A processing device includes a plurality of processing cores, a control register, associated with a first processing core of the plurality of processing cores, to store a first base clock frequency value at which the first processing core is to run, and a power management circuit to receive a base clock frequency request comprising a second base clock frequency value, store the second base clock frequency value in the control register to cause the first processing core to run at the second base clock frequency value, and expose the second base clock frequency value on a hardware interface associated with the power management circuit.

Platform power management includes boosting performance in a platform power boost mode or restricting performance to keep a power or temperature under a desired threshold in a platform power cap mode. Platform power management exploits the mutually exclusive nature of activities and the associated headroom created in a temperature and/or power budget of a server platform to boost performance of a particular component while also keeping temperature and/or power below a threshold or budget.

A method for power management of a computing system having two or more physical servers for hosting virtual machines of a virtual system and one or more uninterruptible power supplies for supplying at least a subset of the physical servers with power, each of the one or more uninterruptible power supplies being connected to a phase of a multiple phase power supply, is disclosed. The method comprises receiving an action input for the computing system, which may impact the power consumption of the physical servers, processing the received action input with a predictive model of power consumption of the physical servers with regard to the battery autonomy of the one or more uninterruptible power supplies and/or the load balancing of the several phases of the multiple phase power supply, and optimizing the utilization of the physical servers based on the result of the processing.

Systems and methods are described for power control in a media receiver device having a plurality of electronic components, using a trained model. Input signals are received from at least one electronic component. An alertness state of the device is determined using a machine learning based determiner trained to process the received input signals and predict a subsequent alertness state identifying at least one additional component or device. Power consumption by the identified components and devices is controlled based on the predicted alertness state.

A system can validate multiple nonvolatile random-access memory (NVRAM) devices in parallel. The system can concurrently write a first data to a first volatile memory of a first NVRAM device and a second NVRAM device. The system can modify a first electrical power source that provides an electrical power output that is received by the first NVRAM device and is received by the second NVRAM device to modify a voltage of the electrical power from a first value to a second value to initiate the first NVRAM device and the second NVRAM device to respectively perform a vault. The system can reset the first electrical power source, causing the first NVRAM device and the second NVRAM device to reset. The system can verify whether the first NVRAM device and the second NVRAM device respectively store the first data in volatile memory subsequent to performing the resetting.

A system can validate multiple nonvolatile random-access memory (NVRAM) devices in parallel. The system can concurrently write a first data to a first volatile memory of a first NVRAM device and a second NVRAM device. The system can modify a first electrical power source that provides an electrical power output that is received by the first NVRAM device and is received by the second NVRAM device to modify a voltage of the electrical power from a first value to a second value to initiate the first NVRAM device and the second NVRAM device to respectively perform a vault. The system can reset the first electrical power source, causing the first NVRAM device and the second NVRAM device to reset. The system can verify whether the first NVRAM device and the second NVRAM device respectively store the first data in volatile memory subsequent to performing the resetting.

A storage system is described where goods are stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run to lift containers from the stacks and deposit them at alternative locations in the stacks or at stations where goods may be removed or alternative functions may be undertaken. The containers can provide the following exemplary services: power, power control, heating, lighting, cooling, sensing, and data logging. The provision of these services within individual containers rather than across the system as a whole, allows for flexibility in storage whilst reducing cost and inefficiency. The containers when removed from the stacks are electrically connected to the load handling device, power being supplied by a power supply within the load handling device.

A storage system is described where goods are stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run to lift containers from the stacks and deposit them at alternative locations in the stacks or at stations where goods may be removed or alternative functions may be undertaken. The containers can provide the following exemplary services: power, power control, heating, lighting, cooling, sensing, and data logging. The provision of these services within individual containers rather than across the system as a whole, allows for flexibility in storage whilst reducing cost and inefficiency. The containers when removed from the stacks are electrically connected to the load handling device, power being supplied by a power supply within the load handling device.

Methods, systems, and devices for providing computer implemented services using managed systems are disclosed. To provide the computer implemented services, the managed systems may need to operate in a predetermined manner conducive to, for example, execution of applications that provide the computer implemented services. Similarly, the managed system may need access to certain hardware resources (e.g., and also software resources such as drivers, firmware, etc.) to provide the desired computer implemented services. To improve the likelihood of the computer implemented services being provided, the managed systems may be managed using a subscription based model. The subscription model may utilize a highly accessible service to obtain information regarding desired capabilities (e.g., a subscription) of a managed system, and use the acquired information to automatically configure and manage the features and capabilities of the managed systems by powering and depowering select components.

Methods, systems, and devices for providing computer implemented services using managed systems are disclosed. To provide the computer implemented services, the managed systems may need to operate in a predetermined manner conducive to, for example, execution of applications that provide the computer implemented services. Similarly, the managed system may need access to certain hardware resources (e.g., and also software resources such as drivers, firmware, etc.) to provide the desired computer implemented services. To improve the likelihood of the computer implemented services being provided, the managed systems may be managed using a subscription based model. The subscription model may utilize a highly accessible service to obtain information regarding desired capabilities (e.g., a subscription) of a managed system, and use the acquired information to automatically configure and manage the features and capabilities of the managed systems by powering and depowering select components.