Abstract: Methods and systems for power management are disclosed. The disclosed methods and system for power management may reduce the likelihood of a data processing system failing to meet power budget or other types of goals regarding power consumption, use, and/or provisioning. To reduce the likelihood of the data processing system failing to meet power related goals, the data processing system may include two power managers. An integrated power manager may manage power consumption based on a current-based, fast changing representation of the quantity of power being supplied by the power supplies. In contrast, a system power manager may manage power consumption based on digital representations of the power supplied by the power supplies, which may refresh the digital representations less quickly than the rate at which the analog current based representation is refreshed.

Abstract: Methods and systems for thermal management are disclosed. The thermal management method and systems may reduce the likelihood of a data processing system exceeding thermal limits even in cases of highly customizable and modifiable data processing system. To reduce the likelihood of the data processing system failing to meet thermal limits, the data processing system may implement a distributed thermal management system. The distributed thermal management system may include multiple components that are responsible for granular and/or global thermal management of the data processing system.

Abstract: A power management system includes a power infrastructure having power infrastructure components that couple computing devices to power source(s), and a power management subsystem coupled to the computing devices. The power management subsystem identifies power requirement information for each of the computing devices and power transmission limitation information for the power infrastructure components, and determines a power infrastructure architecture that identifies how the power infrastructure components couple the computing devices to the power source(s). The power management subsystem then uses the power requirement information, the power transmission limitation information, and the power infrastructure architecture to generate and provide a respective input current limit to each of the computing devices.

Abstract: Methods and systems for power management are disclosed. The disclosed power management method and systems may improve the likelihood of data processing systems providing desired computer implemented services while meeting power budget goals and/or other types of goals regarding power consumption, use, and/or provisioning. To improve the likelihood of the power budgets being met, the system may dynamically update power allocations to various components of data processing systems. The power allocations may be dynamically allocated by predicting how changes in existing power allocations may impact the ability of the data processing system to service power allocation requests. If it appears that changes in one or more existing power allocations may allow a power allocation request to be serviced, then the power allocations may be dynamically reallocated to free allocable power. The freed allocable power may be used to service the power allocation.

Abstract: Methods and systems for power management are disclosed. The disclosed power management method and systems may improve the likelihood of data processing systems providing desired computer implemented services while meeting power budget goals and/or other types of goals regarding power consumption, use, and/or provisioning. To improve the likelihood of the power budgets being met, the system may dynamically update power allocations to various components of data processing systems. The power allocations may be dynamically allocated by predicting how changes in existing power allocations may impact the ability of the data processing system to service power allocation requests. If it appears that changes in one or more existing power allocations may allow a power allocation request to be serviced, then the power allocations may be dynamically reallocated to free allocable power. The freed allocable power may be used to service the power allocation.

Abstract: Methods and systems for power management are disclosed. The disclosed methods and system for power management may reduce the likelihood of a data processing system failing to meet power budget or other types of goals regarding power consumption, use, and/or provisioning. To reduce the likelihood of the data processing system failing to meet power related goals, the data processing system may include two power managers. An integrated power manager may manage power consumption based on a current-based, fast changing representation of the quantity of power being supplied by the power supplies. In contrast, a system power manager may manage power consumption based on digital representations of the power supplied by the power supplies, which may refresh the digital representations less quickly than the rate at which the analog current based representation is refreshed.

Abstract: In one or more embodiments, one or more systems, methods, and/or processes may query each component of multiple components of a system for multiple power utilization attributes associated with the component; may determine a power budget based at least on each multiple power utilization attributes of each component of the multiple components; may determine an integer number of power supply units based at least on the power budget; may determine a fail safe power level based at least on power provided by the integer number of power supply units; may determine, based at least on the fail safe power level, multiple component fail safe power levels respectively associated with the multiple components of the system; and may provide, to each component of the multiple components, configuration information associated with a respective component fail safe power level, of the multiple component fail safe power levels, respectively associated with the component.

Abstract: In one or more embodiments, one or more systems, methods, and/or processes may determine that a number of operational power supply units is below a first threshold; may determine a first amount of power consumed by multiple information handling systems (IHSs); may determine that the first amount of power meets a second threshold; may initiate a first transfer of data from at least one volatile memory medium of a first information handling system (IHS) of the multiple IHSs to at least one non-volatile memory medium of the first IHS; may determine a second amount of power consumed by the multiple IHSs; and may determine that the second amount of power meets a third threshold; and may initiate a second transfer of data from at least one volatile memory medium of a second IHS of the multiple IHSs to at least one non-volatile memory medium of the IHS.

Abstract: In one or more embodiments, one or more systems, methods, and/or processes may query information handling systems (IHSs) for respective power consumption levels; may determine an amount of power utilized by the IHSs from the power consumption levels; may determine an integer number of power supply units (PSUs) based at least on the amount of power utilized by the IHSs; may determine that a number of operational PSUs changes; may determine that the number of operational PSUs is not at or above a threshold number; may determine if the number of operational PSUs is at or above the integer number of PSUs; if the number of operational PSUs is at or above the integer number of PSUs, may determine that the number of operational PSUs changes; and otherwise, may provide throttle down information to the IHSs.

Abstract: In one or more embodiments, one or more systems, methods, and/or processes may query information handling systems (IHSs) for respective power consumption levels; may determine an amount of power utilized by the IHSs from the power consumption levels; may determine an integer number of power supply units (PSUs) based at least on the amount of power utilized by the IHSs; may determine that a number of operational PSUs changes; may determine that the number of operational PSUs is not at or above a threshold number; may determine if the number of operational PSUs is at or above the integer number of PSUs; if the number of operational PSUs is at or above the integer number of PSUs, may determine that the number of operational PSUs changes; and otherwise, may provide throttle down information to the IHSs.

Abstract: In one or more embodiments, one or more systems, processes, and/or methods may determine first power supply units associated with a first power supply grid of power supply grids that are configured to provide power to information handling systems (IHSs) and second power supply units associated with a second power supply grid of the power supply grids; may determine that the power supply grids are configured for grid redundancy; may determine that a number of operational power supply units of the first power supply units meets a minimum number of operational power supply units to provide power to the IHSs; may determine that a number of operational power supply units of the second power supply units not the minimum number of operational power supply units; and may suppress an alert of at least one of the second power supply units that is not operational to provide power to the IHSs.

Abstract: In one or more embodiments, one or more systems, processes, and/or methods may determine first power supply units associated with a first power supply grid of power supply grids that are configured to provide power to information handling systems (IHSs) and second power supply units associated with a second power supply grid of the power supply grids; may determine that the power supply grids are configured for grid redundancy; may determine that a number of operational power supply units of the first power supply units meets a minimum number of operational power supply units to provide power to the IHSs; may determine that a number of operational power supply units of the second power supply units not the minimum number of operational power supply units; and may suppress an alert of at least one of the second power supply units that is not operational to provide power to the IHSs.

Abstract: In one or more embodiments, one or more systems, methods, and/or processes may query each component of multiple components of a system for multiple power utilization attributes associated with the component; may determine a power budget based at least on each multiple power utilization attributes of each component of the multiple components; may determine an integer number of power supply units based at least on the power budget; may determine a fail safe power level based at least on power provided by the integer number of power supply units; may determine, based at least on the fail safe power level, multiple component fail safe power levels respectively associated with the multiple components of the system; and may provide, to each component of the multiple components, configuration information associated with a respective component fail safe power level, of the multiple component fail safe power levels, respectively associated with the component.

Abstract: In one or more embodiments, one or more systems, methods, and/or processes may determine that a number of operational power supply units is below a first threshold; may determine a first amount of power consumed by multiple information handling systems (IHSs); may determine that the first amount of power meets a second threshold; may initiate a first transfer of data from at least one volatile memory medium of a first information handling system (IHS) of the multiple IHSs to at least one non-volatile memory medium of the first IHS; may determine a second amount of power consumed by the multiple IHSs; and may determine that the second amount of power meets a third threshold; and may initiate a second transfer of data from at least one volatile memory medium of a second IHS of the multiple IHSs to at least one non-volatile memory medium of the IHS.

Abstract: Optimized bus powered peripheral battery charging includes a circuit to initiate a change in an advanced configuration and power interface (ACPI) state in a controller allowing charging of a peripheral device battery, the circuit including a signal converter coupled between an input port and the controller to sense when a the peripheral device battery is coupled to an input port and to restrict the controller from changing ACPI state multiple times for a given peripheral device battery coupling; and a ground loop detector coupled in parallel to the signal converter between the input port and the controller to allow the controller to know that the peripheral device battery has maintained being coupled to the input port.

Abstract: An information handling system (IHS) remote input/output (I/O) connection system includes an enclosure having a power button, a communication bus connection point, and an audio connection point. A cable dongle extends from the enclosure. The cable dongle has a first end and a second end. The cable dongle also includes a connection from the power button on the enclosure on the first end to a communication connection point plug on the second end, which mates with a connection point plug on a remote I/O device card that enables a parallel (ACPI) S5-capable power button from the IHS to exist on the enclosure. The cable dongle further includes a communication cable coupled to the communication bus connection point on the first end and having a communication connection point plug on the second end. In addition, the cable dongle includes an audio cable coupled to the audio connection point on the first end and having an audio connection point plug on the second end.

Abstract: An event recognition and response system includes an event sensor. An event recognition engine is coupled to the event sensor. An action profile database is coupled to the event recognition engine. The event recognition engine is operable to receive an event input from the event sensor, compare the event input to a plurality of action profiles in the action profile database and, upon determining that at least one action profile in the action profile database matches the event input, perform a predetermined action.

Abstract: An information handling system (IHS) remote input/output (I/O) connection system includes an enclosure having a power button, a communication bus connection point, and an audio connection point. A cable dongle extends from the enclosure. The cable dongle has a first end and a second end. The cable dongle also includes a connection from the power button on the enclosure on the first end to a communication connection point plug on the second end, which mates with a connection point plug on a remote I/O device card that enables a parallel (ACPI) S5-capable power button from the IHS to exist on the enclosure. The cable dongle further includes a communication cable coupled to the communication bus connection point on the first end and having a communication connection point plug on the second end. In addition, the cable dongle includes an audio cable coupled to the audio connection point on the first end and having an audio connection point plug on the second end.

Abstract: Optimized bus powered peripheral battery charging includes a circuit to initiate a change in an advanced configuration and power interface (ACPI) state in a controller allowing charging of a peripheral device battery, the circuit including a signal converter coupled between an input port and the controller to sense when a the peripheral device battery is coupled to an input port and to restrict the controller from changing ACPI state multiple times for a given peripheral device battery coupling; and a ground loop detector coupled in parallel to the signal converter between the input port and the controller to allow the controller to know that the peripheral device battery has maintained being coupled to the input port.

Abstract: Optimized bus powered peripheral battery charging includes a circuit to initiate a change in an advanced configuration and power interface (ACPI) state in a controller allowing charging of a peripheral device battery, the circuit including a signal converter coupled between an input port and the controller to sense when a the peripheral device battery is coupled to an input port and to restrict the controller from changing ACPI state multiple times for a given peripheral device battery coupling; and a ground loop detector coupled in parallel to the signal converter between the input port and the controller to allow the controller to know that the peripheral device battery has maintained being coupled to the input port.