The present disclosure relates to an omnidirectional sensor fusion system and method and a vehicle including the same. The omnidirectional sensor fusion system includes a sensor track processing unit configured to receive recognition information from one or more sensors to generate a sensor track, a sensor track association determination unit configured to determine, based on the generated sensor track being located at an overlapping point of sensing regions of the one or more sensors, an association between a previous sensor fusion track and the sensor track, the sensor track association determination unit further configured to change sensor track information in response to the determined association and output a sensor fusion track, a sensor fusion track tracing unit configured to trace the output sensor fusion track, and a sensor fusion track maintenance unit configured to maintain the traced sensor fusion track.

An interactive vehicle safety system having capabilities to improve peripheral vision, provide warning, and improve reaction time for operators of vehicles. For example, the interactive vehicle safety system may have capabilities for portraying objects, which are being blocked by any of the structural pillars and/or mirrors of a vehicle (such as a truck, van, train, etc.). The interactive vehicle safety system disclosed may comprise one or more image capturing devices (such as camera, sensor, laser), distance and object sensors (such as ultrasonic sensor, LIDAR radar sensor, photoelectric sensor, and infrared sensor), a real-time image processing of an object, and one or more display systems (such as LCD or LED displays). The interactive vehicle safety system may give a seamless 360-degree front panoramic view to a driver.

A motor vehicle, having a plurality of image recording devices arranged across the entire vehicle for recording images of the vehicle environment, includes a control device for generating an image representation showing the 360° environment around the motor vehicle on the basis of the images. The motor vehicle further includes a display device for displaying the image representation. The control device is designed to generate an additional partial image representation showing the area below the motor vehicle on the basis of images recorded, and to integrate the partial image representation into the displayed image representation for outputting an overall image representation. At least one sensor device is provided which detects the area below the motor vehicle and communicates with the control device. The overall image representation can be modifiable at least in the area of the partial image representation on the basis of the sensor information.

A collision avoidance assembly for reducing collisions with a semitrailer includes a rear and side facing alert modules, which are mountable to a semitrailer, and a control module, which is mountable in a cab of a semitruck engaged to the semitrailer. Each alert module comprises a sensor, a camera, and a speaker. The sensors detect and the cameras image an approaching vehicle. The speaker and the control module provide audible alerts to a driver of the approaching vehicle and an operator of the semitrailer, respectively, so as to facilitate collision avoidance.

A crane vehicle achieves safe movement by reliably detecting an obstacle in a region which is a blind spot from the opposite side of the driver seat across a boom. The crane vehicle includes an obstacle sensor which is a transmission/reception antenna that transmits a detection wave and receives the detection wave reflected from the obstacle. A signal corresponding to the reflected wave received by the obstacle sensor is amplified and input to a controller, which calculates the position and the size of the obstacle on the basis of the signal. The controller generates an obstacle display image and displays the image on a display, the obstacle display image including a vehicle object that represents a crane vehicle and an obstacle object which is an object corresponding to the calculated size of the obstacle and which is disposed at a position corresponding to the calculated position of the obstacle.

A method of providing surrounding information of a vehicle includes: detecting at least one sensor-based obstacle using sensor detection information acquired through a surroundings sensor, detecting at least one image-based obstacle using image information acquired through a plurality of cameras, detecting at least one matched obstacle from the at least one sensor-based obstacle or the at least one image-based obstacle, and correcting the position of the at least one matched obstacle using at least one of a sensor-based detection result or an image-based detection result with respect to the at least one matched obstacle.

An image processor includes a line extraction portion configured to extract a line from an image generated from a vehicle surrounding image captured at a predetermined timing, a tracking determination portion configured to determine whether the extracted line fulfills a predetermined condition or not, a comparing portion configured to compare the line that is determined as fulfilling the predetermined condition with a line that is extracted by the line extraction portion from another image generated from another vehicle surrounding image captured at a predetermined timing in the past to obtain degrees of similarity and coincidence thereof, a parking area line determination portion configured to determine the line as a parking area line when the degrees of similarity and coincidence are equal to or more than a given value, and a parking frame setting portion configured to set a parking frame using the line determined as the parking area line.

A head-up display (HUD) device for a vehicle includes a sensor for detecting a front object of the vehicle, a controller for selecting any one region of a display region preset based on a driver's gaze as a target region for displaying HUD information depending on an overlapping position and a degree of overlap between the display region and the front object, and determining a virtual image forming position of the HUD information and a graphics mode for displaying a virtual image depending on a relative position of the target region in the display region, an HUD generator for generating the HUD information according to the determined graphics mode, and an HUD adjuster adjusting an image forming distance of the HUD information according to the virtual image forming position.

A driver nudge system is operated within a vehicle to indicate a warning to a driver of the vehicle. The system includes a steering wheel, a vehicle sensor monitoring an operating environment of the vehicle, and an electric motor connected to the steering wheel configured to nudge the steering wheel in an opposite direction to a threat diagnosed according to data from the vehicle sensor.

A vehicle includes: a first camera mounted on the vehicle to have a first field of view and configured to acquire first image data; a second camera mounted on the vehicle to have a second field of view and configured to acquire second image data; a display; and a controller. The controller is configured to display around-view data in which the first image data and the second image data are combined so that a boundary between the first image data and the second image data becomes a first reference angle on the display. The controller is also configured to display around-view data in which the first image data and the second image data are combined so that a boundary between the first image data and the second image data becomes a second reference angle on the display based on an obstacle located around the vehicle.