The present disclosure provides a control method. The method includes when an electronic device is in a first operating mode and has an abnormal situation, switching the electronic device to a second operating mode, to process the abnormal situation in the second operating mode; and when the electronic device has returned to normal, switching the electronic device to the first operating mode. Power consumption and/or available system resource of the electronic device in the first operating mode are less than power consumption and/or available system resource of the electronic device in the second operating mode.

A display apparatus includes: a display panel including a light emitting structure and including a main display area, a left edge display area adjacent to the main display area, and a right edge display area adjacent to the main display area; and a first pattern film attached under the display panel and overlapping with the main display area and the left and right edge display areas, the first pattern film having a stiffness higher than a stiffness of the display panel, and a stress dispersing portion is located on the first pattern film.

Optical sensors and optical markers are placed on components in a medical system to provide calibration and alignment, such as on a patient transportation mechanism and spatially separated medical diagnostic devices. Image processing circuitry uses the data captured by these optical devices to coordinate their movements and/or position. This enables scans that were captured in multiple medical diagnostic devices to be accurately aligned.

The present disclosure provides a photodynamic energy electronic label, a working method thereof, a managing method and a managing apparatus thereof. The photodynamic energy electronic label includes a photodynamic energy converter configured to convert light energy into electric energy, and a triggering circuit connected with the photodynamic energy converter and configured to send out a triggering signal to enable the photodynamic energy electronic label to be in a working state when an output of the photodynamic energy converter reaches a set condition.

A system and method for efficiently capturing data by sequential circuits across multiple operating conditions are described. In various implementations, an integrated circuit includes multiple signal arrival adjusters both at its I/O boundaries and across its die. The signal arrival adjuster includes two internal timing paths, each with a respective latency. The signal arrival adjuster receives an input signal, and generates an output signal from the a selected one of the first timing path and the second timing path. The signal arrival adjuster sends the output signal to a sequential circuit. The sequential circuit uses the output signal as one of an input data signal and an input clock signal. The selection between the two timing paths within the signal arrival adjuster aids satisfying the setup and hold time requirements of the sequential circuit.

Example systems, apparatus, and methods receive audio information including a plurality of frames from a source device, wherein each frame of the plurality of frames includes one or more audio samples and a time stamp indicating when to play the one or more audio samples of the respective frame. In an example, the time stamp is updated for each of the plurality of frames using a time differential value determined between clock information received from the source device and clock information associated with the device. The updated time stamp is stored for each of the plurality of frames, and the audio information is output based on the plurality of frames and associated updated time stamps. A number of samples per frame to be output is adjusted based on a comparison between the updated time stamp for the frame and a predicted time value for play back of the frame.

Example systems, apparatus, and methods receive audio information including a plurality of frames from a source device, wherein each frame of the plurality of frames includes one or more audio samples and a time stamp indicating when to play the one or more audio samples of the respective frame. In an example, the time stamp is updated for each of the plurality of frames using a time differential value determined between clock information received from the source device and clock information associated with the device. The updated time stamp is stored for each of the plurality of frames, and the audio information is output based on the plurality of frames and associated updated time stamps. A number of samples per frame to be output is adjusted based on a comparison between the updated time stamp for the frame and a predicted time value for play back of the frame.

One embodiment provides a method, including: receiving, at an information handling device in a low power mode, a wake indication; waking, responsive to the receiving, the information handling device from the low power mode; receiving, at the awoken information handling device, context data obtained by at least one other device; and performing an action based on the received context data. Other aspects are described and claimed.

The kernel function generation unit 81 defines a first kernel function by using two-dimensional feature representation that represents a combination of two features of data. The model learning unit 82 defines a linear model including an inner product of a mapping used in the first kernel function and a first weight and performs learning with the defined linear model. The component expanding unit 83 expands the learned linear model to define expanded component representation that is new component representation of the data. The expansion model generation unit 84 generates an expansion model including an inner product of data by the expanded component representation and a second weight.

Disclosed embodiments may relate to a time-dependent color-changing label for a product. The label may include a first layer comprising a plurality of particles, the particles comprising a time dependent color-changing material that changes color after a predetermined time period, the predetermined time period being greater than one month. The label may also include an attachment structure attaching the first layer to the product. In certain embodiments, the first layer may include a polymer, and the particles may include glass microspheres containing the time-dependent color changing material. The particles may be embedded in the polymer.