Provided is a vehicle control device mounted on a vehicle including headlights. The vehicle control device includes an environment recognition unit, an image generation unit, an image display unit, and an illumination range detector. The environment recognition unit acquires surrounding environment formation around the vehicle. The image generation unit generates, on a basis of the surrounding environment information, an environment image that includes forward environment information on environment forward of the own vehicle. The image display unit displays the environment image. The illumination range detector detects an illumination range, in which the illumination range is illuminated by the headlights. The environment image solely includes information acquired inside the illumination range.

A vehicular vision system includes a camera module configured for mounting at an in-cabin portion of a windshield of a vehicle and viewing forward of the vehicle and through the windshield. The camera is electrically connected to circuitry established at the circuit board via a flexible electrical connection. Circuitry of the circuit board (i) provides electrical power to the camera via the flexible electrical connection, (ii) controls the camera via the flexible electrical connection, (iii) receives image data from the camera via the flexible electrical connection and (iv) includes a data encoder chip operable to encode captured image data. With the camera module mounted at the windshield, the circuit board is tilted at an acute angle relative to the longitudinal axis of the lens barrel of the camera. An image processor is operable to process image data captured by the camera for a driver assist system of the vehicle.

A parking assist system and method that uses one or more cameras on the side of a vehicle to provide modified video output to an electronic display unit that can assist a driver with parallel parking. The modified video output provides the driver with real time visual feedback of the position of the vehicle, with respect to a curb or other barrier, and may also indicate if the current position is compliant with local parking regulations, as determined based on the vehicle's current location. The modified video output includes one or more visual indicators that may be graphically superimposed over top of the video output from the side camera so that the driver can see in real time when the vehicle is or is not lawfully parallel parked.

An image signal processing apparatus includes a first control unit starting activation in response to an activation request, a decoding unit, and a second control unit. Each of the decoding unit and the second control unit starts activation when the first control unit completes the activation, and shifts from an off-state to a normal operating state after the activation is completed. In the normal operating state, the decoding unit receives an image signal from outside and outputs the image signal after executing a decoding process to the image signal. In the normal operating state, the second control unit processes an image included in the image signal outputted from the decoding unit, and displays the processed image. When the first control unit completes the activation and the decoding unit completes the activation, the first control unit instructs the decoding unit to perform a setting for executing the decoding process.

A displace device for a vehicle includes a display unit and a controller. The controller is configured to: receive an image of a road in which the vehicle is located and trajectory information providing a trajectory of vehicle movement, detect one or more lanes of the road based on the received image of the road, assign weights to (i) the detected one or more lanes and (ii) the trajectory of vehicle movement, respectively, based on a preset reference value, generate a virtual road image providing a direction based on the assigned weights, and control the display unit to display the generated virtual road image.

A method for controlling a vehicle as it travels along a road includes processing at an ECU provided image data captured by a forward viewing camera and processing at the ECU a provided output indicative of a determined geographical location of the vehicle. Responsive at least in part to processing of the provided output, a geographically-derived path of travel of the vehicle is generated. Responsive to determination of a traffic lane in which the vehicle is traveling along the road, a camera-derived path of travel of the vehicle is generated. The vehicle is controlled based on (i) the geographically-derived path of travel of the vehicle and/or (ii) the camera-derived path of travel of the vehicle. The vehicle is controlled based on diminished weight of the geographically-derived path or diminished weight of the camera-derived path when a respective reliability level is below a threshold level.

An augmented road line display system that includes one or more sensors installed on a vehicle, one or more external databases, and processing circuitry. The processing circuitry is configured to receive inputs from the one or more databases, sensors of the vehicle, and a sub-system of the vehicle, build and validate a road line model to detect or predict a road line based on the inputs received, determine environmental conditions based on the inputs from one or more of the databases, and a sub-system of the vehicle, assign weights to the inputs received based on the environmental conditions to generate weighted inputs, and execute the road line model to determine the road line based on the weighted inputs.

A visual system (1) for a vehicle (7) having a capturing unit (2) for capturing a field of view (8) and a calculation unit (3), which is adapted to generate image data to be displayed based on the captured image data, and to supply the same to an image display unit (4), wherein the image data to be displayed include the field of view (8) captured by the capturing unit (2), the image display unit (4) is adapted to display the image data to be displayed, so that they are visible for the driver of the vehicle (7), and the calculation unit (3) is adapted to superimpose at least one trajectory (10, 10′) of a future track/driving curve of the vehicle (7) on the image data to be displayed on the image display unit (4), if a steering angle of the vehicle (7) has a predetermined amount.

A backup assist system for a vehicle reversing a trailer includes an input receiving a backing command and outputting a control signal based thereon. A controller receives the control signal, generates a vehicle steering command based on the control signal, and determines a length of a recovery period based on the control signal. The system also includes an interface outputting an indication of the length of the recovery period.

A heads up display arrangement for a motor vehicle includes a wheel sensor sensing a speed of rotation of a wheel. A distance-sensing device senses a distance between the motor vehicle and an other vehicle that is in front of the motor vehicle relative to a direction of travel of the motor vehicle. A processor receives the sensed speed of rotation of the wheel and calculates dependent thereon a stopping distance of the motor vehicle. A heads up display presents an image indicative of both the calculated stopping distance of the motor vehicle and the sensed distance between the motor vehicle and the other vehicle.