A method in an electronic device, the method includes projecting infrared (“IR”) light from a plurality of light emitting diodes (“LEDs”) disposed proximate to the perimeter of the electronic device, detecting, by a sensor, IR light originating from at least two of the plurality of LEDs reflected from off of a person, and carrying out a function based on the relative strength of the detected IR light from the LEDs.

The present disclosure provides a fingerprint detecting device, including: a photosensitive sensing component, a first electrode of which is coupled to a reference signal terminal, a second electrode of which is coupled to a pull-down node; a reset component, coupled to a reset terminal and the pull-down node, configured to reset the pull-down node in a first stage; a voltage output component, coupled to the pull-down node, a selection terminal and an output terminal of the fingerprint detecting device, configured to output a voltage signal to the output terminal of the fingerprint detecting device according to the potential of the pull-down node, the first stage to a second stage, an amount of change in a voltage signal output to the output terminal of the fingerprint detecting device is positively correlated with an amount of change in the potential of the pull-down node.

A rear seat entertainment (RSE) remote controller and a method thereof are provided. The RSE remote controller includes a sensing module provided with a sensing surface including a biometric sensor and configured to sense a biometric signal and a finger gesture of a user, a main processor configured to provide an AC current to the sensing module, and a short-range wireless communication module configured to transmit one of the sensed biometric signal or the sensed finger gesture to a rear seat monitor through wireless communication depending on an operation mode.

A rear seat entertainment (RSE) remote controller and a method thereof are provided. The RSE remote controller includes a sensing module provided with a sensing surface including a biometric sensor and configured to sense a biometric signal and a finger gesture of a user, a main processor configured to provide an AC current to the sensing module, and a short-range wireless communication module configured to transmit one of the sensed biometric signal or the sensed finger gesture to a rear seat monitor through wireless communication depending on an operation mode.

Aspects of the present invention relate to external user interfaces used in connection with head worn computers (HWC).

Aspects of the present invention relate to external user interfaces used in connection with head worn computers (HWC).

Embodiments are provided that perform cross-application installation of a particular target application program. Such embodiments facilitate cross-application installation of the particular target application program through a computer-executable tool capable of incorporation into any number of distinct application programs, including third-party application programs. Some example embodiments incorporate a computer-executable tool within a first application program installed on a mobile device, execute the first application program on the mobile device and, upon such execution, execute the computer-executable tool to detect system data from the mobile device, determine based at least in part on the system data that an application program set installed to the mobile device does not include a target application program, and in response to the determination use the computer-executable tool to cause rendering of a representation of the target application program within a first user interface associated with the first application program.

A method for interacting with controls in a graphical user interface (GUI) having a plurality of GUI controls, the method includes identify one GUI control that a user is gazing at, from among a plurality of GUI controls presented on a display, detect user interface gestures performed by the user, when the detected gesture is performed in an airspace away from the display, apply a relative motion corresponding to the gesture to the identified GUI control, and when the detected gesture is performed by the user touching the display, apply a sequence of absolute display locations touched by the gesture to a GUI control presented at the touched locations that is different than the identified GUI control.

An operation method of an electronic device for sensing an optical signal is provided. The electronic device includes a plurality of optical sensors and a plurality of light-emitting elements disposed adjacent to the plurality of optical sensors. The operation method of the electronic device for sensing the optical signal includes the following steps. The optical signal is provided to a first optical sensor of the plurality of optical sensors. The first optical sensor outputs a driving signal when dimming the plurality of light-emitting elements adjacent to the first optical sensor. Therefore, the accuracy of sensing the optical signal may be effectively increased.

A method for detecting locations of objects in a plane, including emit light beams, one at a time, at locations along a first edge of a detection area, refract each light beam into multiple divergent light beams, direct each of the divergent beams to arrive at a respective pair of focusing lenses mounted along a second edge of the detection area, opposite the first edge, wherein an intensity profile of each divergent beam has maximum intensity along the center of the beam, for each of the focusing lenses, measure an intensity profile of that portion of the divergent beam that enters the focusing lens, for each pair of focusing lenses receiving a single divergent beam, compare the measured intensity profiles for light arriving at each lens, and determine a location of an object that partially blocks at least one of the divergent beams, based on the compares.