A parking assistance system for a vehicle includes surround sensors, internal sensors, a data memory, and a processing unit. The surround sensors are configured to provide sensor data of the surrounding of the vehicle. The internal sensors are configured to detect a seat occupancy of passenger seats within the passenger room of the vehicle. The data memory stores a vehicle data model of the vehicle including positions of vehicle doors in the chassis of the vehicle. In addition, the processing unit is configured to process the sensor data received from the surround sensors to calculate an occupancy grid map of the vehicle's surrounding and further configured to calculate disembarking distances for the vehicle doors depending on the vehicle data model, the occupancy grid map and the detected seat occupancy.

An imaging system for a vehicle includes an imaging sensor and a video display device. The imaging system generates an overlay that is electronically superimposed on the displayed images to assist a driver of the vehicle when executing a backup maneuver. The overlay has first, second and third overlay zones, with the overlay zones indicative of respective distance ranges from the rear of the vehicle to respective distances. As indicated to the driver viewing the video display screen when executing a backup maneuver, the first distance is closer to the rear of the vehicle than the second distance and the second distance is closer to the rear of the vehicle than the third distance. The first overlay zone may be a first color and the second overlay zone may be a second color and the third overlay zone may be a third color.

The present application provides an obstacle detection system and method thereof. The obstacle detection method comprises: obtaining a first image captured by a camera at a first time point; identifying a vertical edge candidate in the first image, and measuring a first length of the vertical edge candidate based on the first image; obtaining a second image captured by the camera at a second time point; measuring a second length of the vertical edge candidate based on the second image; calculating a difference between the first length and the second length; and comparing the difference with a predetermined length difference threshold, if the difference is greater than the length difference threshold, outputting a message that an obstacle is found.

A method for determining an ego-motion of a vehicle is described, which is carried out in driver assistance systems, particularly in parking assistance systems. The method involves: taking a sequence of images, successive in time of a vehicle surroundings by a vehicle camera; determining, based on the image sequence, at least one motion flow with regard to an object in the vehicle surroundings; and determining the ego-motion of the vehicle based on the at least one motion flow.

A working vehicle includes a vehicle main body to which a tire is mounted, an excavation member coupled to the vehicle main body on a front side of the vehicle main body and that includes an end part arranged on an outer side of the tire in a vehicle-width direction of the vehicle main body, a hydraulic cylinder arranged at a center part in the vehicle-width direction and that is to move the excavation member, a housing that houses a power transmission mechanism to transmit power to the tire, and a camera supported by a part of the vehicle main body on a lower side of the hydraulic cylinder and on an upper side of the housing and that acquires an image of a region that includes end parts on both sides of the excavation member and that is between the excavation member and the tire.

The driving assistance system of motor vehicles comprises a driving assistance device of a motor vehicle having at least a detection device for detecting the presence of possible obstacles on the outside of the motor vehicle, first activation/deactivation means operatively connected to the detection means and adapted to the activation/deactivation of the detection means, a first RF communication unit operatively connected to the first activation/deactivation means, removable fixing means of the assistance device to the motor vehicle, and wherein the system comprises a command device of the assistance device comprising an OBD type connector coupleable to an OBD type connection port of an on-board diagnostics system of the motor vehicle.

The invention relates to a method for operating a rearview camera system (2) of a motor vehicle (1), in which a sequence of images (15) of an environmental region (9) behind the motor vehicle (1) is provided by means of an image capturing device (3) of the rearview camera system (2) and the sequence of the images (15) is displayed on a display (10), wherein a headlight flasher (14) of a vehicle (13) located in the environmental region (9) is detected by the rearview camera system (2) and due to the detection of the headlight flasher (14), a warning signal (17) separate from the images (15) is generated, by which the detected headlight flasher (14) is signaled to the driver of the motor vehicle (1).

A vehicle lighting system includes: a lighting device that emits a first light and a second light to a periphery of an own vehicle, the second light having a higher directivity than the first light; a camera to acquire image information; a detector to emit an electromagnetic wave and acquire a reflection wave; and an electronic control unit configured to detect a physical body using the image information, detect the physical body using information of the reflection wave, control the lighting device such that the first light is emitted to the physical body detected by the reflection wave, determine whether the physical body detected using the image information in a state where the first light is being emitted is an target object, and control the lighting device such that the lighting device emits the second light toward a predetermined range around the target object.

A vehicle control system for moving a vehicle to a target location is disclosed. According to examples of the disclosure, a camera captures one or more images of a known object corresponding to the target location. An on-board computer having stored thereon information about the known object can process the one or more images to determine vehicle location with respect to the known object. The system can use the vehicle's determined location and a feedback controller to move the vehicle to the target location.

In some embodiments of the present disclosure, techniques are provided for automatic turn signal deactivation in a vehicle with a trailer. The vehicle includes a camera monitoring system that provides video images for display devices that replace traditional side view mirrors. In some embodiments, video information is obtained from the camera monitoring system and is used to determine an angle of the trailer. Upon activation of a turn signal indicator, the video information is used to detect departure of the trailer angle from a centered region and the subsequent return of the trailer angle to the centered region in order to automatically deactivate the turn signal indicator.