A method of displaying images on an immersive display. The method includes receiving information from an external sensor or input device of the immersive display, based on the information received, detecting an object that conflicts with a virtual reality space, adjusting at least one dimension of virtual reality space to provide an adjusted virtual reality for display on the immersive display to accommodate for the object, and displaying the adjusted virtual reality on the display of the immersive display.

A method of providing image includes obtaining at least one first image of a surrounding area (52) from a first camera (26, 33, 38A, 38B, 40A, and 40B). At least one second image of the surrounding area (52) is obtained from a second camera (26, 33, 38A, 38B, 40A, and 40B). The at least one first image is fused with the at least one second image to generate a three-dimensional model (51) of the surrounding area (52). A first image (54A) of the three dimensional model is provided to a display by determining a first position of an operator. A second image (54B) of the three-dimensional model is provided to the display by determining when the operator is in a second position to simulate motion parallax.

According to various implementations, a method is performed at an electronic device including one or more processors, a non-transitory memory, and a display. The method includes displaying, on the display, a virtual agent that is associated with a first viewing frustum. The first viewing frustum includes a user avatar associated with a user, and the user avatar includes a visual representation of one or more eyes. The method includes, while displaying the virtual agent associated with the first viewing frustum, obtaining eye tracking data that is indicative of eye behavior associated with an eye of the user, updating the visual representation of one or more eyes based on the eye behavior, and directing the virtual agent to perform an action based on the updating and scene information associated with the electronic device.

Methods and systems are provided for generating augmented reality (AR) scenes where the AR scenes can be adjusted to modify at least part of an image of the physical features of a user to produce a virtual mesh of the physical features. The method includes generating an augmented reality (AR) scene for rendering on a display for a user wearing AR glasses, the AR scene includes a real-world space and virtual objects overlaid in the real-world space. The method includes analyzing a field of view into the AR scene from the AR glasses; the analyzing is configured to detect images of physical features of the user when the field of view is directed toward at least part of said physical features of the user. The method includes adjusting the AR scene, in substantial real-time, to modify at least part of the images of the physical features of the user when the physical features of the user are detected to be in the AR scene as viewed from the field of view of the AR glasses, wherein said modifying includes detecting depth data and original texture data from said physical features to produce a virtual mesh of said physical features; the virtual mesh is changed in size and shape and rendered using modified texture data that blends with said original texture data. In one embodiment, the modified physical features of the user appear to the user when viewed via the AR glasses as existing in the real-world space. In this way, when the physical features of a user are detected to be in the AR scene, the physical features are augment in the AR scene which can result in the self-perception of the user improving which in turn can provide the user with confidence to overcome challenging tasks or obstacles during the gameplay of the user.

An electronic device is provided. The electronic device includes a display member including at least one glass, a frame supporting at least a portion of the display member, and a leg member coupled to at least one side of the frame. The leg member includes a first structure, a second structure to be coupled with the first structure, a speaker disposed in a space between the first structure and the second structure, a printed circuit board disposed in the space, and a rib included in at least one of the first structure or the second structure and accommodating the printed circuit board. A rear surface of the speaker may face a resonance space between the first structure and the second structure, and the resonance space may include the space the printed circuit board is disposed in, and may be connected to at least one ventilation hole formed in at least one region of the rib so as to be connected to an outside of the leg member.

An information processing system includes a device causing a user to see visual information in which a virtual object is superimposed onto information about a real space, an acquirer that acquires a position of a real object existing in the real space, and a processor configured to move the virtual object in a direction away from the real object in a case where the real object is positioned inside a predetermined range from the device.

A wireless position tracking device, a display system, and a wearable device are provided. The wireless position tracking device includes a rigid body, point light sources, a motion sensor, and a wireless transmission module. The rigid body has an inner concave surface, a head, a connecting portion, and a tail. The connecting portion connects the head and tail. The point light sources are fixed to positions outside the inner concave surface. The motion sensor locates in the rigid body for sensing a motion thereof and generating motion information. The wireless transmission module locates in the rigid body and electrically connects the motion sensor for wirelessly transmitting the motion information to the head-mounted device. An image capturing module of the head-mounted device captures a pattern formed by the point light sources. The head-mounted device calculates a relative position of the wireless position tracking device according to the pattern and motion information.

A novel display apparatus is provided. The display apparatus includes a first layer including a plurality of pixel circuits, a second layer provided over the first layer, a plurality of optical lenses provided over the second layer, a display region, and a plurality of light-receiving regions. The display region includes a first pixel circuit provided in the first layer and a light-emitting device provided in the second layer. The light-receiving region includes a second pixel circuit provided in the first layer and a light-receiving device provided in the second layer. The plurality of light-receiving regions are provided around the display region. The optical lens is provided at a position overlapping with the light-receiving region.

A head-mountable device can include modules that provide fit adjustment capabilities when assembled together. By providing a head-mountable device with modular features, certain modules can provide fit adjustment capabilities without requiring other modules to be custom designed or available in a wide variety of sizes and/or shapes. The head-mountable device and/or other electronic devices can be operated to guide a user to select the optimal light seal module for use with an HMD module. For example, the head-mountable device or another device can include sensors for detecting features of the user's face, forces distributed on the face when worn, and/or entry of light from an external environment.

While head-mountable devices can provide immersive experiences, a user wearing a head-mountable device can also benefit from activities that include body motion and promote the user's health. Because such activities may not be intrinsically necessary to the operation of head-mountable devices, it can be beneficial to provide additional or modified operations that allow a user to continue operation of a head-mountable device while performing the desired body motions. The head-mountable device can detect movement and/or stasis of the user and determine whether motion would be recommended. Upon determining that motion, an additional motion, or a different motion would be beneficial, the head-mountable device can provide an output to the user that promote such motions. The output can include a notification to the user and/or a modification of the user interface that encourages the user to move in a particular way.