An alarm clock is provided that has a housing, one or more charging ports, an audio transducer, an alarm control device, a display, and a controller. The charging ports are mounted in a surface of the housing and provide power from a power supply to an external device. The controller receives input signals from the alarm control device and sends output signals to the audio transducer and the display. When the controller receives input signals from the alarm control device, it responds by displaying and setting a desired alarm time on the display, and by arming an alarm function. While the alarm function is armed, if a current time matches the alarm time, the controller causes the audio transducer to emit an alarm sound. When the controller receives another input signal from the alarm control device, it responds by taking the alarm time off the display, disarming the alarm function, and, if the alarm sound is being emitted, quieting the alarm sound. The alarm function remains disarmed until the controller receives yet another input signal from the alarm control device, and in response rearms the alarm function.

An alarm clock is provided that has a housing, one or more charging ports, an audio transducer, an alarm control device, a display, and a controller. The charging ports are mounted in a surface of the housing and provide power from a power supply to an external device. The controller receives input signals from the alarm control device and sends output signals to the audio transducer and the display. When the controller receives input signals from the alarm control device, it responds by displaying and setting a desired alarm time on the display, and by arming an alarm function. While the alarm function is armed, if a current time matches the alarm time, the controller causes the audio transducer to emit an alarm sound. When the controller receives another input signal from the alarm control device, it responds by taking the alarm time off the display, disarming the alarm function, and, if the alarm sound is being emitted, quieting the alarm sound. The alarm function remains disarmed until the controller receives yet another input signal from the alarm control device, and in response rearms the alarm function.

The present invention relates to a watch-type electronic device and a manufacturing method therefor, the electronic device comprising: a main body including a display unit; a frame provided to the main body and having an upper surface, a lower surface formed to face the upper surface, and side surfaces formed so as to cover the upper surface and the lower surface; and a touch sensor formed on the frame, wherein the upper surface comprises: a planar part formed to be parallel to the lower surface; and a curved part formed so as to be inclined toward the end of the lower surface from an end portion of the planar part, the touch sensor is formed on the curved part so as to be spaced apart from the display unit, the display unit is placed on the planar part, the frame includes a laser direct structuring (LDS) material, and the touch sensor is formed of a metal thin film.

An electronic timepiece, including: a first operation unit; a first communication unit; and a first control unit, wherein one of the plurality of the operation receiving units is a function switching operation receiving unit, i) when a first input signal is input, the first control unit assigns the operation receiving units including the function switching operation receiving unit as external device operation receiving units according to predetermined operation processing to be executed by the external device, ii) when an input operation to the operation receiving units is detected, the first control unit transmits an operation request according to the operation processing corresponding to the input operation to the external device via the first communication unit, and iii) when a second input signal is input, the first control unit ends assignment of the operation receiving units as the external device operation receiving units.

An electronic timepiece, including: a first operation unit; a first communication unit; and a first control unit, wherein one of the plurality of the operation receiving units is a function switching operation receiving unit, i) when a first input signal is input, the first control unit assigns the operation receiving units including the function switching operation receiving unit as external device operation receiving units according to predetermined operation processing to be executed by the external device, ii) when an input operation to the operation receiving units is detected, the first control unit transmits an operation request according to the operation processing corresponding to the input operation to the external device via the first communication unit, and iii) when a second input signal is input, the first control unit ends assignment of the operation receiving units as the external device operation receiving units.

A system has a first electronic device with optical sensor, digital radio transceiver, and processor with firmware; this device is typically portable or wearable. The system also has a computerized device with a display, a second digital radio transceiver, and a second processor with firmware. The first and computerized devices are configured to set up a digital radio link when in radio range. The second processor uses a spot on the display to optically transmit a digital message including a secret such as an encryption key or subkey and/or an authentication code adapted for authenticating an encrypting the radio link. The first device receives the digital message via its optical sensor, and uses the digital message to validate and establish encryption on the radio link. In embodiments, the system determines a location of the first device on the display and positions the transmission spot at the determined location.

Disclosed are a mobile terminal capable of implementing an always-on function with a lower power, based on a motion, and a motion-based low power implementing method thereof. The method includes sensing a motion of a user by using an acceleration sensor in a low-power always-on that only the acceleration sensor is activated; a selectively activating an always-on function according to the sensed motion and deactivating the always-on function when no motion is sensed in an always-on state and automatically entering to the low-power always-on function.

Various example embodiments of the present disclosure provide an electronic device including: a housing including a substantially circular opening and a first surface facing in a first direction; a wearing structure configured to enable the electronic device to be removably worn on a part of a human body and connected to the housing; a display disposed in the opening; an annulus installed on the first surface and configured to be rotatable along a periphery of the opining, the annulus including a second surface facing a second direction opposite the first direction; at least one spacer interposed between a part of the first surface and the second surface of the annulus; and a circuit configured to detect a rotation of the annular member and to change the display at least in part based on the rotation.

Various example embodiments of the present disclosure provide an electronic device including: a housing including a substantially circular opening and a first surface facing in a first direction; a wearing structure configured to enable the electronic device to be removably worn on a part of a human body and connected to the housing; a display disposed in the opening; an annulus installed on the first surface and configured to be rotatable along a periphery of the opining, the annulus including a second surface facing a second direction opposite the first direction; at least one spacer interposed between a part of the first surface and the second surface of the annulus; and a circuit configured to detect a rotation of the annular member and to change the display at least in part based on the rotation.

Disclosed is an application interface that takes into account the user's gaze direction relative to who is speaking in an interactive multi-participant environment where audio-based contextual information and/or visual-based semantic information is being presented. Among these various implementations, two different types of microphone array devices (MADs) may be used. The first type of MAD is a steerable microphone array (a.k.a. a steerable array) which is worn by a user in a known orientation with regard to the user's eyes, and wherein multiple users may each wear a steerable array. The second type of MAD is a fixed-location microphone array (a.k.a. a fixed array) which is placed in the same acoustic space as the users (one or more of which are using steerable arrays).