The invention concerns an augmented vision system (1) comprising: a displaying device (3) comprising: a fixing element (31) for coupling the displaying device (3) to a head-mountable component (90) configured to be positioned in front of a 5 face (102) of a user (100), and a display body (32) being coupled to said fixing element (31) by means of a pivoting link (321, 322, 323) providing a rotation of the display body with respect to the fixing element around a rotational axis (38); the display body (32) comprising 10 a display (33) configured to display thermal data and/or images provided by a thermal sensing device (2); and a first surface portion (325) configured to enter in contact with a forehead of a user, when said head-mountable component (90) is positioned in front of the face of the user, so as to rotate the display 15 body (32) to a predefined angular positioning (381) around the rotational axis (38).

The present disclosure proposes an information processing device, an information processing method and a program, which are capable of, while virtual reality content is displayed, informing a user of positional relationship between the user and a boundary region of a space in which the user can act in the real space. The information processing device comprising: an obtaining unit that obtains body information of a user; and an output control unit that, while virtual reality content is displayed by a display unit, causes a sign indicating positional relationship between the user and a boundary region of a second real space in which the user can act in a first real space in which the user is located, the boundary region having been determined on the basis of the body information of the user, to be displayed with the sign superimposed on the content.

The present invention relates to an apparatus for displaying display information according to a driving environment and a method thereof. The apparatus for displaying display information according to the driving environment according to the present invention includes an input unit receiving driving environment information, a memory in which a program for controlling internal and external displays of a vehicle according to a driving environment is stored, and a processor executing the program, wherein the processor controls to select and project display information according to the driving environment information in an internal screen area and an external screen area according to preset partitioning.

Apparatuses and methods are disclosed for a wearable proximity detection system. In one embodiment, a wearable device configured to be worn by a wearer includes a first energy source configured to transmit energy; a sensor configured to detect energy from a proximate, second energy source of a compatible, second wearable device; and processing circuitry in communication with the first energy source and the sensor, the processing circuitry configured to use the energy detected by the sensor to determine a predetermined identifying characteristic associated to a second wearer of the second wearable device. In one embodiment, a method includes transmitting, via a first energy source, energy; detecting, via a sensor, energy from a proximate, second energy source of a compatible, second wearable device; and using, via processing circuitry, the energy detected by the sensor to determine a predetermined identifying characteristic associated to a second wearer of the second wearable device.

A head-mounted device may have a head-mounted housing. A radar sensor may be mounted in the housing. The head-mounted housing may have rear-facing displays that display images for a user. The images are viewable from eye boxes while the head-mounted device is being worn by the user. A forward-facing camera may capture real-world image content. The rear-facing displays may be used to display captured real-world image content merged with computer-generated image content. The forward-facing camera and the radar sensor may be mounted under inactive display borders of a forward-facing display. The radar sensor may have a horizontal array of patch antenna elements configured to form a phased antenna array. Communications circuitry in the head-mounted device may use the phased antenna array to transmit and receive wireless communications signals.

An information presentation apparatus includes an out-of-vehicle risk detection section that is configured to detect an out-of-vehicle risk object, a gaze detection section that is configured to detect a gaze direction of a driver of the vehicle, a recognition determination section that is configured to determine whether the out-of-vehicle risk object is recognized by the driver based on a detection result by the out-of-vehicle risk detection section and a detection result by the gaze detection section, and an information presentation section that is configured to present, to the driver, out-of-vehicle risk information regarding the out-of-vehicle risk object in a presentation mode. The information presentation section is further configured to change the presentation mode depending on whether the out-of-vehicle risk object is recognized by the driver based on a determination result by the recognition determination section.

A wearable heads-up display includes a power source, laser sources, and a lightguide. A photodetector is positioned to detect an intensity of a test light emitted at a perimeter of the lightguide from an optical path within the lightguide. A laser safety circuit provides a control to reduce or shut off a supply of electrical power from the power source to the laser sources in response to an output signal from the photodetector indicating that the detected intensity is below a threshold.

Systems, methods, and non-transitory computer readable media configured for modifying the display of virtual objects docked to a movable input device are provided. In one implementation, the computer readable medium may be configured to receive image data from an image sensor, the image data representing an input device placed at a first location on a supporting surface. At least one processor may generate a presentation of at least one virtual object in proximity to the first location. Operations may include docking the at least one virtual object to the input device. The processor may determine that the input device is in a second location on the support surface. The virtual object presentation may be modified based on the second location. Operations may further include determining that the input device is in a third location removed from the support surface and modifying the virtual object presentation accordingly.

An integrated computational interface device may include a portable housing having a key region and a non-key region; a keyboard associated with the key region of the housing; and a holder associated with the non-key region of the housing. The holder may be configured for selective engagement with and disengagement from the wearable extended reality appliance, such that when the wearable extended reality appliance is selectively engaged with the housing via the holder, the wearable extended reality appliance is transportable with the housing.

An integrated computational interface device may include a portable housing having a key region and a non-key region; a keyboard associated with the key region of the housing; and a holder associated with the non-key region of the housing. The holder may be configured for selective engagement with and disengagement from the wearable extended reality appliance, such that when the wearable extended reality appliance is selectively engaged with the housing via the holder, the wearable extended reality appliance is transportable with the housing.