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).

A system includes a wearable electronic device and a strap operatively connected to the wearable electronic device. The strap is configured to allow a user to wear the wearable electronic device on a body part. The system also includes an actuator connected to the strap, and a processor in signal communication with the wearable electronic device and the actuator. The processor is configured to receive a first signal from the wearable electronic device and send a second signal, based on the first signal, to the actuator to cause the strap to move relative to the wearable electronic device and provide a haptic effect to the user.

Particular embodiments described herein provide for an electronic device, such as a wrist worn electronic device. One particular example implementation of the electronic device may include a main housing, a main display in the main housing, a wrist strap that allows the main housing to be secured to a user such that the main display is located on top of a wrist of the user, and a secondary display located on the wrist strap, where the secondary display communicates information to the user without the user having to turn the wrist.

Particular embodiments described herein provide for an electronic device, such as a wrist worn electronic device. One particular example implementation of the electronic device may include a main housing, a main display in the main housing, a wrist strap that allows the main housing to be secured to a user such that the main display is located on top of a wrist of the user, and a secondary display located on the wrist strap, where the secondary display communicates information to the user without the user having to turn the wrist.

The present disclosure relates to a watch type mobile terminal which includes a main body, an infrared communication unit configured to generate an infrared signal, a communication unit configured to perform communication in a wireless manner, a sensing unit configured to sense an attachment of the main body to a first device, the first device configured to receive the infrared signal, and a controller configured to control the infrared communication unit to generate an infrared signal for the first device on the basis of a control signal associated with the first device, received from a second device through the communication unit, when the attachment of the main body to the first device is sensed, and configured to transmit the generated infrared signal to the first device through the infrared communication unit.

A wearable electronic device may include: a display unit comprising a display included in a body of the wearable electronic device; a touch sensor module comprising touch sensing circuitry located to surround the display unit and configured to detect a touch; and a processor configured to perform a preset operation based on a start position of the touch detected by the touch sensing circuitry and a movement direction of the touch.

An electronic device is provided that includes a housing having a first surface facing a first direction, and a second surface facing a second direction opposite to the first direction. The electronic device also includes a conductive pattern having a first conductive coil with an axis that is substantially perpendicular to the first direction or the second direction. The electronic device additionally includes a communication circuit configured to cause the first conductive coil to generate a magnetic flux. The second surface includes a first region made of a conductive material and a second region made of a nonconductive material. When viewed from the second surface, the first conductive coil is disposed mostly under the first region. The first conductive coil is configured to include a first section disposed near or on the second region to cause the magnetic flux to pass through the second region.

An optical processing apparatus and a light source luminance adjustment method adapted to detect a rotational displacement and a pressing state are provided. The optical processing apparatus includes a light source unit, a processing unit, and an image sensing unit, wherein the processing unit is electrically connected to the light source unit and the image sensing unit. The light source unit provides a beam of light. The processing unit defines a frame rate, defines a plurality of time instants within a time interval, and sets the light source unit to a luminance value at each of the time instants. A length of the time interval is shorter than the reciprocal of the frame rate. The luminance values are different and are within a range. The image sensing unit captures an image by an exposure time length at each of the time instants, wherein the exposure time lengths are the same.

An optical processing apparatus and a light source luminance adjustment method adapted to detect a rotational displacement and a pressing state are provided. The optical processing apparatus includes a light source unit, a processing unit, and an image sensing unit, wherein the processing unit is electrically connected to the light source unit and the image sensing unit. The light source unit provides a beam of light. The processing unit defines a frame rate, defines a plurality of time instants within a time interval, and sets the light source unit to a luminance value at each of the time instants. A length of the time interval is shorter than the reciprocal of the frame rate. The luminance values are different and are within a range. The image sensing unit captures an image by an exposure time length at each of the time instants, wherein the exposure time lengths are the same.

A method of an optical sensor apparatus which is to be used with a controlling device arranged for controlling an object having a long shape and flexible form of a material, includes: using a light emitting circuit to generate and output a light ray to a surface of a portion of the object; sensing the light ray reflected from the surface for multiple times to generate multiple images; detecting at least one motion image in the generated multiple images; and, determining a motion, an offset, or a rotation angle of the object, which is controlled by the thread controlling device, according to the detected at least one motion image.