A vehicle display device includes a display control unit that is configured to: display markers in positions, on a display unit, corresponding to future positions of a host vehicle which are acquired from an autonomous driving control unit that autonomously drives the host vehicle, and move display positions of the markers on the display unit in accordance with travel of the host vehicle and toward a reference position on the display unit corresponding to the host vehicle.

An automatic parking control unit comprises a recognizing section recognizing an outer world outside a vehicle, a vehicle operation control section performing an operation control on the vehicle, an automatic parking control section performing a parking operation to park the vehicle at a target parking position and a display control section synthesizing images taken by a camera group into an image of a surrounding area of the vehicle and displaying the image on an output device group. The display control section displays an image of the surrounding area of the vehicle and a vehicle body image of the vehicle with a portion of the vehicle made translucent, the portion of the vehicle making a blind area to a driver in the surrounding area of the vehicle and the portion of the vehicle is changed according to a direction in which the vehicle is running.

A vehicle display control device, which displays a predetermined image at a display region showing a foreground of a vehicle, includes a memory, and a processor connected to the memory. In a case in which a change operation that changes an advancing direction of the vehicle is planned, the processor displays at least one directional image, which indicates an advancing direction after the change, in the display region, and changes a number of the directional images during a time period until the vehicle reaches a change operation point at which the change operation is to be carried out.

A system and method for assisting drivers of vehicles are described. The systems and methods provide an extended view of the area surrounding the driver's vehicle while providing real-time object trajectory for objects and other vehicles that may enter the driver's reactionary zone. The system and methods capture images of the area surrounding the driver's vehicle and create a composite image of that area in real-time and using Augmented Reality (AR) create a 3-D overlay to warn the driver as objects or other vehicles enter the driver's reactionary zone so that a driver can make more informed driving decisions.

An information recording device acquires outside image information corresponding to an outside image obtained by photographing the outside of a moving body from the moving body; acquires autonomous driving information indicating a state of autonomous driving control of the moving body; acquires display information for simultaneously displaying at least a part of the outside image and an autonomous driving state image indicating the state of the autonomous driving control at a time of photographing the outside image, based on the outside image information and the autonomous driving information; and records the display information in a recording medium. The autonomous driving state image includes brake information indicating whether braking of the moving body is under the autonomous driving control.

A computer includes a processor and a memory, the memory storing instructions executable by the processor to collect biometric data of a vehicle user, identify a set of user-specific data from one or more stored sets of user-specific data based on the biometric data, and receive a request for a stored location. When the biometric data of the vehicle user match the stored biometric data, the instructions include instructions to display the requested location. When the biometric data of the vehicle user do not match the stored biometric data, the instructions include instructions to identify an offset location based on the requested location and a population density of the requested location and display the offset location.

Techniques are disclosed for creating and presenting a graphical user interface for display of autonomous vehicle behaviors. The techniques include determining a trajectory of a vehicle operating in a real-world environment. Sensors of the vehicle obtain sensor data representing an object in the real-world environment. A maneuver of the vehicle to avoid a collision with the object is predicted based on the sensor data and the trajectory of the vehicle. It is determined that a passenger comfort level of a passenger riding in the vehicle will decrease based on the maneuver of the vehicle. The passenger comfort level is measured by passenger sensors of the vehicle. A graphical user interface is generated including representations of the vehicle, the object, and a graphic, text, or a symbol alerting the passenger of the predicted maneuver. The graphical user interface is transmitted to a display device of the vehicle.

A navigation method, an electronic device and a readable storage medium, which relate to a field of vehicle networking technology, and in particular to a field of navigation technology. The navigation method includes: acquiring a real world image and a navigation information; converting the real world image to obtain a projection image, wherein the projection image is matched with an eyebox of at least one pair of vehicle-mounted glasses; superimposing the navigation information on the projection image to obtain a navigation image; and transmitting to the vehicle-mounted glasses the navigation image so that the navigation image is displayed by the vehicle-mounted glasses.

Devices, systems, and methods for remote deicing/anti-icing of an aircraft are described herein. One remote operator deicing/anti-icing station located in a remote location from a deicing/anti-icing rig includes a number of remote rig control components for actuation by a remote operator, wherein the remote rig control components include a remote operator user interface, located outside of a rig being at least partially controlled by the remote operator deicing/anti-icing station, the rig including a truck and a deicing/anti-icing control cabin that controls disbursement of substances to deice/anti-ice an aircraft, and a communication device that communicates instructions from the remote operator user interface and the number of remote rig control components to the rig to control at least one of the truck and the deicing/anti-icing control cabin.

An infotainment system for a motor vehicle includes a display screen positioned to be visible by a passenger of the motor vehicle. A storage arrangement stores a collection of video segments to be presented on the display screen. The storage arrangement also stores metadata in association with the video segments. A user interface receives inputs from the passenger. A sensor detects a characteristic of the passenger. A processing arrangement is communicatively coupled to each of the display screen, the collection of video segments, the user interface and the sensor. The processing arrangement selects one of the video segments to present on the display screen. The selecting of the one video segment is dependent upon inputs received from the passenger via the user interface, signals received from the sensor indicative of the characteristic of the passenger, and metadata associated with individual segments.