An apparatus to target recipients of media content items comprises a camera, a communication interface, and a selector input device. The selector input device is communicatively coupled to the camera and the communication interface and has settings associated with groups of recipients. The groups of recipients include a first group and a second group. In response to receiving a selection of a first setting from the selector input device, the camera captures a first media content item and the communication interface transmits the first media content item to the first group. The selector input device can be a rotary wheel. To select the first setting from the plurality of settings, the user can rotate the rotary wheel to the first setting and press the rotary wheel. Other embodiments are described herein.

An improved VR headset accessory, and in particular, a case for carrying the VR headset that has advanced functionality necessary for facilitating portable maintenance and usage. For example, the accessory houses additional batteries and/or power source connections for charging the VR headset as well as ancillary devices for controlling the display of content in the VR headset to create a controlled viewing environment. The accessory also houses a communication component for sharing content with a remote server.

The present disclosure relates to modular waveguide displays including: a modular frame; a waveguide lens attached to the modular frame, where the waveguide lens in configured to be attached to the modular frame to locate one or more waveguides within the waveguide lens in front of the modular frame; and an optical engine which is configured to be attached to the modular frame, wherein, when the optical engine is attached to the modular frame, the optical engine is configured to provide image containing information to a front side of the one or more waveguides. Advantageously, a modular waveguide display allows for customization by a user. The modular waveguide display is designed to operate without such components as the optical engine when such functionality is undesired to save weight and power. Also, modular waveguide displays allow for parallel development of components such as the waveguide lens and the optical engine.

A near-eye display system including an optics module coupled with an electronics module having a controller. Wherein the optics module includes a planar waveguide operable to display virtual images, and a camera operable to capture pictures and videos. The planar waveguide coupled with the camera via the optics module, whereby a first view through the planar waveguide is oriented to be the same as a second view by the camera.

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.

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.

Systems and devices for controlling camera privacy in wearable devices are described. A camera cover can be provided that is movable between a closed position and an open position. In the closed position, the camera cover can occlude a field of view of a camera, such that the camera cannot capture meaningful data. In the open position, the camera cover can be at least partially out of the field of view of the camera, such that the camera can capture meaningful data. The camera cover can be positioned within a housing of the wearable device, and an actuator can be positioned external to the housing of the wearable device. A user can move the camera cover by moving the actuator.

Systems, apparatuses, and methods are taught that provide reconfigurable components for eyewear devices. A reconfigurable component for use in an eyewear device includes an embedded electronics system. The embedded electronics system is configured for wireless communication and for processing sensor signals. The embedded electronics system is embedded into a component of the eyewear device. A plurality of sensors is embedded into one or more of the reconfigurable component and the eyewear device. The plurality is in electrical communication with the embedded electronics system. The embedded electronic system further includes a processor. The processor is configured to receive outputs from the plurality of sensors and to determine a system control parameter from an output of at least one sensor of the plurality of sensors.

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.

A head-mountable device can include adaptable components, which move to comfortably engage the face of the user and to exclude light from an external environment. A head-mountable device can include a light seal element that includes discrete portions that rotate relative to each other and to a user. Such mobility allows the portions to be oriented with respect to corresponding regions of the face, so that an engagement surface of each portion directly engages the corresponding region of the face to maximize the surface area of contact.