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.

A system on chip (SoC) includes a first core and a second core, first and second power gating switches, and a first power switch. The first power gating switch is arranged between the first core and a first power rail that receives a first voltage, and is selectively turned on in response to a first power gating signal. The second power gating switch is arranged between the second core and a second power rail that receives a second voltage, and is selectively turned on in response to a second power gating signal. The first power switch is arranged between the first power rail and the second power rail, and is selectively turned on in response to a first power control signal to connect the first power gating switch or the second power gating switch both the first power rail and the second power rail.

In an exemplary embodiment of the present disclosure, disclosed is a computer program stored in a computer readable storage medium executable by one or more processors, in which when the computer program is executed by one or more processors of a computing device, the computer program performs operations below for processing data, the operations may include: selecting a plurality of different data from a data set including data formed of one or more feature groups, transforming a part of each data among the plurality of selected data, assigning a label to each of the plurality of transformed data, and computing the transformed data by using the model.

Techniques are disclosed that pertain to synchronizing power states between integrated circuit dies. A system includes an integrated circuit that includes a plurality of integrated circuit dies coupled together. A particular integrated circuit die may include a primary power manager circuit and one or more remaining integrated circuit dies include respective secondary power manager circuits. The primary power manager circuit is configured to issue a transition request to the secondary power manager circuits to transition their integrated circuit dies from a first power state to a second power state. A given secondary power manager circuit is configured to receive the transition request, transition its integrated circuit die to the second power state, and issue an acknowledgement to the primary power manager circuit that its integrated circuit die has been transitioned to the second power state. Techniques are further disclosed relating to managing latency tolerance events within a multi-die integrated circuit.

A power management arrangement (10) for a device connection system 5 is described. The power management arrangement comprises a processing module (30) connected to data communication lines (35) for exchanging data with one or more peripherals (100), an interrupt interface (20) connected to interrupt channels (25) for sending an interrupt to and from one or more of the peripherals (100), and a local storage (50) connected to the processing module (30) for storing of logic operations relating to communication with and operation of the plurality of peripherals (100).

An output system, a system, and an output method. The output system communicates with an output apparatus and an information processing apparatus, and transmits, in response to a request from the output apparatus for electronic data including source identification information received from the information processing apparatus, electronic data associated with a user identified based on the source identification information to the output apparatus.

A method and an apparatus for controlling a sleep mode in a portable terminal having a main controller and a sub-controller operating at low power are provided. The method includes detecting, by the sub-controller, a first sensor signal generated by a first sensor when the main controller is in the sleep mode, extracting a sensed pattern from the detected first sensor signal, determining whether the extracted sensed pattern is substantially identical with a preset wake-up pattern, and cancelling the sleep mode by waking-up the main controller when the extracted sensed pattern is substantially identical with the wake-up pattern.

Case management interface provides correlation among a plurality of transaction orders in an interactive graphical format. A visualization window displays a plurality of transaction orders that are visually connected based on one or more common data elements associated with the transaction orders. The visualization window can allow a user to interact with different elements of the display to analyze the relationship between order data elements, view order details, reject or accept orders or mark an order as suspect. Different layout options are available to enhance the visualization of the transaction order data.

Case management interface provides correlation among a plurality of transaction orders in an interactive graphical format. A visualization window displays a plurality of transaction orders that are visually connected based on one or more common data elements associated with the transaction orders. The visualization window can allow a user to interact with different elements of the display to analyze the relationship between order data elements, view order details, reject or accept orders or mark an order as suspect. Different layout options are available to enhance the visualization of the transaction order data.

A PoDL system includes a PSE supplying DC power and Ethernet data over a single twisted wire pair to a PD. Prior to coupling the DC voltage source to the wire pair, the PD needs to receive sufficient power to perform a detection and classification routine with the PSE to determine whether the PD is PoDL-compatible. The PSE has a low current, pull-up current source coupled to a first wire in the wire pair via a first inductor. This pull-up current charges a capacitor in the PD to a desired operating voltage, and the operating voltage is used to power a PD logic circuit. The PD logic circuit and a PSE logic circuit then control pull-down transistors to communicate detection and classification data via the first wire. After the handshaking phase, the PSE then applies the DC voltage source across the wire pair to power the PD for normal operation.