A heads up display system includes a display medium in combination with a dock or support configured to receiving a portable electronic device. The display of the portable electronic device is projected by the display medium, such as in a forward direction. The vehicle dashboard or a surrounding area can have an integral dock, which can be at a top of a gauge visor, bottom of a gauge visor, is displace below vehicle gauges. In each case, an aperture may be provide to provide a path from the display of the electronic device to the display medium. In some embodiments, the heads up display system may include a dedicated display that mirrors the display of the portable electronic device, via a wired or wireless connection.

A virtual object display system includes a plurality of head-mounted displays 1 each having a virtual object acquisition unit 22 that acquires a virtual object, a display information acquisition unit 23 that acquires display information used to display the virtual object, and a display control unit 24 that causes a display unit to display the virtual object on the basis of the display information, and enables switching between of first display control for causing the virtual object to be displayed on the basis of display information acquired by each of the plurality of head-mounted displays 1 and second display control for causing the virtual object having an identical orientation to an orientation of the virtual object displayed on the basis of display information acquired by another head-mounted display 1 to be displayed.

Systems and methods are provided for discerning the intent of a device wearer primarily based on movements of the eyes. The system may be included within unobtrusive headwear that performs eye tracking and controls screen display. The system may also utilize remote eye tracking camera(s), remote displays and/or other ancillary inputs. Screen layout is optimized to facilitate the formation and reliable detection of rapid eye signals. The detection of eye signals is based on tracking physiological movements of the eye that are under voluntary control by the device wearer. The detection of eye signals results in actions that are compatible with wearable computing and a wide range of display devices.

A side head-up display system is provided. The side head-up display system has an image generator configured to emit a generated image to create a virtual image for viewing by a vehicle occupant. In some forms, a side display surface is disposed along a vehicle side of the motor vehicle, and the virtual image is viewable through the side display surface. In some versions, a controller is provided and configured to cause the generated image to be generated intermittently while the first motor vehicle is running so that the image generator is off at least part of the time while the motor vehicle is running. The controller may be configured to cause the image generator to create the generated image to show information about another vehicle outside of the motor vehicle, such as speed information and/or distance and location information.

In one implementation, a non-transitory computer-readable storage medium stores program instructions computer-executable on a computer to perform operations. The operations include presenting, on a display of an electronic device, first content representing a standard view of a physical setting depicted in image data generated by an image sensor of the electronic device. While presenting the first content, an interaction with an input device of the electronic device is detected that is indicative of a request to present an enriched view of the physical setting. In accordance with detecting the interaction, second content is formed representing the enriched view of the physical setting by applying an enrichment effect that alters or supplements the image data generated by the image sensor. The second content representing the enriched view of the physical setting is presented on the display.

Provided are a content visualizing device and method that changes positions and shapes of route guidance content and driving related content based on a distance to an adjacent object, a current driving state, and an occurrence of a driving related event.

There is provided a display device for a vehicle, the display device including: a display unit that is visible to an occupant of a vehicle; a memory; and a processor that is connected to the memory, the processor changing a content image displayed on the display unit so as to be displayed in the same direction as a direction in which a travel path of the vehicle curves.

The present patent application describes techniques for generating an enhanced electronic document that may include one or more graphical user interface (GUI) elements that comprise an interactive workflow. An electronic document is automatically processed to identify patterns within the content of the document that indicate individual content items, such as individual steps or instructions associated with a task described in the document, or individual input fields at which information is to be recorded. For each individual content item identified, a data object (e.g., a JSON object) is added to a file, which is ultimately embedded within the original document to create an enhanced electronic document. When the enhanced electronic document is presented via an appropriate document viewing application of a hands-free computing device, the content of the document is presented in combination with the interactive GUI elements so the end-user can interact with the content and GUI elements via audible (spoken) commands.

A vehicle display device includes a display that emits a display image to be projected onto a windshield provided to a vehicle, as display light, at least one reflecting mirror that is disposed on an optical path of the display light from the display to the windshield and reflects the display light, an optical sensor that detects external light (SL) incident from an opening through which an outside and an internal space are communicated with each other, a temperature sensor that detects a temperature of the display, a dimming member that is disposed on the optical path of the display light, and a controller that causes the dimming member to be switched between a state with a first transmissivity and a state with a second transmissivity smaller than the first transmissivity.

The information processing device 4 includes an acquisition unit 40A, a structural feature point extraction unit 41A, a common coordinate system transformation unit 42A, and a structural feature point integration unit 43A. The acquisition unit 40A is configured to acquire captured images Im generated by plural image acquisition devices 5 and positional relation information Ip indicative of a positional relation among the plural image acquisition device 5. The structural feature point extraction unit 41A is configured to extract, from each of the captured images Im, intra-image coordinate values Pi for structural feature points, which are structural feature points of a target structure of observation through a display device, the display device displaying a virtual object superimposed on a view. The common coordinate system transformation unit 42A is configured to convert, based on the positional relation information Ip, the intra-image coordinate values Pi for each of the structural feature points extracted from each of the captured images Im into individual coordinate values Pc indicating coordinate values in a common coordinate system which is a common three-dimensional coordinate system. The structural feature point integration unit 43A is configured to determine, for each of the structural feature points, a representative coordinate value Pcr in the common coordinate system based on the individual coordinate values Pc in the common coordinate system.