A system is disclosed to communicate in vehicular traffic an intention of a driver of a vehicle to execute a parallel parking maneuver. The system includes a display generating a signal to indicate to other drivers the intention to execute the parallel parking maneuver to either a left side of the vehicle or a right side of the vehicle. The signal is distinct from and in addition to a turn signal for the vehicle indicating an intended left turn or right turn. Embodiments of the disclosed system include an illuminated word parallel, arrows pointing both right and left and forward and backward, a determination to a particular open space based upon an orientation of a head of the driver, and a laser emitter providing a second indication to onlookers to a parking space.

A vehicle control device according to an embodiment includes: a steering controller configured to control steering of a vehicle; and a controller configured to, when the vehicle is located at a first position on a travel route, instruct the steering controller to control the vehicle at a steering angle corresponding to a second position that is an advanced position from the first position in a traveling direction on the travel route.

A parking assistance device according to an embodiment includes a determination unit that determines, when the parallel parking of a vehicle in a parking area is assisted, whether the parking space length of a frontage that the vehicle enters in the parking area is the sum of the full length of the vehicle and a certain length or more and a control unit that performs parking assistance for the vehicle along a route in which stationary steering control is not performed at a turning position of the vehicle when the parking space length is the sum of the full length of the vehicle and the certain length or more.

Systems and methods for curb detection for parking are disclosed. An example vehicle parking assist system includes a processor and memory. An example program stored in the memory is configured to move a vehicle using a set of maneuvers to park the vehicle in a parking space based on an estimated location of a curb. The example program is also configured to compare a first yaw rate to a reference yaw rate to detect when the vehicle contacts the curb. Additionally, the example program is configured to move the vehicle using an adjusted set of maneuvers based on an actual location of the curb.

A method for operating a driver assistance system of an electrically driven motor vehicle includes providing a first and a second driving mode and setting the first driving mode or the second driving mode via an actuating device by a single user input. A first turning maneuver of the motor vehicle is set as the first driving mode and a second turning maneuver of the motor vehicle is set as the second driving mode. During the first turning maneuver, a direction of movement for each of the four wheels of the motor vehicle is respectively set via four control signals such that right side wheels of the motor vehicle and left side wheels of the motor vehicle rotate against each other. Via the driver assistance system, the motor vehicle is operated at least partially autonomously at least during the first driving mode and/or the second driving mode.

A system and method are provided for steering control during vehicle reverse operation when maneuvering a trailer in a reverse direction with a desired turn angle. The system has a P-I-D cascade structure and includes a rear video camera for providing images to determine a trailer angle, a yaw angle determination device, a steering angle sensor, a vehicle interior display with an input device, and a vehicle speed determination device. When a trajectory mode is selected and a desired turn angle value are received, an electronic processor determines a trailer trajectory based on the desired turn angle value, the trailer angle, vehicle yaw angle, and physical properties of the vehicle and trailer. The trailer trajectory is displayed on the vehicle interior display with the rear camera image. When a driver selects an automatic steering maneuver mode, the trailer tow assist system automatically controls steering of the vehicle.

An automobile having sets of front and rear wheels, of which one or both sets are steerable wheels and one or both sets are driven wheels. Each steerable wheel is rotatably supported on a respective steering knuckle that is swivelable about an upright steering axis, and is coupled to the frame by a suspension system for relative movement upwardly and downwardly of the automobile's frame. The steering knuckle of each steerable wheel is movable through a ninety degree range between a straight-ahead position for longitudinally straight travel of the automobile in a normal road travel mode, and a ninety-degree position for lateral travel of the automobile in another mode.

A method for operating a display unit in a vehicle includes detecting a parking space and collision obstacles. The collision obstacles are obstacles located in the vicinity of the vehicle and/or the parking space. A relative position of the vehicle to the parking space is determined. A control signal is generated to generate an image on the display unit according to the relative position of the vehicle to the parking space. The image comprises a virtual vehicle, a virtual parking space and schematic elements. The virtual vehicle is a schematic representation of the vehicle. The virtual parking space is a schematic representation of the parking space. The schematic elements are a schematic representation of the collision obstacles.

The present disclosure relates to an apparatus and method for controlling a parking operation of a vehicle, and more specifically, to a specific method and apparatus for controlling a parking operation of a vehicle using a radar sensor and an ultrasonic sensor of the vehicle to reduce parking time.

An information processing device for a vehicle includes an object detecting unit, an object information storage unit, and an object information management unit. The object detecting unit detects, based on an output of a sensor mounted on the vehicle, an object located around the vehicle. The object information storage unit stores, as object information, information about the object detected by the object detecting unit. The object information management unit is configured to: receive, from a travelling assistance unit that performs an assistance operation of assisting travelling of the vehicle based on the object information, related information, the related information being related to the assistance operation performed by the travelling assistance unit; determine storage priority of the object information in the object information storage unit based on the related information; and manage a storage state of the object information in the object information storage unit based on the storage priority.