A display device for a vehicle includes: a plurality of imaging units configured to capture images around the vehicle; an image compositing unit configured to composite the images captured by the imaging units to generate a composite image; an image display unit configured to display the composite image generated by the image compositing unit; and an acquiring unit configured to acquire information about an object around the vehicle. The imaging units are arranged such that imaging areas thereof overlap with each other. The image compositing unit is configured to set a boundary between the captured images in the composite image such that the boundary is provided in a part where the imaging areas of the imaging units overlap with each other. In a case where the acquiring unit acquires the information about the object, the image compositing unit changes the boundary.

A parking assistance device includes a camera configured to capture a rear-view image of a vehicle, a plurality of sensors configured to sense an obstacle located around the vehicle, a controller configured to generate a parking guide line to guide the vehicle into a target parking space and assist a driver of the vehicle to park based on a separation distance between a predicted entrance trajectory corresponding to a steering angle of the vehicle and the parking guide line, and a display configured to match and display the rear-view image of the vehicle with the parking guide line.

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 display system includes an image capture device, a display device, and at least one of a first illuminance sensor and a second illuminance sensor. The image capture device captures an image rearward of the vehicle. The display device is coupled to the image capture device, and receives at least a portion of the rearward image captured by the image capture device. The first illuminance sensor detects brightness around the vehicle, and the second illuminance sensor detects intensity of light emitted onto a front surface of the display device.

A parking assist system includes a control device configured to control screen display of a display device, to set a parking position candidate selected by an occupant as a target parking position, and to control an autonomous parking operation to autonomously move the vehicle to the target parking position. When a number of the parking position candidates detected by a parking position candidate detector exceeds a predetermined upper limit number, the control device selects, from among the detected parking position candidates, the upper limit number of parking position candidates to be displayed on the display device according to a predetermined rule and causes the display device to display the parking position candidates that have been selected.

A volume hologram is arranged inside a transparent portion of a pane of a display device for a vehicle. The display device further includes a light source by which light is coupled into the volume hologram. An image appearing three-dimensional to a human observer can be generated by use of the volume hologram. A camera includes a light-sensitive image sensor to acquire images via an optical unit which is at least partially formed by the transparent portion of the pane.

A vehicle body structure, comprising an image capturing apparatus configured to capture an image of a left-rearward area and a right-rearward area of a vehicle, and a display apparatus including a left-side display unit configured to display the left-rearward area and a right-side display unit configured to display the right-rearward area, wherein when viewed in a vehicle body front-and-rear direction, the left-side display unit and the right-side display unit are respectively fixed at a left-side end part and a right-side end part of a vehicle cabin forward structure so as to be positioned higher than a center of a steering wheel and lower than an upper end of the steering wheel.

A photoelectric conversion apparatus includes a control unit configured to change a voltage of an input node from a first voltage toward a predetermined voltage during a predetermined time period after the voltage of the input node changes to the first voltage and before the voltage of the input node changes to a second voltage. A method of driving the photoelectric conversion apparatus includes controlling changing of the voltage of the input node from the first voltage toward the predetermined voltage during the predetermined time period.

A method, computer program product, and computing system for monitoring one or more machine vision sensors to obtain perception information concerning one or more third-party vehicles proximate an autonomous vehicle; identifying one or more vehicle shapes within the perception information, thus defining one or more detected vehicles shapes; generating proximate object display information that locates the one or more detected vehicles shapes with respect to the autonomous vehicle; and rendering the proximate object display information on a visual display system, thus confirming the perception of the one or more third-party vehicles by the autonomous vehicle.

A lead vehicle braking warning system includes a speed sensor, a detector, a display and an electronic controller. The speed sensor measures current speed of a host vehicle. The detector detects current speed of a lead vehicle relative to the speed of the host vehicle. The display has a braking condition display area configured to display each of a plurality of braking conditions of the lead vehicle for the operator of the host vehicle. The electronic controller is in electronic communication with the speed sensor, the detector and the display. The electronic controller determines whether or not the lead vehicle is currently decelerating and determine which one of a plurality of braking conditions is currently being experienced by the lead vehicle and display information identifying the current one of the plurality of braking conditions of the lead vehicle within the braking condition display area of the display.