Systems and methods described herein provide augmented reality images to an operator of a machine. A pose of an augmented reality device relative to a cab of the machine is determined using image information. A pose of the augmented reality device in a real world coordinate frame is determined using a pose of the machine in the real world coordinate frame and the pose of the augmented reality device relative to the cab of the machine. Digital content is provided on one or more displays of the augmented reality device. The digital content is arranged on the one or more displays based on the pose of the augmented reality device in the real world coordinate frame.

A head-up display system mounted on a vehicle, the system including: a head-up display device that displays an image in front of the vehicle; and a forward sensing device that detects a forward object of the vehicle, the head-up display device including an image data generation unit, and an image display unit, the image data generated by the image data generation unit including a constantly displayed object, and a real scene overlaid object, a gyro sensor being installed in the vehicle, the image data generation unit performing pitching correction on a display position of an object to be displayed, based on angular velocity information for two axial directions, and in a case where the vehicle travels on a curve in an inclined state, the pitching correction being suppressed or stopped, and a brightness of display of the real scene overlaid object being reduced or stopped.

In one example, a method performed by a processing system includes controlling a first device in a first location to project a virtual presences in a current field of view of a subscriber of a virtual presence projection service, computing a moving trajectory of the subscriber from the first location to a second location, identifying a second device that is located along the moving trajectory, wherein the second device includes a second set of resources for projecting virtual presences, and wherein the second device is registered with the virtual presence projection service to lend the second set of resources to subscribers of the virtual presence projection service, and controlling the second device to project the virtual presence in the current field of view of the subscriber when the subscriber is no longer within range of the first device but is within range of the second device.

Provided is a head-up display device which can stably display a virtual image viewed so as to be stuck to a road surface, during traveling of a vehicle. A head-up display device according to the present invention is provided with a display means for projecting display light to a front window shield provided to a vehicle, and generating and displaying a virtual image, formed by the display light reflected at the front window shield, so as to be superposed on an actual scene seen through the front window shield. At least a part of a virtual image display region in which the virtual image is displayed is positioned below a road surface on which the vehicle travels.

Disclosed is an electronic device. The electronic device includes: a display; a communicator comprising a circuitry, for obtaining, from an external device, an image captured by the external device and information about at least one among an acceleration and angular velocity of the external device, the acceleration and angular velocity being measured while capturing an image; and a processor for identifying a degree of movement of the external device per a preset unit time period based on the obtained information, and controlling the display to display the image with an adjusted field of view (FOV) based on the degree of movement.

In displaying content superposed in a visual field of a vehicle occupant by a display device worn on the head of the vehicle occupant, vehicle regions are specified on which content must not be superposed. Alternatively, only content that is redundant with respect to content currently displayed within the vehicle regions may be superposed on the restricted vehicle regions.

A relative movement of a head-wearable electronic display device is determined with respect to a vehicle interior of a vehicle by way of a recording device arranged on the electronic display device and a virtual perspective of a wearer of the electronic display device is adapted to virtual content according to the determined relative movement. A recording range of the recording device is limited to the vehicle interior in order to eliminate distortions, resulting from a relative movement of the vehicle with respect to the vehicle surroundings, with regard to the recording of the relative movement of the electronic display device with respect to the vehicle interior.

A display system including a display device and a light combining device is provided. The display device includes a first display region and a second display region. The light combining device has a first surface and a second surface opposite to the first surface. At least one part of a first light beam from the first display region is reflected by the first surface to an observing region so as to form a first virtual image. At least one part of a second light beam from the second display region penetrates through the first surface, is reflected by the second surface, penetrates through the first surface again, and is transmitted to the observing region in sequence, so as to form a second virtual image.

A construction machine for building or finishing a road, such as a road finisher, comprises at least a working equipment, a display unit and a plurality of sensors. Each sensor is adapted to measure a value of an operating parameter of the construction machine. The sensors are adapted to output data corresponding to the measured values to the display unit, and the display unit is adapted to output a representation of at least a part of the construction machine together with the measured values of the operating parameters.

A user interface apparatus for a vehicle includes: an interface unit; a display unit configured to project an augmented reality (AR) graphic object onto a screen; at least one processor; and a computer-readable medium coupled to the at least one processor having stored thereon instructions which, when executed by the at least one processor, causes the at least one processor to perform operations including: acquiring, through the interface unit, front view image information and vehicle motion information; based on the front view image information, generating the AR graphic object; and based on the vehicle motion information, warping the AR graphic object.