A low power docking station and a power consumption monitoring method thereof are provided. The low power docking station includes a processing module, a monitoring module, a power supply module, and a power supply control module. The processing module is used for interpreting, transcoding, and distributing the input data to peripheral ports. The monitoring module is used for monitoring whether or not the plurality of peripheral ports is connected to a peripheral device to generate a corresponding one of a monitoring signal. The power supply module is used for supplying power to the plurality of peripheral ports, the processing module, and the monitoring module. The power supply control module is connected to the monitoring module and the power supply module. The power supply control module is used for controlling the power supply module to output power according to the monitoring signal.

A low power docking station and a power consumption monitoring method thereof are provided. The low power docking station includes a processing module, a monitoring module, a power supply module, and a power supply control module. The processing module is used for interpreting, transcoding, and distributing the input data to peripheral ports. The monitoring module is used for monitoring whether or not the plurality of peripheral ports is connected to a peripheral device to generate a corresponding one of a monitoring signal. The power supply module is used for supplying power to the plurality of peripheral ports, the processing module, and the monitoring module. The power supply control module is connected to the monitoring module and the power supply module. The power supply control module is used for controlling the power supply module to output power according to the monitoring signal.

A method of peak power management (PPM) is provided for two NAND memory dies. each NAND memory die comprises a PPM circuit having a PPM contact pad held at an electric potential common between the two NAND memory dies. The method includes the following steps: detecting the electric potential during a first peak power check (PPC) routine for the first NAND memory die; driving the electric potential to a second voltage level if the detected electric potential is at a first voltage level higher than the second voltage level; generating a pausing signal in the electric potential to pause a second PPC routine for the second NAND memory die if no pausing signal is detected; and generating a resuming signal in the electric potential to resume the second PPC routine for the second NAND memory die after the first NAND memory die completes a first peak power operation.

A control method of a power supply path includes detecting a plug-in state of a first connector through a configuration channel pin of the first connector; acquiring a plurality of rated voltages of a first power adaptor externally connected to the first connector and a rated current corresponding to each of the rated voltages; detecting a plug-in state of a second connector through a direct-current (DC) input pin of the second connector; acquiring a power quota of a second power adaptor externally connected to the second connector; selecting, from the plurality of rated voltages, the largest one that is not greater than an operating voltage, as a selected rated voltage; calculating a power quota of the selected rated voltage; and controlling a switching circuit to couple a power circuit to a power pin of one of the first and second connectors according to the two power quotas.

In an embodiment, an electronic device includes a first near field communication module, at least one second communication module, at least one portion of a volatile memory, at least one register, and at least one first circuit configured to activate the near field communication module, wherein the at least one second communication module is configured to power the at least one portion of the volatile memory, the at least one register and the at least one first circuit with a first supply voltage when the electronic device is in an on state and when the first near field communication module is in a standby mode.

In an embodiment, an electronic device includes a first near field communication module, at least one second communication module, at least one portion of a volatile memory, at least one register, and at least one first circuit configured to activate the near field communication module, wherein the at least one second communication module is configured to power the at least one portion of the volatile memory, the at least one register and the at least one first circuit with a first supply voltage when the electronic device is in an on state and when the first near field communication module is in a standby mode.

An energy-aware system is provided. The system includes an energy harvester adapted to supply harvested energy as an output for storage at an energy storage; and a scheduler, the scheduler being made up of, at least in part, hardware of the energy-aware system, the scheduler operable to schedule execution of operations performed by the energy-aware system, wherein the scheduler is configured to: determine if a current voltage level at the energy storage is higher than a start voltage level; and cause initiation of execution of at least a portion one of the operations when the start voltage of the one of the operations levels is lower than or equal to the current voltage level.

An energy-aware system is provided. The system includes an energy harvester adapted to supply harvested energy as an output for storage at an energy storage; and a scheduler, the scheduler being made up of, at least in part, hardware of the energy-aware system, the scheduler operable to schedule execution of operations performed by the energy-aware system, wherein the scheduler is configured to: determine if a current voltage level at the energy storage is higher than a start voltage level; and cause initiation of execution of at least a portion one of the operations when the start voltage of the one of the operations levels is lower than or equal to the current voltage level.

Power supply efficiency may be provided. First, a total power supply capacity may be determined comprising a sum of a plurality of supply capacities respectively corresponding to a plurality of power supplies serving a plurality of components. Next, a load value corresponding to the plurality of components may be determined. A number of the plurality of power supplies may then be powered down. The number of power supplies powered down may comprise a value that may cause a remaining number of the plurality of power supplies serving the plurality of components to operate within an efficiency range.

Power supply efficiency may be provided. First, a total power supply capacity may be determined comprising a sum of a plurality of supply capacities respectively corresponding to a plurality of power supplies serving a plurality of components. Next, a load value corresponding to the plurality of components may be determined. A number of the plurality of power supplies may then be powered down. The number of power supplies powered down may comprise a value that may cause a remaining number of the plurality of power supplies serving the plurality of components to operate within an efficiency range.