A computer program product comprises a non-transitory computer useable storage device that has a computer readable program. When executed on a computer, the computer readable program causes the computer to receive, from a footwear apparatus, motion data corresponding to a foot movement of a user wearing footwear operably attached to the footwear apparatus. The motion data is measured by one or more sensors operably attached to the footwear. Further, the computer is caused to provide, with a processor positioned within a mobile computing device, a user experience based on the motion data. Additionally, the computer is caused to display, via a display device in operable communication with the mobile computing device, the user experience.

A fabric-based electronic device may include an electronic device housing coupled to fabric. Control circuitry may be mounted in the electronic device housing and may control the movement of an output device in the fabric that provides tactile output to a user. For example, the output device may include a wire enclosed within a flexible tube. The flexible tube may be intertwined with fibers in the fabric. The wire may include a kink or other irregularity that presses against the inner surface of the flexible tube. When the wire is rotated or moved into an appropriate position, the kink may press against the inner surface of the tube, which in turn forms a protrusion on the fabric. The protrusion may press against the user's body and may therefore be used to obtain the attention of a user that is wearing or holding the fabric-based electronic device.

Provided is a virtual reality (VR) device, system and framework for generating VR continuum experience choreographed to a physical procedure incorporating at least one procedural action associated with a physical sensation and potentially inducing an anxiety or pain response. The VR continuum experience can modify perceptions of pain and anxiety associated with the procedure. The virtual reality device is configured to allow device control via a device user interface accessible to an operator other than the wearer (i.e. a medical practitioner), to allow the operator to control device calibration and virtual reality (VR) experience start while the apparatus is worn by the wearer, and to provide one or more VR experiences each associated with a physical procedure.

In a virtual reality space, a virtual reference body controlled to follow a player's hand, a virtual body part controlled to follow the player's ear, and a virtual smartphone being a virtual object as a prop are arranged. After the proximity of the virtual reference body to the virtual smartphone, the virtual smartphone is deemed as being gripped and the virtual reference body and the virtual smartphone are integrally moved. Stereophonic sound control is performed such that the emitted sound from the virtual smartphone is a ringtone before the proximity of the virtual reference body or the virtual smartphone to the virtual body part, and after the proximity, the emitted sound is switched to communication sound so that the player listens to the stereophonic sound by a headphone.

According to one embodiment, an electronic device includes a character input controller. The character input controller displays a software keyboard including a set of input areas. Each input area of the set includes objects each representing a character. The set of input areas is arranged adjacent to one another in a first direction. The character input controller moves an active input area in the first direction or in a second direction opposite to the first direction, in response to a first operation or a second operation, and changes a character of an active object displayed in the active input area into another character in the active input area, in response to a third operation or a fourth operation.

An electronic device is provided. The electronic device includes a housing configured to mount at least a part of an external device operating 5th generation (5G) mobile communication, a support member connected to one region of the housing to support wearing of the electronic device with respect to one region of a user's body, a second antenna module disposed in a first region of the housing adjacent to a first antenna module among at least one antenna module included in the external device to face at least a part of the first antenna module, at least one third antenna module disposed in at least one of a second region of the housing or a third region of the support member, and at least one conductive member electrically connecting between the second antenna module and the at least one third antenna module.

A method and an apparatus for controlling a running status of a wearable electronic device, where the method includes determining a posture of a wearable electronic device, where the posture includes a stationary posture and a moving posture, and controlling a running status of the wearable electronic device according to the posture. According to the method and the apparatus for controlling a running status of a wearable electronic device, the posture of the wearable electronic device is monitored using, for example, a gyroscope signal from a mobile phone, whether a user is using the wearable electronic device is determined, and the running status of the wearable electronic device is determined without using a light sensor, which reduces manufacturing costs of the wearable electronic device.

A head-mounted device including a main frame couplable to an electronic device and a support part configured to affix the main frame to a facial side of the user, and an auxiliary input device including a body, an input module disposed on at least one surface of the body and configured to process an input signal for controlling a function of the electronic device, a sensor module disposed in the body and configured to obtain sensing information in accordance with a movement of the auxiliary input device, and a connection part electrically connectable to the electronic device and configured to serve as a path through which the input signal and the sensing information are transmitted to the electronic device is provided.

Various systems and methods for synchronizing haptic actuators with displayed content are described herein. A system may include a computer system, a head-mounted display (HMD) system, and a number of actuators on a wearable device. The computer system may construct a data packet with a network address of a control mechanism on the wearable device and transmit the data packet to the HMD in a video/audio stream. The HMD may identify the data packet in the video/audio stream and forward the data packet to a bus. The control mechanism on the bus is able to retrieve the data packet and access a control message in the data packet, which is used to initiate an effect produced by the control mechanism. The control mechanism may be a haptics actuator, a light controller, or the like.

Technology for a wearable heart rate monitoring device is disclosed. The wearable heart rate monitoring device can include a heart rate sensor operable to collect sensor data, a modulator operable to generate a modulated signal that includes the sensor data, a housing configured to engage a body feature or surface in a manner that allows for heart rate detection, and a communication module configured to transmit the sensor data in the modulated signal to a mobile computing device via a wired connection that is power limited. The mobile computing device is typically configured to demodulate the modulated signal in order to extract the sensor data.