A charge pump circuit includes a voltage input port, a voltage output port, a plurality of charge pump units cascaded between the voltage input port and the voltage output port, a clock signal source, and N clock delay elements. The clock signal source generates a main clock signal and the N clock delay elements generate clock signals received by the charge pump units by delaying the main clock signal. The main clock signal received by the first charge pump unit has a rising edge leading a rising edge of the last clock signal received by the last charge pump unit, and a falling edge lagging the rising edge of the last clock signal. Each of the charge pump units includes two sets of inverters with delay elements for generating two complementary clock signals.

A charge pump includes a first pumping capacitor configured to pump a first voltage of a first node, in response to a first clock signal, a gate pumping capacitor configured to pump a second voltage of a second node, in response to a second clock signal, a charge transfer transistor including a first source connected to a first one of a third node and the first node, a first gate connected to the second node, and a first drain connected to a remaining one of the first node and the third node, a gate control transistor including a second source connected to the first one of the third node and the first node, a second gate connected to the remaining one of the first node and the third node, and a second drain connected to the second node, and a gate discharge or charge unit.

During its first and second residence times, corresponding first and second currents flow between a charge pump and a circuit that connects to one of the charge pump's terminals. Based on a feedback measurement from the charge pump, a controller adjusts these first and second currents.

A control method used in a switched tank converter with a first conversion unit, a second conversion unit and a rectification unit, includes: based on current flowing through the resonant tanks in the first and second conversion units, determining when to turn on the high side switches of the first and second conversion units, and when to turn on the low side switches of the first and second conversion units; detecting whether current flowing through the first, second, third and fourth rectification switches crosses zero; and based on the detection result, respectively determining when to turn off the high side switch of the first conversion unit, when to turn off the high side switch of the second conversion unit, when to turn off the low side switch of the second conversion unit, and when to turn off the low side switch of the first conversion unit.

A cascade multiplier includes a switch network having switching elements, a phase pump, and a network of pump capacitors coupled with the phase pump and to the switch network. The network of pump capacitors includes first and second capacitors, both of which have one terminal DC coupled with the phase pump, and a third capacitor coupled with the phase pump through the first capacitor.

A voltage generator includes an oscillator, a charge pump, a smoothing capacitor, and a driving controller. The oscillator has an output. The charge pump has an input and an output, and the input of the charge pump is coupled to the output of the oscillator. The smoothing capacitor is coupled to the output of the charge pump. The driving controller is coupled to the oscillator, and generates an enable signal to adjust an operation frequency of the oscillator. The voltage generator supplies a driving voltage to a switch for driving the switch via the smoothing capacitor. The driving controller generates the enable signal according to the driving voltage.

A semiconductor device including: a semiconductor substrate; at least one circuit block provided on a main surface of the semiconductor substrate and having a predetermined function; a wiring layer including plural metal layers that connect the circuit block; and plural capacitors including a first capacitor connected to the circuit block and that uses the plurality of metal layers, and a second capacitor that uses an active area disposed within the main surface of the semiconductor substrate, wherein at least one of the first capacitor and at least one of the second capacitor are stacked in a stacking direction of layers of the semiconductor.

Transient or fault conditions for a switched capacitor power converter are detected by measuring one or more of internal voltages and/or currents associated with switching elements (e.g., transistors) or phase nodes, or voltages or currents at terminals of the converter, and based on these measurements detect that a condition has occurred when the measurements deviate from a predetermined range. Upon detection of the condition fault control circuitry alters operation of the converter, for example, by using a high voltage switch to electrically disconnect at least some of the switching elements from one or more terminals of the converter, or by altering timing characteristics of the phase signals.

An apparatus for converting a first voltage into a second voltage includes a reconfigurable switched capacitor power converter having a selectable conversion gain. The power converter has switch elements configured to electrically interconnect capacitors to one another and/or to the first or second voltage in successive states. The switch elements are configured to interconnect at least some capacitors to one another through the switch elements. A controller causes the reconfigurable switched capacitor power converter to transition between first and second operation modes. The controller minimizes electrical transients arising from transition between modes. In the first operating mode, the power converter operates with a first conversion gain. In the second operating mode, it operates with a second conversion gain.

A multi-stage charge pump circuit including a first stage of the multi-stage charge pump having a first voltage output, a last stage of the multi-stage charge pump having a first voltage input, and an inter-stage limitation circuit configured to protect a voltage drop of the first voltage output of the first stage of the multi-stage charge pump when there is a voltage drop on the first voltage input of the last stage of the multi-stage charge pump.