A head-up display device for a transportation vehicle and a method, a device and a computer-readable recording medium with instructions for controlling a display of a head-up display device for a transportation vehicle. A road course ahead of the transportation vehicle is determined and the contents shown by the head-up display device are then displaced according to the road course that was determined.

One embodiment provides a method, including: identifying a user of a wearable device within an environment; determining a security level of the user for the environment; generating, based upon the determined security level of the user, a navigational path within the environment; displaying, on a display of the wearable device, the generated navigational path on the wearable device of the user; and tracking the user while moving along within the environment. Other aspects are described and claimed.

A display device includes a processing circuit and a display. The processing circuit obtains an ambient temperature of a gyro sensor, obtains a sensitivity associated with a temperature range including the ambient temperature, corrects an angular velocity of the gyro sensor in accordance with the sensitivity, estimates a first estimated vehicle orientation based on the angular velocity corrected, estimates a second estimated vehicle orientation based on the angular velocity detected by the gyro sensor, derives a third estimated vehicle orientation by correcting the first estimated vehicle orientation using a position and a speed of vehicle, and updates the sensitivity of the temperature range using a calculated sensitivity that is based on the second estimated vehicle orientation and the third estimated vehicle orientation. The display displays an image that is in accordance with the third estimated vehicle orientation.

Embodiments of the present invention provide an Augmented Reality (AR) method and apparatus for driving assistance, which are applied in the technical field of AR. The method comprises the steps of: determining, based on information acquired during the driving process, driving assistance information, and displaying virtual three dimensional (3D) display information corresponding to the driving assistance information. In the present invention, the AR technology can be applied in the vehicle travelling process to assist a driver in better mastering driving information in the vehicle travelling process, and the user experience can be improved.

A vehicle is provided. The vehicle includes: a global navigation satellite system (GNSS) receiver configured to receive a signal from a GNSS; a guide lamp installed on a front portion of the vehicle; and a controller electrically connected to the GNSS receiver and the guide lamp, wherein the controller is configured to: identify an entry of the vehicle into a parking lot based on a GNSS signal acquired by the GNSS receiver; and control the guide lamp to display a light line representing a path to be travelled by the vehicle and an area to be occupied by the vehicle on a road ahead of the vehicle based on the entry of the vehicle into the parking lot.

An in-vehicle information display apparatus and a method of controlling the same output outputting various pieces of information using image output devices disposed on a rear surface of a protrusion type information display apparatus. The protrusion type information display apparatus applied to a vehicle includes an output region determination unit configured to, upon detecting that an event occurs, determine an image corresponding to the event and an output region, among a plurality of regions of a windshield, a screen correction unit configured to correct the determined image to match the determined output region, and a projector unit disposed on a rear surface opposite to a front surface on which a display is disposed and configured to project the corrected image onto the determined output region.

A head up display arrangement for a motor vehicle includes a global positioning system module emitting geographic location coordinates associated with the motor vehicle. A database includes lane marking location data stored in association with corresponding geographic location coordinates. An electronic processing device is communicatively coupled to the global positioning system module and to the database. The electronic processing device receives the geographic location coordinates and retrieves from the database lane marking location data stored in association with the received geographic location coordinates. The electronic processing device transmits the retrieved lane marking location data. A head up display is communicatively coupled to the electronic processing device and receives the transmitted lane marking location data. The head up display displays virtual lane markings dependent upon the received lane marking location data.

Provided is a system for controlling transparency of a vehicle window according to recognition of a gaze of a driver, the system including: an electrochromic film provided on a vehicle window and configured to control transparency according to a transparency control signal; a gaze detector configured to detect a gaze of a driver; a gaze determiner configured to determine whether the gaze of the driver is directed at the vehicle window on which the electrochromic film is located; and a controller configured to transmit the transparency control signal according to the determined gaze of the driver.

An in-car cloud VR device includes: a GIS information acquisition unit that detects a location of a vehicle through a GPS sensor installed in a traveling vehicle and acquires the GIS information near the vehicle; an thing information acquisition unit that collects videos around the vehicle through at least one camera sensor installed in the vehicle and acquires surrounding thing information around the vehicle; a movement information acquisition unit that acquires movement information of a user in the vehicle through at least one gyro sensor; and an FOV video determination unit that determines a first FOV video based on the GIS information, updates the first FOV video based on the surrounding thing information, and determines a second FOV video within the first FOV video based on the movement information of the user.

A HUD device that allows an occupant of a moving body to view a virtual image by projecting an image on a display medium includes a display item information acquisition unit that acquires display item information showing position and display content of display item, a travel information acquisition unit that acquires travel information indicating position of the moving body at predetermined time intervals, and a state information acquisition unit that acquires state information indicating state of the moving body, and specifies at display timings display position on the basis of position indicated by display item information and position indicated by travel information acquired last. The HUD device includes a display controller that specifies display position on the basis of position indicated by display item information and correction position obtained by correcting position indicated by travel information acquired last in accordance with state indicated by state information and displays an image showing display content indicated by display item information at the specified display position on the display medium when a predetermined condition is satisfied.