An electronic device (eyeglasses-type wireless communication device) to be worn by a user includes a wearing section to be worn by the user and an extending section formed in the wearing section and disposed in a direction extending away from the user when the wearing section is worn on the user's head. A first antenna is formed in the extending section.

An electronic apparatus capable of reducing SAR and, simultaneously, performing a radio communication in an excellent manner is provided. To that end, an electronic apparatus to be worn on the user's head for use includes lenses positioned in front of the user's eyes when the electronic device is worn on the user's head and an array antenna configured with a plurality of antennas formed on surfaces of the lenses.

Voice data communication is performed appropriately depending on the purposes of use. Provided is a wearable device including a microphone (172), a speaker (174), an input voice data acquisition unit (510) configured to acquire input voice data from the microphone (174), an output voice data providing unit (520) configured to provide output voice data to the speaker (172), a communication unit (530) configured to perform communication sessions for allowing the input voice data and the output voice data to be transmitted and received in accordance with a hands-free profile of Bluetooth between the communication unit and a smartphone (200), and a controller (540) configured to invalidate a session triggered by the smartphone (200) among the communication sessions.

Representative Drawing

FIG. 3

A client device, such as a mobile phone or a mobile phone accessory (e.g., phone case), is provided that receives and transmits data (e.g., a social media code) via light wave communication. The light wave communication may comprise structured light (e.g., projected light patterns). The client device may include a lightbox comprised of LEDs located on a back face of the client device.

A unique input mechanism for controlling several operations of an electronic device is provided. Using the unique input mechanism, which may be the single input mechanism for providing user inputs to the electronic device, a user may provide different inputs or combinations of inputs to control different operations based on the current mode or capacity of the electronic device. For example, a single, short click of a button may control a media operation (e.g., play/pause) in a media mode, and the same input may control a telephony operation (e.g., initiate/terminate call) in a telephony mode. In some embodiments, different inputs may be associated with different types of operations. The unique input mechanism may include, for example, a button, a switch, a key, or an actuator.

A wearable camera apparatus for taking photographs and videos is provided. The wearable camera apparatus comprises a camera housing and a camera mounted within the camera housing. A lens is mounted on the camera housing with the lens being in visual communication with the camera. A power button is mounted to the camera housing with the power button alternatingly depressible to power the camera on and to power the camera off. A selecting mechanism selects between photographs and videos. A mounting system is secured to the camera housing for releasably securing the camera housing to an object. The camera providing a simple and accessible means of capturing pictures and video.

A wireless audio device tethering system is provided for including an intermediary device having at least one wireless transceiver that is configured to establish a first wireless connection with a first wireless audio device and a second wireless connection with a second wireless audio device. The intermediary device is also configured to receive a unique identifier from the second wireless audio device and to transmit the unique identifier to the first wireless audio device in order to initiate wireless tethering between the first and second wireless audio device. Once tethering has been initiated, wireless audio signals can be streamed to the first wireless audio device and then re-streamed to the second wireless audio device.

In one embodiment, an aviation communication headset includes, but is not limited to, at least one microphone; one or more speakers; one or more docks configured to interface with one or more eyepieces; and at least one control unit operable to perform operations including at least: detecting a presence of one or more eyepieces at the one or more docks; and outputting aviation flight information via the one or more docks for display on the one or more eyepieces.

Systems, methods, devices, computer readable media, and other various embodiments are described for location management processes in wearable electronic devices. Performance of such devices is improved with reduced time to first fix of location operations in conjunction with low-power operations. In one embodiment, low-power circuitry manages high-speed circuitry and location circuitry to provide location assistance data from the high-speed circuitry to the low-power circuitry automatically on initiation of location fix operations as the high-speed circuitry and location circuitry are booted from low-power states. In some embodiments, the high-speed circuitry is returned to a low-power state prior to completion of a location fix and after capture of content associated with initiation of the location fix. In some embodiments, high-speed circuitry is booted after completion of a location fix to update location data associated with content.

Embodiments describe a magnetic securing component including a set of magnets positioned laterally adjacent to one another and having a curved top surface defined by individual curved top surfaces of each magnet in the set of magnets. The set of magnets includes: first and second magnets positioned laterally adjacent to one another, where the first and second magnets each have a polarity that is oriented parallel to a vertical dimension; and third and fourth magnets laterally positioned from the first and second magnets, where the third magnet is positioned adjacent to the first magnet and the fourth magnet is positioned adjacent to the second magnet, the third and fourth magnets each having a magnetic polarity that is oriented at an angle with respect to the vertical dimension.