Described herein are systems and satchels, with an integrated head-mounted display, including a body with sides and a bottom forming an interior and a concavity opposite the interior, the interior and the concavity separated by the bottom and each open at one end, the concavity configured to accept a head-mounted display; and at least one reversible connector configured to reversibly retain the head-mounted display accepted in the concavity, wherein when the head-mounted display is accepted and retained in the concavity the sides are substantially flush with the head-mounted display; and a strap comprising two ends and a reversible connector at each end, the strap convertible to reversibly attach to the body to form a satchel strap or to reversibly attach to the head-mounted display to form a head-mounted display strap.

Systems and methods for operating a controlled device via an activation accessory of a wearable device that includes a moveable actuator, a sensor, and a communication element. The sensor is coupled to a controller, which has an output coupled to a control signal interface. The controller is programmed to receive and evaluate input signals from the sensor that are responsive to movements of the moveable actuator to determine whether or not they represent a command for the controlled device by assessing the input signals for a signal pattern indicative of a plurality of volitional actions of a wearer of the activation accessory. If/when the processor determines that the input signals represent the command, then it decodes the command and transmits an associated control signal to the controlled device via the control signal interface.

Various embodiments of the disclosure relate to a heat radiating structure and an electronic device including the same. According to various embodiments of the disclosure, it is possible to provide an electronic device including: a housing including a first surface facing a first direction, a second surface facing a second direction opposite to the first direction, and a third surface enclosing an internal space between the first surface and the second surface, wherein at least one portion of the third surface faces a third direction different from the first direction and the second direction, wherein a first opening is formed in the first surface, and a second opening is formed in the third surface; a substrate disposed in the internal space; an electronic component disposed on at least one surface of the substrate; and a mesh member disposed in the internal space and disposed adjacent to the first opening and the second opening.

A headset includes a thermal frame disposed within a housing. A printed circuit board is thermally coupled to the thermal frame. Heat generated by one or more electrical components on the PCB is transmitted to the thermal frame, which distributes the heat uniformly throughout the headset. The thermal frame provides a substantially rigid structural support to which components are coupled and is configured to transfer thermal energy away from the one or more electrical components of the headset and toward an environment located outside of the housing.

An image display method applied to AR glasses is disclosed. An inner frame of the AR glasses is provided with a first camera, and an outer frame of the AR glasses is provided with a second camera. The image display method comprises: detecting eye rotation information of a glasses wearer by using the first camera (S101); adjusting a shooting angle of the second camera according to the eye rotation information, and acquiring a target image collected by the second camera after adjusting the shooting angle (S102); judging whether there is a target object in the target image (S103); and if yes, displaying an image including position information of the target object via a lens of the AR glasses (S104). The object recognition accuracy of the AR glasses is improved.

A light-shielding member that moderates the contact pressure is provided. The light-shielding member reduces external light to be incident to the eyes of a user who is wearing a head-mounted display and includes an attachment portion that is attached to a housing of the head-mounted display and a light-shielding wall extending backwardly from the attachment portion. The light-shielding wall includes at least at part thereof bellows that come into contact with the periphery of the eyes of the user who is wearing the head-mounted display and are deformed to expand and contract in response to the contact pressure.

A detachable projection device, a sealing housing thereof, and a wearable apparatus are provided. The sealing housing includes a first cover, a second cover, a first waterproof and dustproof gasket having an enclosed loop-shape, and a transparent case. The first cover and the second cover respectively have two sealing edge portions corresponding in shape to each other. The second cover is detachably fastened to the first cover, and the first waterproof and dustproof gasket is gaplessly sandwiched between and abutted against the two sealing edge portions, so that the first cover, the second cover, and the first waterproof and dustproof gasket jointly define an accommodating space. The transparent case is connected to the second cover and has an insertion slot that is in spatial communication with an optical area of the accommodating space.

Augmented reality (AR) glasses may include a main housing configured to accommodate lenses of the AR glasses, with at least a portion of the main housing formed of a conductive member A sub-housing forms a leg of the AR glasses. A PCB is disposed in the sub-housing. A conductive hinge structure is configured to interconnect the main housing and the sub-housing such that the sub-housing is foldable with respect to the main housing. The conductive hinge structure is electrically connected to the PCB and the conductive member. A wireless communication circuit is disposed in the sub-housing and is configured to transmit and/or receive a signal of a predetermined frequency band based on an electrical path including the conductive hinge structure and the conductive member by directly feeding power to the conductive hinge structure. Various other embodiments identified through the specification are possible.

An optical device includes a frame supporting a lightguide, a microdisplay, and a field lens positioned therebetween that directs light from the microdisplay into a top surface of the lightguide. Four optical surfaces of the lightguide include: a curved surface where light from the microdisplay enters a top of the lightguide, curved eye-side and world-side surfaces providing total internal reflection, and a combiner surface. The eye-side surface is used twice. Once in total internal reflection, and a second time as a refractive surface when light is reflected from the combiner surface and is thereby refracted out of the lightguide and directed towards a user's eye. The field lens has a curved first surface oriented toward the microdisplay and a curved second surface oriented toward the top of the lightguide. The combiner surface combines ambient light from a world-side of the lightguide with light from the microdisplay.

An electronic device includes a lens frame accommodating a display member, a wearing member connected to the lens frame, a circuit board provided inside the wearing member, a battery provided inside the wearing member, and a connection member including a first end connected to the circuit board, a second end connected to the battery, an elastic member formed of a conductive material, and a wire at least partially surrounded by the elastic member. The battery is electrically connected to the circuit board via the elastic member and the wire.