A charger integrated circuit is configured to charge a battery device including a first battery and a second battery connected in series. The circuit includes a direct charger configured to generate a first charging current and a first current based on an input voltage received from an input terminal, the first current used to generate a first system current, and a buck converter configured to generate a second current and a second system current based on the input voltage, the second current used to generate a second charging current. The circuit includes a switched capacitor configured to generate the first system current based on the first current, and to generate the second charging current based on the second current, and a linear charger configured to provide the first charging current and the second charging current to the battery device.

A bipolar output charge pump circuit having a network of switching paths for selectively connecting an input node and a reference node for connection to an input voltage, a first pair of output nodes, two pairs of flying capacitor nodes, and a controller for controlling the switching of the network of switching paths. The controller is operable to control the network of switching paths when in use with two flying capacitors connected to the two pairs of flying capacitor nodes, to provide a first mode and a second mode when in use with two flying capacitors connected to the flying capacitor nodes, wherein at least the first mode corresponds to a bipolar output voltage of +/−3VV, +/−VV/5 or +/−VV/6.

A resonant switching power converter includes: capacitors; switches; at least one charging inductor; at least one discharging inductor; a controller generating a charging operation signal corresponding to charging process and discharging operation signals corresponding to discharging processes, to operate the switches to switch electrical connection relationships of the capacitors. In the charging process, the controller controls the switches via the charging operation signal, so that a series connection of the capacitors and the charging inductor is formed between the input voltage and the output voltage, which forms a charging path. In the discharging processes, the controller controls the switches via the discharging operation signals, so that a series connection of one of the capacitors and the discharging inductor is formed between the output voltage and a ground voltage level, to form plural discharging paths at different periods in a sequential order.

A switched capacitor voltage converter includes an inductive branch and two branches, by controlling a turning on and off of switch transistors, charges on a parasitic capacitor of one branch are completely transferred to another branch of the two branches via the inductive branch within a period of time after primary switch transistors are turned off, and voltage difference between both terminals of each of the primary switch transistors become zero, and then the primary switch transistors are started to be turned on, the respective voltage differences of the primary switch transistors are zero at a moment when the primary switch transistors are turned on.

The present document describes a power converter configured to convert electrical power at an input voltage at an input of the power converter to electrical power at an output voltage at an output of the power converter. The power converter comprises a first upper capacitor and a first lower capacitor, which are coupled with one another via a first mid node; a second upper capacitor and a second lower capacitor, which are coupled with one another via a second mid node; an inductor; and a set of power switches. In addition, the power converter comprises a control unit which is configured to control the set of power switches such that during an operation cycle the power converter is operated in a first main state and in a second main state in a mutually exclusive manner.

A circuit including: a three-level buck converter having: a plurality of input switches and an inductor configured to receive a voltage from the plurality of input switches, the plurality of input switches coupled with a first capacitor and configured to charge and discharge the first capacitor; a second capacitor at an output of the buck converter; and a switched capacitor at an input node of the inductor, wherein the switched capacitor is smaller than either the first capacitor or the second capacitor.

In accordance with an aspect of the disclosure, an electronic device comprises: a battery; a receive coil configured to wirelessly receive power from a transmit coil of an external power device; and a power management module electrically connected with the battery and the receive coil, wherein the power management module includes: a rectifier circuit configured to rectify current flowing in the receive coil, the rectifier circuit including an output terminal; a charging circuit configured to charge the battery including a plurality of switches and an input terminal, the input terminal connected to the output terminal of the rectifier circuit; and a rectifying capacitor electrically connected with the output terminal of the rectifier circuit and the input terminal of the charging circuit, and wherein the power management module generates a sync signal based on current flowing in the output terminal of the rectifier circuit and controls whether the plurality of switches operate or switching frequencies of the plurality of switches, based on the sync signal.

A power conversion circuit is provided. In the power conversion circuit, a three-switch unit of a switch bridge arm includes first, second and third terminals and upper, middle and lower switches serially connected between the first and third terminals sequentially. The upper and lower switches are turned on and off synchronously. A grounding switch is coupled between the third terminal and a negative input terminal. A cross-connected storage capacitor is electrically connected between a node between the upper and middle switches and the third terminal. A diode, a capacitor and a driving unit of a floating driving circuit are electrically connected between the upper and lower switches. A connection node between the diode and the capacitor is electrically connected to a driving terminal of the upper switch. A connection node between the capacitor and the driving unit is electrically connected to a driving terminal of the lower switch.

A power conversion circuit is provided. According to the topologies of power conversion circuits and the corresponding control manners of the present disclosure, the output voltage is greatly reduced relative to the input voltage, and thus the function of voltage reduction is achieved. Moreover, a voltage-second product of the time and the voltage across the first output inductor and a voltage-second product of the time and the voltage across the second output inductor are both greatly reduced. Accordingly, the inductance, volume and loss of the first output inductor and the second output inductor are greatly reduced. Therefore, the voltage regulation module may receive the low output voltage outputted by the power conversion circuit, thereby reducing the overall volume of the voltage regulation module and increasing the power conversion density and conversion efficiency of the voltage regulation module.

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.