A virtual space experience system capable of preventing unintentional contact between players without inhibiting a sense of immersion is provided. A virtual space image determination unit 35 of a VR system S causes an image of a virtual space to be perceived by a second player to include an image in which a first avatar corresponding to a first player moves so as to generate a gap in a correspondence relationship between coordinates of the first player and coordinates of the first avatar when a trigger event is recognized, and causes the image of the virtual space to be perceived by the second player to include an image of a second avatar corresponding to the second player and a third avatar corresponding to the first player after the recognition. An avatar coordinate determination unit 34 determines coordinates of the third avatar based on the coordinates of the first player.

An electronic gaming console includes a first control device including a first button, a second control device including a second button, a tube connecting the first control device to the second control device, the tube comprising a plurality of lights within an interior of the tube, a memory; and a controller. The controller can be configured to receive one or more sets of instructions from a user device, store the sets of instructions in the memory, receive a first input from the first button and a second input from the second button; and control illumination of the plurality of lights based on at least one of the sets of instructions, and at least one of the first input or the second input.

An electronic gaming console includes a first control device including a first button, a second control device including a second button, a tube connecting the first control device to the second control device, the tube comprising a plurality of lights within an interior of the tube, a memory; and a controller. The controller can be configured to receive one or more sets of instructions from a user device, store the sets of instructions in the memory, receive a first input from the first button and a second input from the second button; and control illumination of the plurality of lights based on at least one of the sets of instructions, and at least one of the first input or the second input.

The present disclosure discloses a model loading method and apparatus for a head-mounted display device and a head-mounted display device. The method includes: obtaining a type of a target handheld device, in which the target handheld device is a handheld device connected to a current application service; determining whether the type of the target handheld device is an existing type in the head-mounted display device; obtaining, in response to the type of the target handheld device being not the existing type in the head-mounted display device, corresponding model resource data based on the type of the target handheld device; and generating, based on the model resource data, a handheld model corresponding to the target handheld device, and loading the handheld model.

A physical rehabilitation tool has a personal electronic device with a processor, a camera and a display screen. The processor is programed to illustrate a game module on the display screen. The game module includes at least a first feature and a second feature. The camera is configured to superimpose an image of a body part over the game module. Movement of the image of the body part from the first feature to the second feature requires the body part to traverse a desired range of motion.

A physical rehabilitation tool has a personal electronic device with a processor, a camera and a display screen. The processor is programed to illustrate a game module on the display screen. The game module includes at least a first feature and a second feature. The camera is configured to superimpose an image of a body part over the game module. Movement of the image of the body part from the first feature to the second feature requires the body part to traverse a desired range of motion.

A non-transitory computer readable medium storing computer executable instructions which, when executed by one or more computers, cause the one or more computers to acquire a mode of a plurality of modes in which each mode corresponding to a line of sight directed to a different object of plural objects, the mode related to a line of sight of an avatar corresponding to a motion of a delivering user wearing a head-mounted display; create, according to the mode, moving-image display data for displaying a moving image of a virtual space in which the avatar is disposed as viewed from a virtual camera; and transmit the moving-image display data to a viewing user device for display to a viewing user.

Systems, methods and apparatus for multi-realm, computer-generated reality systems are disclosed. A method for managing a multi-realm, computer-generated reality includes determining one or more variances between each activity of a first participant and a corresponding baseline activity for each of a plurality of activities associated with traversal of a managed reality system during a session, and quantifying the one or more variances to obtain a performance metric. The method includes combining at least one performance metric for each activity of the first participant to obtain a session performance measurement for the first participant.

In one embodiment, a method includes using one or more cameras of a mobile computing device to capture one or more images of a first user wearing a VR display device in a real-world environment. The mobile computing device transmits a pose of the mobile computing device with respect to the VR display device to a VR system. The mobile computing device receives from the VR system a VR rendering of a VR environment. The VR rendering is from the perspective of the mobile computing device with respect to the VR display device. The method includes segmenting the first user from the one or more images and generating, in real-time responsive to capturing the one or more images, a MR rendering of the first user in the VR environment. The MR rendering of the first user is based on a compositing of the segmented one or more images of the first user and the VR rendering.

In one embodiment, a method includes receiving sensor data of a scene captured using one or more sensors, generating (1) a number of virtual surfaces representing a number of detected planar surfaces in the scene and (2) a point cloud representing detected features of objects in the scene based on the sensor data, assigning each point in the point cloud to one or more of the number of virtual surfaces, generating occupancy volumes for each of the number of virtual surfaces based on the points assigned to the virtual surface, generating a datastore including the number of virtual surfaces, the occupancy volumes of each of the number of virtual surfaces, and a spatial relationship between the number of virtual surfaces, receiving a query, and sending a response to the query, the response including an identified subset of the plurality of virtual surfaces in the datastore that satisfy the query.