A motor vehicle and a system for carrying out the method will also be provided.

Abstract: A system for controlling autonomously-controllable vehicle functions of an autonomous vehicle cooperating with partner subjects includes a database device with information on communication signals from partner subjects, action objectives, and scenarios, and has an autonomous vehicle with autonomously controllable vehicle functions communicatively connected to the database device. The autonomous vehicle includes a control device with a programmable unit and a surround sensor device. The control device receives sensor signals acquired by the surround sensor device of a surrounding area of the vehicle and communication signals originating from at least one partner subject. The control device determines a situation context based on the database information, and converts the captured communication signals into control signals for the autonomously controllable vehicle functions based on the situation context.

Abstract: While a vehicle is operated from a first area to a second area based on a stored route, one or more turning regions are identified along the stored route based on sensor data. Upon selecting one turning region, a route is determined from the second area to the first area via the selected turning region based on the stored route. Upon receiving a message from a handheld device, the vehicle is actuated to operate along the route and turn around in the selected turning region.

Abstract: While a vehicle is in an off state, expiration of a timer and receipt of a first message from a user device are monitored. Upon determining that at least one of the timer has expired or that the first message is received from the user device, a communication network onboard the vehicle is then monitored for a specified set of fault conditions. Upon detecting, on the onboard vehicle communication network, a fault condition included in the set of fault conditions, the fault condition is then identified as one of transient or persistent. A user assist feature of the vehicle is disabled upon identifying that the fault condition is transient and that a second message was received from the user device after the fault condition was detected.

Abstract: The invention concerns a method for operating a brake back-up system (8) of a motor vehicle (2), with the steps: (S100) Reading in operating data (BD) of the motor vehicle (2), (S200) Evaluating the read-in operating data (BD) to identify malfunctions of a braking system of the motor vehicle (2), and (S300) Providing at least one actuation signal (AS, AS?) to influence components of a drive train of the motor vehicle (2).

Abstract: Enhancing situational awareness of an advanced driver assistance system in a host vehicle can be provided by acquiring, with an image sensor, an image data stream comprising a plurality of image frames. Analyzing A vision processor can analyze the image data stream to detect objects, shadows and/or lighting in the image frames. Recognizing A situation recognition engine can recognize at least one most probable traffic situation out of a set of predetermined traffic situations taking into account the detected objects, shadows and/or lighting. A processor can then control the host vehicle taking into account the at least one most probable traffic situation.

Abstract: While a vehicle is in an area, a stored map uncertainty value of map data for the area is retrieved. The stored map uncertainty value gives a range of uncertainty for at least one indicator of a travel path specified by the map data. Upon estimating the travel path and a vehicle pose, a dynamic map uncertainty value is determined based on a pose uncertainty value and a travel path uncertainty value. The pose uncertainty value gives a range of uncertainty for the vehicle pose in three degrees-of-freedom based on vehicle sensor data, and the travel path uncertainty value gives a range of uncertainty for the at least one indicator of the estimated travel path based on vehicle sensor data. Upon determining that the dynamic map uncertainty value is less than the stored map uncertainty value, the map data is updated based on the vehicle sensor data. Upon updating the map data, the vehicle is operated based on the updated map data.

Abstract: A method for controlling a user-initiated vehicle-operation-command, the user of the vehicle being located external to the vehicle during an autonomous driving or parking operation of the vehicle, is provided wherein the vehicle-operation-command is a cancellation or stop command of the autonomous driving or parking operation. A system equipped to perform the method and to a vehicle including the system is also provided. The method and apparatus enhance the security-level of autonomous driving and parking operations.

Abstract: The invention relates to a method for operating a motor vehicle (2) with a remotely controlled parking assistant (6), with the steps: (S100) Reading in status data (SD) indicative of a status (S1, S2, S3, S4), (S200) Determination of at least one state (Z1, Z2) by evaluating the status data (SD), (S300) Assigning the specific state (Z1, Z2) to a state class (K1, K2) of a plurality of state classes (K1, K2), and (S400) Outputting a control data record (AS1, AS2) that is assigned to the assigned state class (K1, K2) and/or (S600) outputting an information data record (IS1, IS2) that is assigned to the assigned state class (K1, K2).

Abstract: While operating a vehicle on a travel path, a width of the travel path is determined based on a map. Upon detecting a presence or an absence of a target vehicle in the travel path, a lateral position for the vehicle on the travel path is determined based on the width of the travel path and the presence or absence of the target vehicle. The vehicle is controlled to operate according to the determined lateral position on the travel path and a speed of the vehicle that is based on the determined lateral position on the travel path.

Abstract: A user trained map for providing driver assistance in a vehicle is obtained by entering a training mode, acquiring and at least temporarily storing vehicle sensor data related to the vehicle's position during training mode while the vehicle is operating in training mode, generating and storing a trained digital map of a parking route at least partially based on the acquired vehicle sensor data, acquiring and storing position information related to a drop-off location and to a pickup location, the drop-off location and the pickup location being part of the parking route, and exiting the training mode.

Abstract: A vehicle is operated along a segment of a stored travel path based on vehicle operating parameters for the segment. The stored travel path includes a risk level for the segment. The risk level for the segment is updated based on actuating a vehicle component to avoid an object along the segment. The vehicle operating parameters for the segment are updated based on the updated risk level. The vehicle is operated along the segment based on the updated vehicle operating parameters.

Abstract: A sub-area in an area is identified as an authorized sub-area for a vehicle to access based on detecting a first object in the sub-area from first sensor data. Then a parameter of the first object is determined from the first sensor data. Upon detecting a second object in the sub-area from second sensor data, a parameter of the second object is determined based on the second sensor data. The sub-area is determined valid based on determining the parameter of the second object is different than the parameter of the first object.

Abstract: A computer includes a processor and a memory storing instructions executable by the processor to identify a current location of the vehicle in a map of a stopping area, collect data to calibrate a sensor while the vehicle is moving in the stopping area, calibrate the sensor based on the collected data, and actuate one or more vehicle components to move the vehicle to a stopping location in the stopping area based on the location of the vehicle in the map and data collected by the calibrated sensor.