The present invention relates to an eyewear device comprising a system for alerting of a need of an eye examination and/or a change of frame and/or a change of lens of the eyewear device, in order to provide the best visual correction and comfort. The invention also relates to a process for monitoring the need of an eye examination and/or a change of frame and/or lens of an eyewear device, comprising using an eyewear device according to the invention, and to a process for manufacturing an eyewear device according to the invention.

A method of manufacturing a button-enabled housing assembly includes preforming a composite button component or insert having an elastically flexible button membrane that is mounted on a rigid frame, and thereafter molding a housing over the button insert. The composite button insert is formed in a co-molding operation and can include a rigid island in the flexible button membrane for supporting a cosmetic keycap.

Smart glasses comprise a glasses frame. The smart glasses further comprise a pair of glasses legs connected to two lateral portions of the glasses frame respectively, each of the glasses legs having a first end and a second end, wherein the second end of each of the glasses legs bends inwardly to form a first arc portion. In addition, the smart glasses further comprise a pair of clamping members each disposed at one of the glasses legs, wherein each of the clamping members comprises an elastic clamping element, said elastic clamping element being disposed at the inner side of said second end, wherein said elastic clamping element having a free end that bends inwardly to form a second arc portion.

Current invention propounds a novel active contact lens device, system, as well as, a corresponding method of operation of such contact lens with an embedded orientation determination mechanism. The system, furthermore, utilizes an onboard, integrated orientation and gaze sensing component to determine eye orientation, in 3D (x,y,z) dimension corresponding to the direction of eye gaze, or in 2D (x,y) dimension, denoting orientation relative to the horizontal or vertical line of the eye, also known as, the horizontal or vertical meridian of the eye. Such a system may be used to provide rich augmented reality (AR) or virtual reality (VR) experience to its user/wearer. Hereby, we propose to incorporate several electronic, electro-optical, optical or other types of components into the contact lens substrate and interconnect them to form such an innovative AR/VR enabled active contact lens system. The system proffered herein, may incorporate and integrate a number of the following components: an integrated orientation sensing module, a positioning module (a location determination module—for example GPS sensor), an integrated substantially transparent, or semi-transparent, or non-transparent display device, a source of electric power, a communication component, a processing component, and an audio output device. Some constituent modules may be integrated into the lens substrate and some may be located remotely and accessible via wireless communication channel. The smart contact lens with an embedded orientation module may be used to implement a variety of reactive, adaptive, predictive, behavior monitoring and analyzing systems.

An electronic case for electronic spectacles may include a base comprising a cavity formed therein. A first spectacle retention device may be located within the cavity. The first spectacle retention device may be configured to retain spectacles. An electrical control system may be included. An electrical connector may be configured to couple the electrical control system in electronic communication with the spectacles.

An eyewear with a pair of light emitting diodes (LED) matrices is an apparatus that enhances the aesthetic appeal of the eyewear by illuminating different patterns and letterings with the pair of LED matrices. A left lens and a right lens each have an LED matrix, which traverse through and protrude out of their respective lens. Both LED matrices are electronically connected to a programmable microcontroller, which is able to turn on/off each individual LED in order to create the patterns and letterings on the LED matrices. The microphone and VU meter also allows the LED matrices to display patterns and lettering that relate to the music or sounds around the apparatus. Each individual LED for both LED matrices are properly spaced apart from each other so that visibility is not significantly reduced while wearing the apparatus.

A wearable electronic device is provided. The wearable electronic device includes a lens frame configured to accommodate a display member and including a first end and a second end opposite to the first end, a hinge structure including first and second hinge structures connected respectively to the first and second ends, a wearing member including a first and second wearing members connected respectively to the first hinge and second hinge structures, the first wearing member or the second wearing member being configured to move with respect to the lens frame, a battery disposed in the first wearing member, a circuit board disposed in the first wearing member and including electrodes, and a charging terminal structure disposed in the first wearing member and including charging pads exposable to an outside and a connecting member disposed in the first wearing member and configured to electrically connect the charging pads and the electrodes.

A pair of eyeglasses has a frame and lenses mounted on the frame. A computer processor is mounted on eyeglasses together with a plurality of cameras and a digital projection system. IR sensors and/or dual zoom cameras may also be mounted on the glasses and configured to track the movement of the user's hand.

A retinal display projection device comprising a micro-projection component (2) arranged for projecting an image directly onto the retina of a user wearing the device, characterized in that said micro-projection component is arranged for projecting an image outside of the normal field of view of said user.

A contact lens having a cap, core, and base forming three layers to allow for the contact lens to be thick enough to accommodate a payload, while ensuring sufficient oxygenation of the wearer's eye. The cap and base are each a thin layer of gas-permeable material, each shaped to form an air gap between them and the core. The two air gaps are connected by air passages that traverse the core. Oxygen from an outside environment passes through the gas-permeable cap to reach the outer air gap, through the air passages to the inner air gap, and through the gas-permeable base to reach the cornea of the wearer's eye. The cap may be annular in form, having a center hole such that the cap does not extend over the central zone of the core, reducing a thickness of the contact lens.