A head up display (HUD) system includes: a difference module configured to determine a speed difference based on a difference between (a) a present speed of a vehicle and (b) a target speed of the vehicle; a light source configured to, via a windshield of the vehicle, generate a virtual display that is visible within a passenger cabin of the vehicle; and a display control module configured to control the light source to include a visual indicator of the speed difference in the virtual display.

A system for a vehicle towing a trailer includes a sensor system configured to detect objects in an operating environment of the vehicle and a controller configured to monitor a relative position of at least one object with respect to the vehicle during an initial vehicle movement and store in memory the information as a reference data set at an instance when the initial vehicle movement ends at a vehicle standstill. The controller is further configured to retrieve from memory the reference data set upon detecting an event indicating an end of the vehicle standstill, process the reference data set to determine whether the at least one object is in a travel path of the trailer corresponding with a subsequent vehicle movement, and execute a contact avoidance measure based on the at least one object being in the travel path of the trailer.

The present invention relates to an image output device mounted on a vehicle to implement augmented reality. One or more of an autonomous driving vehicle, a user terminal, and a server of the present invention can be linked to an artificial intelligence module, a drone (unmanned aerial vehicle, UAV), a robot, an augmented reality (AR) device, a virtual reality (VR) device, a device related to 5G services, etc.

An image capturing unit captures a periphery of a moving body through a transmitting portion. A heater is capable of heating the transmitting portion. An air-conditioning unit switches an air-conditioning state in the moving body between an inside air circulation state and an outside air introduction state. A control unit controls the heater. The control unit can make the heater operate intermittently, and perform control so that an OFF time of the heater during an intermittent operation will be shorter in the case in which the air-conditioning state is set to the inside air circulation state than the case in which the air-conditioning state is set to the outside air introduction state.

The present disclosure provides a display system that includes an information acquisition device, a display processing device, a posture detection device, and a correction processing device. The information acquisition device acquires a position of a moving body and information outside the moving body. The display processing device controls display of an image based on information acquired by the information acquisition device. The posture detection device that detects posture variation of the moving body. The correction processing device that sets a correction amount of a display position of the image based on posture variation of the moving body, outputs the correction amount when the display information acquired from the display processing device indicates that the image is being displayed, and reduces size of the correction amount when the display information indicates that the image is not being displayed.

To clear the line-of-sight (LOS) on a window in a lidar system within a vehicle, ultrasonic transducers are physically attached to the interior surface of the window to remove debris. When debris is detected at the window, the ultrasonic transducers are directed to vibrate at an ultrasonic frequency thereby generating an ultrasonic wave which causes the debris to bounce off the window. In some scenarios, the ultrasonic transducers vibrate with a particular phase shift to generate a travelling wave that causes the debris to sweep across the window. Additionally, windshield wipers, spray from a nozzle, and/or a hydrophobic or oleophobic coating may be used in combination with the ultrasonic transducers to remove the debris from the window.

A solid-state imaging device according to an embodiment of the present disclosure includes a stacked photoelectric converter for each of pixels. The stacked photoelectric converter has a plurality of photoelectric conversion elements stacked therein. The plurality of photoelectric conversion elements each has different wavelength selectivity. This solid-state imaging device further includes a plurality of data output lines from which pixel signals based on electric charges outputted from the photoelectric conversion elements are outputted. A plurality of data output lines is provided for each predetermined unit pixel column. The plurality of the data output lines is equal in number to an integer multiple of the photoelectric conversion elements stacked in the stacked photoelectric converter.

The disclosure includes embodiments of a lane change timing indicator for a connected vehicle. In some embodiments, a method includes determining a time and a path for an ego vehicle to change lanes. In some embodiments, the method includes displaying, on an electronic display device of the ego vehicle, one or more graphics that depict the time and the path.

A semi-transparent sign includes a reflective display, multiple layers and a control circuit. The reflective display may be semi-transparent, have a first side subject to a thermal load, have a second side opposite the first side, and configured to generate a plurality of visible images. A heat sink layer may be attached to the first side, be transparent, and configured to carry heat energy away from the reflective display. The thermal layer may be attached to the heat sink layer, be semi-transparent, and configured to reduce an intensity of the thermal load reaching the reflective display. The warming layer may be attached to the second side, be transparent, and configured to heat the reflective display in response to an electric current. The control circuit may be configured to control the electric current to the warming layer based on a temperature signal indicating a temperature of the semi-transparent sign.

A display control apparatus comprising: a display control unit configured to display an image such that the image is superimposed on a visual field region of a driver of a vehicle; and a detection unit configured to analyze a line of sight of the driver and detect a viewpoint of the driver in the visual field region that is obtained as a result of the analysis, wherein the display control unit subjects a predetermined region in the visual field region to display control, and based on a result of determination of overlapping between the predetermined region in the visual field region and the viewpoint of the driver detected by the detection unit, if the overlapping satisfies a condition, the display control unit changes a mode of the display of the image.