Dynamic transcode throttling methods and devices for processing resource management and thermal mitigation in electronic devices such as eyewear devices. An electronic device monitors its temperature and, responsive to the temperature, configures a transcoding service to operate at different rates. A frame delay module is configured to add a delay between read frames prior to the transcoding service. This enables the electronic device to consume less power when temperatures are too high in order to provide thermal mitigation and can be performed without powering down the electronic device.

A power circuit according to the present disclosure may include a multiplexer connected to a first power line and a second power line and selecting and outputting one of a first voltage supplied through the first power line and a second voltage supplied through the second power line. Further, the power circuit may include a first power circuit which generates a first driving voltage and a second driving voltage by using a voltage supplied from the multiplexer, recognizes whether there is the first voltage supplied through the first power line, and does not output the first driving voltage when the first voltage is not recognized.

A terminal screen-on/off control method includes receiving an operation instruction that is sent by a user by using a first terminal; if the operation instruction meets a preset condition, determining a current state of a screen of a second terminal, and if the current state of the screen is on, controlling the second terminal to turn off the screen; or if the current state of the screen is off, controlling the second terminal to turn on the screen. The preset condition is used to determine whether the second terminal is to turn the screen on/off. The first terminal can be directly used to control the second terminal to turn the screen on/off. This operation is very simple.

A fingerprint sensing device and an operation method thereof are provided. The fingerprint sensing device includes a driver integrated chip and a fingerprint sensor. The driver integrated chip is coupled to a host processor. The fingerprint sensor is coupled to the driver integrated chip and the host processor. The fingerprint sensor obtains a fingerprint image during a period when the host processor is in the sleep mode. The driver integrated chip performs a fingerprint verification on the fingerprint image, and the driver integrated chip determines to wake up the host processor according to whether the fingerprint image passes the fingerprint verification.

An electronic device including a rollable display is provided. The electronic device includes a housing including a main body, a first planar part disposed at one end of the main body, and a second planar part disposed at another end of the main body and disposed in parallel to the first planar part, a rollable display drawn out from an interior of the housing or inserted into the interior of the housing through a slit formed in a direction perpendicular to the first planar part, and a handler member combined with an end of the rollable display and including a first magnet. A second magnet having a polarity different from a polarity of the first magnet disposed within the main body so that the handler member is attached to a surface of the main body in a state in which a part of the rollable display has been drawn out from the interior of the housing.

A power-management scheme where when a system-on-chip (SoC) is in an active state, control and monitoring logic or circuitry turns off all wake logic or circuits for various associated intellectual property (IP) blocks. Based on user defined operating system power manager (OSPM) policies, OSPM kicks off an interrupt to the control and monitoring logic or circuitry to turn off or power gate the wake logic for individual IP blocks in the SoC. As such, wake logic that are idle in active state (e.g., S0 state) and would otherwise draw power in the S0 state are now turned off, thus saving power and/or extending battery life for the system. When the SoC is in a low power state, then the control and monitoring logic or circuitry selectively turns on the wake logic for the associated IP blocks based on detected user presence for the computing system having the SoC.

An electronic apparatus includes a processing unit, a memory, a processor, and an operation control unit. The processing unit executes system processing based on a system. The memory temporarily stores image data of an image captured by an imaging device. The processor processes image data stored in the memory. The operation control unit controls an operating state of the system. The processor includes a face detection unit that processes image data of an image obtained by the imaging device capturing a predetermined imaging range and stored in the memory to perform detection of a face area with a face captured therein and an orientation of the face from the image. The operation control unit controls, according to a detection result by the face detection unit, the operating state of the system to be a first operating state or a second operating state.

A device includes a display and an internal strap coupled to the display, the internal strap being adjustable to secure the device to the user. The device also includes a deformable material coupled to a portion of the internal strap and configured to contact the user when the device is secured to the user and a backing layer disposed against the deformable material, the backing layer including an aperture therein. The device further includes a switch coupled to the backing layer and configured such that at least a portion of the switch is insertable in the aperture of the backing layer, wherein the deformable material is configured to deform when the device is secured to the user, thereby causing the switch to be positioned in a first position when the device is secured to the user and a second position when the device is removed from the user.

Methods, apparatuses, and systems for contextual resource registration are described herein. A resource, such as a computer, may be registered for use by a user with a mobile device. The resource may be connected to a controller that has an amount of control over the resource. The controller may broadcast its identifying information, such as an Internet protocol (IP) address, to mobile devices in the vicinity. A mobile device may receive the broadcast message and establish a connection with the controller. The controller may determine whether the mobile device is already registered and also whether the corresponding resource is available for registration. The controller may cause the resource to display a digital signage to facilitate registration with the resource.

A method includes obtaining a request for one of multiple operational modes from an application installed on an extended reality (XR) device or an XR runtime/renderer of the XR device. The method also includes selecting a first mode of the operational modes, based at least partly on a real-time system performance of the XR device. The method also includes publishing the selected first mode to the XR runtime/renderer or the application. The method also includes performing a task related to at least one of image rendering or computer vision calculations for the application, using an algorithm associated with the selected first mode.