A method for displaying and transmitting images and an electronic device thereof are provided. The electronic device includes a first display, a second display separated from the first display, a transceiver, at least one processor electrically connected to the first display, the second display, and the transceiver, and a memory electrically connected to the at least one processor. The at least one processor is configured to display a first screen image on the first display, provide a second screen image on the second display at least partially simultaneously with the displaying of the first screen image on the first display, provide data associated with one of the screen images to the transceiver, and control the transceiver to transmit the data to an external device such that a screen image at least partially identical to one of the screen images is output on a display of the external device.

A robot comprises: a display unit; a user input unit for receiving a request for providing a first service from a first user; a communication unit for connection to a first mobile terminal of a second user; and a control unit for controlling the display unit such that the same displays a screen including first data for providing the first service, in response to the request for providing the first service, receiving a request for providing a second service from the first mobile terminal, and transmitting, to the first mobile terminal, second data for providing the second service, in response to the received request for providing the service second service.

A method for electromagnetic interference control and related devices are provided. The method includes the following. Electromagnetic interference between a Wi-Fi module and a MIPI of a display of the electronic device is detected in response to detecting a request for screen-projection to a target screen-projection device. In response to the detected electromagnetic interference, the display is turned off, and screen-projection to the target screen-projection device is performed, where the first prompt message indicates that the electronic device is turning off the display and performing screen-projection to the target screen-projection device.

A method for electromagnetic interference control and related devices are provided. The method includes the following. Electromagnetic interference between a Wi-Fi module and a MIPI of a display of the electronic device is detected in response to detecting a request for screen-projection to a target screen-projection device. In response to the detected electromagnetic interference, the display is turned off, and screen-projection to the target screen-projection device is performed, where the first prompt message indicates that the electronic device is turning off the display and performing screen-projection to the target screen-projection device.

An electronic device for transmitting, to a cover device, data acquired from an external electronic device, on the basis of identification information of the cover device, and a control method are disclosed. An electronic device according to various embodiments of the present document comprises: a housing; a first antenna and a second antenna which are accommodated in the housing; a first wireless communication circuit set to provide first wireless communication by using the first antenna; a second wireless communication circuit set to provide second wireless communication by using the second antenna; and a control circuit accommodated in the housing and operably connected to the first wireless communication circuit and the second wireless communication circuit, wherein the control circuit detects coupling between a cover device, which can be coupled to one side of the electronic device, and the electronic device, and the cover device includes a third antenna and a third wireless communication circuit set to provide the first wireless communication by using the third antenna, and can be set to: acquire, through the first wireless communication circuit, identification information related to the cover device from the cover device at least on the basis of the detection; acquire, through the second wireless communication circuit, data corresponding to the identification information from an external electronic device; and transmit, through the first wireless communication circuit, the acquired data to the third wireless communication circuit included in the cover device.

A wireless communication system comprises a host device (110) and mobile devices (120) arranged for wireless communication and for distance (140) measurement. The host device has a user interface (113) comprising a connect button (115), and is arranged to execute a connection sequence upon a user activating the connect button. The connection sequence first determines respective distances between the host and respective mobile devices. A first mobile device is identified exhibiting a movement. Then a connection action is executed regarding a connection between the first mobile device and the host device. The mobile device is arranged for executing a ranging protocol and, upon subsequently receiving a connection message, executing a connection action regarding a connection between the first mobile device and the host device. Effectively a connection may be established upon the user of a mobile device pressing a single button on a selected host device and moving the mobile device.

An electrocardiography device is described that can include a main body, an adjustable cap, and a power switch. The main body can include an electrode of a plurality of electrodes configured to acquire electrical signal from a patient. The adjustable cap can include two electrodes of the plurality of electrodes. The adjustable cap can be rotatable around an axis on the main body to orient the plurality of electrodes on different locations on a body of the patient. The power switch can activate the plurality of electrodes to acquire the electrical signal from the patient. Related apparatuses, systems, methods, techniques and articles are also described.

An electrocardiography device is described that can include a main body, an adjustable cap, and a power switch. The main body can include an electrode of a plurality of electrodes configured to acquire electrical signal from a patient. The adjustable cap can include two electrodes of the plurality of electrodes. The adjustable cap can be rotatable around an axis on the main body to orient the plurality of electrodes on different locations on a body of the patient. The power switch can activate the plurality of electrodes to acquire the electrical signal from the patient. Related apparatuses, systems, methods, techniques and articles are also described.

An electronic device with a primary functionality and a tracking functionality can be used in a centralized tracking system. A controller configures the electronic device to operate in one of a set of: an “on” mode, an “off” mode, a first standby mode, and a tracking standby mode. While configured to operate in the “on” mode, the primary and tracking functionality of the electronic device are enabled, and while configured to operate in the “off” mode, both are disabled. While configured to operate in the first standby mode, the tracking functionality is enabled and the primary functionality is limited. While configured to operate in the tracking standby mode, the primary functionality is disabled but the tracking functionality is enabled, enabling the electronic device to be located while the primary functionality is disabled and saving power relative to the first standby mode and the “on” mode.

System includes a haptic garment comprising an integrated circuit (IC) controller coupled to the haptic garment. A sensing circuit configured to cause to transmit a motion signal sensed by a portion of the haptic garment surface to the IC controller is provided. The motion signal is based on one or more of a touch pattern, a gesture pattern, and a movement pattern associated with a user of the haptic garment. The IC controller is configured to transmit a first data associated with the motion signal to an external device. Conductive traces embedded in the haptic garment that electrically couple with the sensing circuit.