A phone holder includes a pocket having a rear wall and a front wall and configured to receive a phone; an elongate neck extending from an upper portion of the rear wall of the pocket and foldable relative to the rear wall of the pocket; and at least one magnet located on or in the neck. The neck is foldable so that a rear surface of the neck faces an opposite surface of the rear wall to enable the neck to overlie a waist band of clothing of the user or a belt or the like with the magnet being magnetically coupled by magnetic attraction to the phone at a location adjacent the phone to support the phone holder.

Notifications for an accessory device are received at a mobile companion device. The notifications are directed to a notification processing application of the companion device that processes notifications intended for accessory device applications. The notification processing application determines an identifier of the accessory application for which the notification is intended, and provides the identifier to a notification display application at the accessory device, which determines user interface and display properties for the notification. The accessory device requests external (dynamic) user interface and display properties from the companion device, as needed, and upon receipt generates a notification display at the accessory device.

A data transmission method is provided, the method is applied to a wearable apparatus configured with a first operation system and a second operation system, and a power consumption of the first operation system is lower than a power consumption of the second operation system; the method; the method includes: obtaining a type of data to be transmitted; detecting current screen state information of the wearable apparatus; and determining target data according to the current screen state information of the wearable apparatus and the type of data to be transmitted, and transmitting the target data from the first operation system of the wearable apparatus to the second operation system of the wearable apparatus.

The present disclosure provides a method, performed in an accessory device, for communicating a leakage state of an ostomy appliance, wherein the accessory device comprises an interface configured to communicate with one or more devices of an ostomy system, the one or more devices comprising a monitor device, and/or the ostomy appliance configured to be placed on a skin surface of a user. The method comprises obtaining monitor data from the one or more devices, the monitor data being indicative of presence of fluid at a proximal side of a first adhesive layer of the ostomy appliance towards the skin surface; determining a leakage state at the proximal side of the first adhesive layer of the ostomy appliance based on the monitor data, and communicating the leakage state of the ostomy appliance via the interface.

The present disclosure provides an augmented reality information prompting system, including: a head pose detector to detect a user's head pose to generate head pose data; an operation control device to generate operation control data based on the user's operation; and a processor to receive the head pose data from the head pose detector and generate a first display control instruction based on the head pose data, and to receive the operation control data from the operation control device and generate a second display control instruction based on the operation control data; an augmented reality display configured to receive the first and second display control instructions from the processor, and to operate prompt information based on the first and second display control instructions. The present disclosure further relates to a display control method used for the system, as well as an electronic equipment and a non-transitory computer-readable storage medium.

A computer implemented method includes: capturing an ambient sound event; determining whether the ambient sound event matches at least one of a plurality of pre-identified sound events stored in a computer storage; generating a prompt via the user interface for a user to confirm that a response is needed; determining whether to initiate a response based on the user's response to the prompt.

In response to detecting that an external device is within communication range of an electronic device and in accordance with a determination that the external device is in a pairing mode, the electronic device displays an affordance corresponding to a pairing application of the electronic device. In response to detecting that an external device is within communication range of an electronic device and in accordance with a determination that the external device is not in the pairing mode, the electronic device forgoes display of the affordance. In response to user input corresponding to selection of the affordance, the electronic device displays a user interface associated with initiating a process to pair the electronic device and the external device.

A system may monitor an appendage gesture with a smart device, extrapolate a gesture direction, select an item on a display based on the gesture direction, and display the item on a second display on the smart device.

A wearable device that communicates with a host device can be used to initiate a communication functionality of the host device (e.g., telephone calls, text messages). The wearable device can obtain user input indicating a recipient of the communication and in some instances content for the communication and can provide an instruction to the host device. The host device can use the indicated recipient and content to initiate communication and where applicable to send the content. Recipients and/or content can be selected from predefined lists available on the wearable device.

A first device comprises at least one amplifier. The at least one amplifier is configured to receive a plurality of sensor signals from a plurality of sensors. The at least one amplifier is configured to amplify at least two of the sensor signals to generate a plurality of amplified signals. Each of the amplified signals corresponds to one of the sensor signals. The first device comprises a plurality of modulators. Each of the modulators is configured to modulate one of the amplified signals to a distinct center frequency through employment of a Voltage Controlled Oscillator (VCO) to generate a modulated signal. The first device comprises an adder configured to create a composite signal. The composite signal comprises the modulated signal from each modulator. The composite signal is configured for transmission to a second device.