In accordance with embodiments of the present disclosure, a method for power loss protection of one or more storage resources may include receiving information from each of the one or more storage resources regarding power loss protection capabilities of such storage resource. The method may also include based on the information, repurposing, for each power loss protection capable storage resource, a communications channel between a logic device and such power loss protection capable storage resource for transmission of a respective early power-off warning signal for such power loss protection capable storage resource. The method may further include in response to a power event of a power supply unit for providing electrical energy to the one or more storage resources, asserting for each power loss protection capable storage resource its respective early power-off warning signal.

A graceful shutdown of a computer system is initiated by sending a command to an asynchronous dynamic random access memory refresh (ADR) trigger device to assert an ADR trigger. Responsive to the command, the ADR trigger device asserts the ADR trigger to initiate an ADR of a non-volatile dual in-line memory module (NVDIMM) of the computer system. In response to the ADR trigger being asserted by the ADR trigger device, an ADR of the NVDIMM is performed before completing the graceful shutdown of the computer.

Processor-based systems employing local dynamic power management based on controlling performance and operating power consumption, and related methods. The processor-based system is configured to locally manage its power consumption by dynamically adjusting operating frequency and/or operating voltage of power supplied to the processor-based system. The processor-based system includes a power control circuit that is aware of the overall power budget for the processor-based system. The control processor in the processor-based system can dynamically increase the voltage level of the power supplied to the processor-based system and/or the operating frequency if the consumed power is lower than the power budget. The power control circuit can also dynamically decrease the operating frequency and/or the voltage level of the power supplied to the processor-based system if the consumed power is higher than the power budget.

According to at least one example embodiment, a method and corresponding apparatus for controlling power in a multi-core processor chip include: accumulating, at a controller within the multi-core processor chip, one or more power estimates associated with multiple core processors within the multi-core processor chip. A global power threshold is determined based on a cumulative power estimate, the cumulative power estimate being determined based at least in part on the one or more power estimates accumulated. The controller causes power consumption at each of the core processors to be controlled based on the determined global power threshold. The controller may directly control power consumption at the core processors or may command the core processors to do so.

According to at least one example embodiment, a method and corresponding apparatus for controlling power in a multi-core processor chip include: accumulating, at a controller within the multi-core processor chip, one or more power estimates associated with multiple core processors within the multi-core processor chip. A global power threshold is determined based on a cumulative power estimate, the cumulative power estimate being determined based at least in part on the one or more power estimates accumulated. The controller causes power consumption at each of the core processors to be controlled based on the determined global power threshold. The controller may directly control power consumption at the core processors or may command the core processors to do so.

In some embodiments, clock input buffer circuitry and divider circuitry use a combination of externally-suppled voltages and internally-generated voltages to provide the various clock signals used by a semiconductor device. For example, a clock input buffer is configured to provide second complementary clock signals responsive to received first complementary clock signals using cross-coupled buffer circuitry coupled to a supply voltage and to drive the first complementary clock signals using driver circuitry coupled to an internal voltage. In another example, a divider circuitry may provide divided clock signals based on the second complementary clock signals via a divider coupled to the internal voltage and to drive the divided clock signals using driver circuitry coupled to the supply voltage. A magnitude of the supply voltage may be less than a magnitude of the internal voltage.

In some embodiments, clock input buffer circuitry and divider circuitry use a combination of externally-suppled voltages and internally-generated voltages to provide the various clock signals used by a semiconductor device. For example, a clock input buffer is configured to provide second complementary clock signals responsive to received first complementary clock signals using cross-coupled buffer circuitry coupled to a supply voltage and to drive the first complementary clock signals using driver circuitry coupled to an internal voltage. In another example, a divider circuitry may provide divided clock signals based on the second complementary clock signals via a divider coupled to the internal voltage and to drive the divided clock signals using driver circuitry coupled to the supply voltage. A magnitude of the supply voltage may be less than a magnitude of the internal voltage.

Provided is a control method including: receiving, from first power equipment, first transaction data including, for example, transmitted power amount information indicating the amount of power transmitted to power accumulation equipment; obtaining, from the power accumulation equipment, received power information including, for example, received power amount information indicating the amount of power received from the first power equipment; verifying the first transaction data by referring to the received power information; executing a first consensus algorithm with second servers when the first transaction data is verified successfully; and recording a block including the first transaction data in a distributed ledger of a first server when the validity of the first transaction data is verified through the first consensus algorithm.

Provided is a control method including: receiving, from first power equipment, first transaction data including, for example, transmitted power amount information indicating the amount of power transmitted to power accumulation equipment; obtaining, from the power accumulation equipment, received power information including, for example, received power amount information indicating the amount of power received from the first power equipment; verifying the first transaction data by referring to the received power information; executing a first consensus algorithm with second servers when the first transaction data is verified successfully; and recording a block including the first transaction data in a distributed ledger of a first server when the validity of the first transaction data is verified through the first consensus algorithm.

A peak power management (PPM) system is provided for managing peak power operations between two or more NAND memory dies. The PPM system includes a PPM circuit on each NAND memory die. Each PPM circuit includes a first pull-up driver electrically connected to a first power source and a first end of a PPM resistor; a second pull-up driver electrically connected to a second power source and a second end of the PPM resistor; a pull-down driver electrically connected to the second end of the PPM resistor; and a PPM contact pad connected to the second end of the PPM resistor. The PPM contact pads of the two or more NAND memory dies are electrically connected with each other with a common electric potential. The PPM system is configured to manage peak power operations according to the electric potential of the PPM contact pads.