In some examples, the disclosure describes a device, comprising: a processor, and a non-transitory memory resource storing machine-readable instructions stored thereon that, when executed, cause the processor to: activate a dynamic power reduction mode for a device in response to identifying the device is in a first power state associated with a first account, and deactivate the dynamic power reduction mode for the device in response to identifying the device is in a second power state associated with a second account.

Methods and systems for managing a premises are disclosed. The premises may comprise a premises management device. The premises management device may be in communication with a security system. The premises management device may manage consumption by maintaining or disabling components associated with the premise management device.

Methods and systems for managing a premises are disclosed. The premises may comprise a premises management device. The premises management device may be in communication with a security system. The premises management device may manage consumption by maintaining or disabling components associated with the premise management device.

The present disclosure relates to methods and devices for wireless communication at a wireless device of a wireless wearable device. In one aspect, the wireless device may transmit a first report based on one of a location of the wireless wearable device, a time period, or reception of a user-controlled indication to transmit the first report. The wireless device may also receive, based on the transmitted first report, a configuration to switch from a first mode to a second mode. In some aspects, the configuration can include at least one parameter associated with a power savings at the wireless wearable device while in the second mode. Additionally, the wireless device can operate based on the at least one parameter while in the second mode.

An authentication method and system for mutual authentication between a first entity and a third entity via a second entity, based on an authentication protocol used by the first entity and the third entity. The second entity forwards mutual authentication messages between the first entity and the third entity. An apparatus is configured to perform an authentication method for a mutual authentication between a first entity and a third entity via a second entity, based on an authentication protocol used by the first entity and the third entity, the second entity forwards mutual authentication messages between the first entity and the third entity.

Broadly speaking, the present technique provides methods, apparatuses and systems for performing a TLS/DTLS handshake process between machines in a manner that reduces the amount of data sent during the handshake process.

In a real-time system having first and second processor systems, cooperative dynamic clock and voltage scaling (“DCVS”) may include a first processor system monitoring a condition indicative of first processor workload, adjusting a first processor operating frequency in response to a detected amount of change in the first processor workload, and providing an indication based on the detected amount of change in the first processor workload to the second processor contemporaneously with providing first processor output data to the second processor. The cooperative DCVS may further include the second processor system adjusting a second processor operating frequency in response to the indication.

Systems and methods for injecting a toggling signal in a command pipeline configured to receive a multiple command types for the memory device. Toggling circuitry is configured to inject the toggling signal into at least a portion of the command pipeline when the memory device is in a power saving mode and the command pipeline is clear of valid commands. The toggling is blocked from causing writes by disabling a data strobe when a command that is invalid in the power saving mode is asserted during the power saving mode.

An image forming system includes at least one piece of image forming apparatus and a server. The at least one piece of image forming apparatus transmits a sleep notification when entering a sleep mode which is a power saving state, and transmits a wake-up notification when returning from the sleep mode to a non-power saving state. The server monitors the sleep notification and the wake-up notification. When a specific image forming apparatus of the at least one piece of image forming apparatus has been in the sleep mode for at least a certain period of time, the sever issues a power-off command to the specific image forming apparatus, so that the specific image forming apparatus shuts off automatically. Before issuing the power-off command, the server delivers a power-off notice to the user who has used the specific image forming apparatus.

Disclosed are systems, methods, and devices for communicating a source of a 10SPE wake. Such a communication may be performed over a low-pin count hardware interface of a 10SPE physical layer (PHY) module having a split arrangement. A controller side of a 10SPE PHY may perform a local or remote 10SPE wake forward in response to a communicated source of a wake. Also disclosed is a digital interface for operatively coupling a PHY controller to PHY transceiver over a low-pin count connection, where the digital interface includes circuitry for checking the integrity of circuitry of the digital interface.