A power regulator provides current to a processing unit. A clock distribution network provides a clock signal to the processing unit. A level-based droop detector monitors a voltage of the current provided to the processing unit and provides a droop detection signal to the clock distribution network in response to the voltage falling below a first threshold voltage. The clock distribution network decreases a frequency of a clock signal provided to the processing unit in response to receiving the droop detection signal. The level-based droop detector interrupts the droop detection signal that is provided to the clock distribution network in response to the voltage rising above a second threshold voltage. The clock distribution network increases the frequency of the clock signal provided to the processing unit in response to interruption of the droop detection signal.

This disclosure relates to current flattening circuits for an electrical load. The current flattening circuits incorporate randomize various parameters to add noise onto the supply current. This added noise may act to reduce the signal to noise ratio in the supply current, increasing the difficulty of identifying a computational artifact signal from power rail noise.

A method of controlling a power consumption of a media stream reproducing device having a wide input voltage range power supply includes receiving a media stream and providing an output signal representative of the received media stream. A mains supply voltage of the media stream receiver is monitored and, in case the measured mains supply voltage falls below a first level the method further includes one or more of providing an output signal representative of a message indicating the reduced mains supply voltage and advising a user to reduce the power consumption of at least the media stream reproducing device, or providing an output signal controlling a first reduction of the power consumption of the media stream reproducing device, or controlling a recording device operatively connected to the media stream reproducing device to record the received media stream for later reproduction.

A system includes a memory device and a processing device, operatively coupled to the memory device, the processing device to perform operations comprising: measuring one of a temperature voltage shift or a read bit error rate of fixed data stored in the memory device in response to detecting a power on of the memory device, the fixed data having been programmed in response to detecting a power loss; estimating an amount of time for which the memory device was powered off based on results of the measuring; and in response to the amount of time satisfying a threshold criterion, updating a value for a temporal voltage shift of a block family based on the amount of time.

The disclosure describes examples of integrate circuit (IC) chips. An IC chip includes a first detector configured to generate information indicative of whether an input supply voltage or power is greater than or equal to a first threshold, a second detector configured to receive a circuit voltage or current level and generate information used to indicate a status of the IC chip based on the received circuit voltage or current level, and a controller configured to cause the IC chip to enter a safe mode in response to both the first detector indicating that the input supply voltage or power is greater than the first threshold and the circuit voltage or current level being greater than a second threshold.

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.

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.

An example method includes detecting an event in an electronic system. The electronic system includes an electronic component and a switched mode power supply. The electronic component draws an amount of power from the switched mode power supply during operation. In response to detecting the event, the electronic component is operated to cause the electronic component to change the amount of power that the electronic component draws from the switched mode power supply. The change in the amount of power that the electronic component draws causes the switched mode power supply to output a signal that is evidence of the event.

Disclosed herein are a vehicle or other system battery with a self-contained backup capability and a method for providing power to a vehicle using the vehicle or other system battery with a self-contained backup capability. In one aspect, the vehicle battery comprises, a main battery portion, a backup battery portion, and a control device for selectively communicating a transfer of energy from the backup battery portion to the main battery portion when a voltage level or other health indicator of the main battery portion is determined to be below a reference voltage threshold, wherein the main battery portion and backup battery portion are each re-chargeable via an alternator of the vehicle when the control device communicates the transfer of energy between the main battery portion and the backup battery portion.

One or more sampling parameters of an application associated with a downstream voltage regulator may be determined. A power supply rejection ratio (“PSRR”) and a switching frequency of an upstream voltage regulator may be dynamically adjusted based on the sampling parameters of the application associated with the downstream voltage regulator. The sampling parameters may include a noise level and a workload of the selected application.