Disclosed herein is a data input device and method of operating the same. In one embodiment, a data input device comprises a plurality of inertial sensor units, one or more touch input devices, a microcontroller configured to collect sensor data from the inertial sensors and the one or more touch input devices and process the sensor data to generate processed sensor data, and a wireless transceiver configured to transmit the processed sensor data to a host computer. In another embodiment, a method comprises receiving sensor data from a handheld device; calculating hand movement characteristics in three dimensional space based on the sensor data; calculating the position and orientation of the components of the handheld device; identifying positions and movements of one or more fingers of a user manipulating the handheld device; identifying a gesture from the positions and movements of one or more fingers of a user manipulating the handheld device; identifying a recognized gesture corresponding to the identified gesture; and dispatching an event notifying the gesture to an application.

An inputting fingertip sleeve includes a sleeve and an inputting end. The sleeve has a curved linear structure. The inputting end is fixed on the sleeve. The inputting end includes a plurality of graphenes. A material of the sleeve is conductive, can be metal, alloy or conductive polymer. The inputting end is electrically connected with the sleeve.

An information processing method, a system and an electronic device are disclosed. The method includes: acquiring a first motion locus with the first electronic component, where the first motion locus is generated by the first part from a first time instant to a second time instant; and acquiring a second motion locus with the second electronic component, where the second motion locus is generated by the second part from the first time instant to the second time instant. The first electronic device may obtain and execute a first control instruction corresponding to the first motion locus and the second motion locus. With the method and electronic device, an advantage of precisely recognizing a slight local action of the user is achieved.

A method for determining positions of fingers of a user is described. The method includes transmitting a power signal from a head mounted display (HMD) to provide power to a plurality of light emitters. The light emitters emit light in a sequence upon receiving the power signal. The method includes using the light emitted by the light emitters to determine a plurality of positions of the light emitters. The positions are used to play a game using the HMD.

Disclosed is a wearable device. The wearable device includes a depth sensor configured to 3-dimensionally sense a user's hand and to generate 3D scan information, a finger recognition unit configured to sense skin lines of user's fingers and to generate pattern information, an image processor configured to generate a 3D model of the user's hand based on the 3D scan information and to add a pattern representing the skin lines of the user's fingers to the 3D model based on the pattern information, and a key determination unit configured to, when the finger recognition unit senses a user's key input motion, generate an input value matching the key input motion, and the finger recognition unit senses the key input motion by comparing the sensed skin lines of the user's fingers with the pattern added to the 3D model.

Provided are a head-mounted information processing apparatus capable of improving user's convenience, and its controlling method. Therefore, it includes a main body device 2 used in a state of being worn on a user's head, and a controller used in a state of being worn on a user's wrist or hand and controlling the main body device. For example, a directional detector 91 in the main body device 2 detects a controller's direction by calculation based on a detected result of a position/attitude sensor of the controller. A rotational detector 92 detects controller's rotation, which uses the direction of the controller as a rotational axis, by calculation based on the detected result of the position/attitude sensor of the controller. An operation instruction converter 87 converts detected results of the directional detector 91 and the rotational detector 92 into instructions for the main body device 2.

A wearable electronic device is provided herein. The wearable electronic device includes a body defining an aperture therethrough. The aperture is sized and shaped to receive a finger of a user. The wearable electronic device further includes a computer processor and an input device at least partially extending from an inner surface of the body. The input device is movable between a first position and a second position. Movement of the input device between the first position and second position provides an input to the processor. The electronic wearable device also includes a transmitter coupled to the computer processor and configured to send electronic transmissions to an external electronic device. The electronic transmissions correspond to the input. The electronic wearable device also includes a power source for providing power to the computer processor, the input device and the transmitter.

A ring-type terminal including a main body having a finger insertion space; a wheel surrounding the main body and being movable and rotatable on the main body; a touchscreen; and a controller configured to sense a rotated position of the wheel on the main body, display control graphic images on the touchscreen for controlling a function in response to the rotated position of the wheel being at a first position on the main body, receive a gesture input corresponding to a touch input on the touch screen or a moving of a finger wearing the ring-type terminal, in response to the rotated position of the wheel being at a second position on the main body, and deactivate the touchscreen in response to the rotated position of the wheel being at a third position on the main body.

Provided are a method and a device for performing spatial positioning on an electronic tag, 3D signature and human-computer interaction. The method for performing spatial positioning on an electronic tag includes: arranging at least three sets of three-dimensionally distributed array antennas on an electronic device, each set of array antennas including multiple antenna array elements extending in one dimension; turning on an electronic tag reader to generate a radio frequency electromagnetic field when spatial positioning is performed on an electronic tag; acquiring induced voltage generated on each antenna array element in each set of array antennas when it is sensed that there is an electronic tag in the radio frequency electromagnetic field; and determining spatial position information of the electronic tag according to the induced voltage.

The present invention relates to a drone controller capable of controlling a movement and a rotation of a drone. The present invention discloses a drone controller capable of controlling a rotation and a movement of a drone, the drone controller including: a main body which is formed in a cylindrical shape and may be held by a user with one hand; a lever which is disposed at one side of the main body, formed such that the user's finger may be inserted into the lever, and operated to move the drone in front and rear directions or left and right directions; and a button unit which is disposed at a predetermined portion of the main body, and operated so that the drone may be rotated.