Method and device of encrypting communication between a server and a peripheral device are disclosed. The method includes: a server receiving a session request from a control device, the session request including a predetermined device ID of a peripheral device associated with the control device; generating a first session key for encrypting and decrypting future communication between the peripheral device and the server; identifying a pre-stored encryption key corresponding to the predetermined device ID from a database, wherein the pre-stored encryption key is also pre-stored in the peripheral device; encrypting the first session key using the pre-stored encryption key; sending the encrypted first session key to the peripheral device via the control device; and encrypting communication to the peripheral device in a respective communication session using the first session key.

The present invention relates to the control and operation of cellular telephones and other electronic devices, and particularly to improvements in the functionality of those devices for use in conjunction with a variety of sports and recreational activities.

One or more processing circuits may obtain sensor data that includes first sensor data generated by a first plurality of sensors of one or more hearing instruments worn by a user and second sensor data generated by a second plurality of sensors of the computing device communicably coupled to the one or more hearing instruments. The one or more processing circuits may generate a notification and may determine, based on at least a portion of the sensor data, a. time period at which the user is available to interact with the notification. The one or more processing circuits may, in response to determining the time period at which the user is available to interact with the notification, output, during the time period, the notification.

The present disclosure provides a metal structure, or antenna radiator, for an accessory that is configured to function as both an antenna and an input control. The device may be a wearable device with a first surface shaped to be in contact with the human body and a second surface shaped to be exposed when the device is being worn. The antenna radiator may be located internally within the housing of the device and coupled to a printed circuit board (PCB). The PCB may be located between the antenna radiator and the surface of the housing such that the PCB may shield the antenna radiator from antenna loss due to the human body. An electric field may extend between the PCB and the antenna radiator. The fringe electric field may improve cross-head and cross-body connectivity between the accessory and another device.

In one aspect, at least a first device includes at least one processor and storage accessible to the at least one processor. The storage includes instructions executable by the at least one processor to execute a first application (app) at a first device, where the first app is configured for presenting content stereoscopically in three dimensional (3D) space using a headset. The instructions are also executable to use the first app to request, from a second app, a virtual display in a square orientation. The instructions are then executable to receive, from the second app, the virtual display in the square orientation and to use the first app to present, in 3D space on a display of the headset, the virtual display in the square orientation.

This watching system is provided with: a watching detection device that is provided with a cartilage conduction vibration source, a mastication sensor, and a bone conduction microphone and that is configured to be mounted on an ear such that the entry of the ear canal is opened; and a mobile phone or an in-home monitoring unit that receives watching detection signals from the mastication sensor and the bone conduction microphone by means of short-range communication and issues a notification to the outside. The watching detection device has an air conduction microphone and also functions as a hearing aid. When detection signals cannot be received from the mastication sensor or the bone conduction microphone for a predetermined time period, a notification is issued. The mobile phone and the in-home monitoring unit crosscheck watching detection information. The mobile phone also issues a notification of information indicating that there is no abnormality.

Systems, methods, and non-transitory computer-readable media for providing situational awareness to users of wearable extended reality appliances are disclosed. In one implementation, a non-transitory computer-readable medium contains instructions that when executed by at least one processor cause the at least one processor to: cause virtual content to be displayed through a first wearable extended reality appliance; detect a second wearable extended reality appliance in proximity to the first wearable extended reality appliance; establish a link between the first wearable extended reality appliance and the second wearable extended reality appliance; and transmit data representing at least a portion of the virtual content in an obscured form to the second wearable extended reality appliance, wherein the obscured form provides an indication of a position of the at least a portion of the virtual content in a three-dimensional space without revealing substance of the virtual content in obscured form.

Consistent with disclosed embodiments, systems, methods, and computer readable media including instructions for wearable extended reality appliances to share virtual content. Embodiments may include a processor to generate a visual code reflecting a first physical position of a mobile device. The visual code may be presented on a display of the mobile device in order for the plurality of wearable extended reality appliances to detect the visual code. The plurality of wearable extended reality appliances may share content in a common coordinate system upon detection of the visual code. The processor may detect movement of the mobile device to a second physical position different from the first physical position. The processor may alter the presentation of the visual code upon the detected movement of the mobile device making the visual code unavailable for use in content sharing.

A smart eyewear device is disclosed that can change any pair of eyeglasses into Bluetooth smart glasses. The smart eyewear device comprises an arm component for a standard pair of eyeglasses. The arm component comprises Bluetooth technology built inside the frame, which enables wireless communications when listening to music, talking on the phone, etc. Thus, users can listen to music and talk on the phone while remaining fully aware of their surroundings. The arm component can be integrated into eyeglasses, sunglasses, prescription eyeglasses, safety glasses, etc. Further, the smart eyewear device is available in diverse colors, styles, and sizes.

Systems, methods, and non-transitory computer readable media configured for enabling content sharing between users of wearable extended reality appliances are provided. In one implementation, the computer readable medium may be configured to contain instructions to cause at least one processor to establish a link between a first wearable extended reality appliance and a second wearable extended reality appliance. The first wearable extended reality appliance may display first virtual content. The second wearable extended reality appliance may obtain a command to display first virtual content via the second wearable extended reality appliance, and in response, this content may be transmitted and displayed via the second extended reality appliance. Additionally, the first wearable extended reality appliance may receive second virtual content from the second wearable extended reality appliance, and display said second virtual content via the first wearable extended reality appliance.