A method of operating a power up circuit is disclosed. The method includes receiving an input voltage and creating a plurality of sample voltages from the input voltage. One of the sample voltages is selected and compared to a reference voltage. The power up circuit produces a brown-out signal in response to the step of comparing.

Methods, systems, and devices for back-bias optimization are described. An apparatus, such as an electronic apparatus, may include a first substrate region and a second substrate region. The apparatus may also include a voltage generator that is disposed on the first substrate region and that includes an output terminal coupled with a conductive path. The apparatus may also include a set of clamp circuits disposed on the second substrate region. The set of clamp circuits may be configured selectively couple the conductive path with a voltage supply.

An energy planning system that proposes an appropriate energy plan for a home includes: a sensor that senses a state of an energy facility in a home; a predictor that predicts a future lifestyle of a resident of the home; and a proposer that determines information about an energy plan for the home based on a result of the sensing by the sensor and the lifestyle predicted by the predictor, and outputs the information.

An energy planning system that proposes an appropriate energy plan for a home includes: a sensor that senses a state of an energy facility in a home; a predictor that predicts a future lifestyle of a resident of the home; and a proposer that determines information about an energy plan for the home based on a result of the sensing by the sensor and the lifestyle predicted by the predictor, and outputs the information.

A system and method are provided for regulating a voltage level at a load. A current source generates a current and a voltage control mechanism provides a portion of the current to regulate the voltage level at the load. When the voltage level at the load is greater than a maximum voltage level, the current source is decoupled from the load and the current source is coupled to a current sink to reduce the voltage level at the load. An electric power conversion comprises the current source and the voltage control mechanism. A downstream controller is configured to control the voltage control mechanism to decouple the current source from the load and couple the current source to a current sink to reduce the voltage level at the load when the voltage level at the load is greater than a maximum voltage level.

This invention is an electronic circuit with a low power retention mode. A single integrated circuit includes a circuit module and a droop switch circuit supplied by a voltage regulator. In a normal mode a PMOS source-drain channel connects the voltage regulator power to the circuit module power input or isolates them dependent upon a power switch input. In a low power mode a second PMOS connected between the first PMOS gate and output diode connects the first PMOS. This supplied the circuit module from the voltage regulator power as reduced in voltage by a diode forward bias drop. This lower voltage should be sufficient for flip-flops in the circuit module to retain their state while not guaranteeing logic operation. There may be a plurality of chain connected droop switch each powering a corresponding circuit module.

A DC-DC power converter is described having a power converter input for receiving a supply voltage; a power converter output for outputting a converted supply voltage; a reference input for supplying a reference value; a switch capacitor power converter coupled to the power converter input and the power converter output and comprising at least one switchable capacitor controllable by at least two non-overlapping clock signals; a controller coupled to the switch capacitor power converter, and the power converter output. The controller is configured to generate at least two non-overlapping clock signals and to vary the non-overlapping time duration dependent on the voltage and/or current value of at least one of the power converter output, the reference input, and the power converter input.

A controller includes a tracking regulator having a reference voltage input and a voltage output and configured to regulate the voltage output to the reference voltage input. The controller is configured to, in response to a short to ground of the voltage output, electrically couple the reference voltage input to the voltage output.

An apparatus includes a signal generator and a control circuit. The signal generator includes a control terminal and includes a current electrode coupled to a terminal that is configured to couple to a power line to receive direct current (DC) power from a power generator. The control circuit is coupled to the current electrode and the control terminal of the signal generator. The control circuit determines an impedance associated with the power generator and applies a control signal to the control terminal of the signal generator to produce an impedance adjustment signal on the current electrode for communication to the power generator through the power line in response determining the impedance.

A cascaded configuration of regulator circuits can be co-integrated within a commonly-shared integrated circuit package (such as an integrated electronic module). Such co-integration can include placing a switched-mode regulator circuit in close proximity to a linear regulator circuit. Magnetic field coupling between the regulator circuits is generally a non-linear function of a separation between the circuits. The switched-mode regulator circuit can generate noise that may adversely impact the linear regulator output. Magnetic coupling between the regulator circuits within the module package can be suppressed or eliminated using a magnetic barrier. The barrier can be magnetically permeable and electrically non-conductive.