A system to support communication and control in a welding environment is disclosed. In one embodiment the system includes an internet-of-things (IoT) technology platform configured to provide scalable, interoperable, and secure communication connections between a plurality of disparate devices within a welding environment. The system also includes a welding power source configured to communicate with the IoT technology platform. The system further includes a computerized eyewear device. The computerized eyewear device includes a control and communication circuitry configured to communicate with the welding power source via the IoT technology platform. The computerized eyewear device also includes a transparent display configured to display information received from the welding power source via the IoT technology platform while allowing a user to view a surrounding portion of the welding environment through the transparent display.

A display device according to an embodiment of the invention includes an image display unit for the left eye, an image display unit for the right eye, a main frame which supports the image display unit for the left eye and the image display unit for the right eye, and a position adjusting unit which adjusts positions of the image display unit for the left eye and the image display unit for the right eye with respect to the main frame. The position adjusting unit adjusts a gap between the image display unit for the left eye and the image display unit for the right eye, and respectively adjusts a position of the image display unit for the left eye with respect to the main frame, and a position of the image display unit for the right eye with respect to the main frame independently.

A wearable display device includes an optical device that forms a virtual image, and a support device that supports the optical device. The support device includes a fixed temple and a movable temple in a temple, which is a contact portion, and the movable temple is attached so as to be positionable further to the upper side than the fixed temple when a state of being worn is assumed.

A headset can include at least one display; virtual reality circuitry operatively coupled to the at least one display; and a display frame that includes a nosepiece coupling and a nosepiece received in part by the nosepiece coupling, where the nosepiece includes a ball, an extension, a carrier and nose pads coupled to the carrier, where the carrier is rotatable via the ball and translatable via the extension.

The present invention relates to an electronic device. More particularly, the present invention relates to an electronic device used in virtual reality (VR), augmented reality (AR), mixed reality (MR), etc. Disclosed herein is an electronic device which includes: a frame including at least one opening and worn on a human body of a user; a control unit fixed to the frame and generating an image; and a display unit fixed to the opening of the frame and showing the image to the user, in which the frame includes a front frame including the at least one opening and first and second side frames which extend in a first direction crossing the front frame at both ends of the front frame and are parallel to each other, and at least one of a first length of each of the first and second side frames and a first interval between the first side frame and the second side frame is adjustable.

A display apparatus includes: a first lens barrel in a bottomed barrel shape and including, at the bottom, a first display that displays an image; a second lens barrel in a bottomed barrel shape and including, at the bottom, a second display that displays another image; a support member elongated in an arrangement direction of the first and second lens barrels, and supporting, by passing through the first and second lens barrels in the arrangement direction, at least one of the first and second lens barrels to allow the at least one lens barrel to move in the arrangement direction; and temple parts respectively connected to two ends of the support member in the arrangement direction. The first lens barrel includes first and second sound pickup devices, the second lens barrel includes third and fourth sound pickup devices, and the temple parts respectively include fifth and sixth sound pickup devices.

An imaging apparatus for stereoscopic viewing has a frame that seats against the head of a viewer. A left-eye imaging apparatus and a right-eye imaging apparatus are supported by the frame. The frame is reshapeable in a manner that changes a relative alignment of the left-eye imaging apparatus and the right-eye imaging apparatus to accommodate different viewer head anatomies. An adjustment mechanism responsive to the reshaping of the frame restores relative alignment of the left-eye imaging apparatus and the right-eye imaging apparatus for conveying stereoscopic virtual images to the viewer.

The embodiment of the present disclosure provides an interpupillary distance adjustment assembly, VR glasses, and a VR device. The interpupillary distance adjustment assembly includes a left frame and a right frame, wherein an adjustable clip with an adjustable width is provided between the left frame and the right frame, and the adjustable clip is detachably connected to the left frame and the right frame, respectively.

An adjustable frame assembly for augmented reality eyewear. The frame assembly includes a face portion for supporting at least one waveguide that creates an eye box, a support rest for supporting the face portion on a user, and a coupling for adjusting the position of the face portion relative to the support rest. This enables movement of the waveguide eye box relative to the support rest to position the eye box in front of the wearer's eyes.

The disclosed flexible facial interface assemblies for head-mounted display systems may include a rigid support frame element and a flexible facial interface frame element. The rigid support frame element may be shaped and configured to physically support a display of a head-mounted display system in front of a user's eyes when the facial interface assembly is worn by the user. The flexible facial interface frame element may be configured to flex to conform to the user's facial features when the facial interface assembly is worn by the user. An outer periphery of the flexible facial interface frame element may be independently movable relative to an outer periphery of the rigid support frame element. Various other systems and methods are also disclosed.