Disclosed is a voltage reference buffer circuit including a first, second, third, and fourth bias generators and a first, second, third, and fourth driving components. The first, second, third, and fourth bias generators generate bias voltages to control the first, second, third, and fourth driving components respectively. The first, second, third, and fourth driving components are coupled in sequence, wherein the first and second driving components are different types of transistors and jointly output a first reference voltage, the third and fourth driving components are different types of transistors and jointly output a second reference voltage, and the group of the first and second driving components is separated from the group of the third and fourth driving components by a resistance load.

Disclosed is a voltage reference buffer circuit including a first, second, third, and fourth bias generators and a first, second, third, and fourth driving components. The first, second, third, and fourth bias generators generate bias voltages to control the first, second, third, and fourth driving components respectively. The first, second, third, and fourth driving components are coupled in sequence, wherein the first and second driving components are different types of transistors and jointly output a first reference voltage, the third and fourth driving components are different types of transistors and jointly output a second reference voltage, and the group of the first and second driving components is separated from the group of the third and fourth driving components by a resistance load.

The present invention relates to the field of battery powered electrical appliances or personal hygiene, in particular to a hair removal device such as an electric shaver or epilator as well as an electric toothbrush. A control device for a battery powered electrical appliance for personal hygiene is described, wherein the control device is adapted to cause the battery powered electrical appliance to perform automated contact fritting of a battery contact by controlling the battery powered electrical appliance such that a current pulse exceeding a wetting threshold is applied across the battery contact during a standby period.

A gallium nitride (GaN) transistor-based regulated voltage source has a reference voltage input coupled to a reference voltage. The regulated voltage source also includes an input port and an output port. The regulated voltage source includes a GaN transistor-based voltage regulation path coupling the input port and the output port with at least a GaN regulation transistor with a threshold voltage and that is formed on a substrate. The regulated voltage source also includes a GaN transistor-based voltage compensator having an intermediate GaN transistor that is also formed on the substrate. The GaN transistor-based voltage compensator couples a gate of the GaN regulation transistor to the reference voltage input and introduces a voltage drop between the gate of the GaN regulation transistor and the reference voltage input to compensate for the threshold voltage of the GaN regulation transistor.

A LED driving system has an energy storage component receiving an input voltage, a power switch coupled between the energy storage component and a reference ground, a first output switch coupled between the energy storage component and a first output terminal, a second output switch coupled between the energy storage component and a second output terminal, and a control circuit, wherein the first output terminal produces a first output voltage to supply power for a first LED array, the second output terminal produces a second output voltage to supply power for a second LED array, the control circuit controls a duty cycle of the first output switch according to voltages at cathode terminals of multiple LED strings in the LED array and controls a duty cycle of the second output switch according to voltages at cathode terminals of multiple LED strings in the second LED array.

A LED driving system has an energy storage component receiving an input voltage, a power switch coupled between the energy storage component and a reference ground, a first output switch coupled between the energy storage component and a first output terminal, a second output switch coupled between the energy storage component and a second output terminal, and a control circuit, wherein the first output terminal produces a first output voltage to supply power for a first LED array, the second output terminal produces a second output voltage to supply power for a second LED array, the control circuit controls a duty cycle of the first output switch according to voltages at cathode terminals of multiple LED strings in the LED array and controls a duty cycle of the second output switch according to voltages at cathode terminals of multiple LED strings in the second LED array.

An alternating-current (AC) voltage regulator including an isolated power supply, a control circuit, an amplifier, and an output. The isolated power supply is configured to receive an input voltage and output a direct-current (DC) signal isolated from the input voltage. The control circuit is configured to adjust a portion of the input voltage, and output an adjusted voltage. The amplifier is configured to output a differential signal. The differential signal is based on at least one selected from a group consisting of the isolated DC signal, the adjusted voltage, and a feedback loop. The output is configured to add the differential signal to the input voltage resulting in a regulated voltage, and output the regulated voltage.

A switching power converter comprising an inductor and one or more switches and configured to operate in a discontinuous operating mode comprises a clamp circuit connected to the ends of the inductor for trapping energy in the inductor during a clamp period. The clamp circuit comprises a first and a second clamp switch connected in series, the clamp circuit arranged and configured to block a voltage of either polarity when both switches are OFF; conduct a current of either polarity when both switches are ON; conduct uni-directionally in one direction when one of the clamp switches is ON; and conduct uni-directionally in the other direction when the other one of the clamp switches is ON. A controller turns the one or more switches ON and OFF to transfer energy from the input to the inductor and from the inductor to the output during an energy transfer phase.

A switching power converter comprising an inductor and one or more switches and configured to operate in a discontinuous operating mode comprises a clamp circuit connected to the ends of the inductor for trapping energy in the inductor during a clamp period. The clamp circuit comprises a first and a second clamp switch connected in series, the clamp circuit arranged and configured to block a voltage of either polarity when both switches are OFF; conduct a current of either polarity when both switches are ON; conduct uni-directionally in one direction when one of the clamp switches is ON; and conduct uni-directionally in the other direction when the other one of the clamp switches is ON. A controller turns the one or more switches ON and OFF to transfer energy from the input to the inductor and from the inductor to the output during an energy transfer phase.

A controller for use with a power converter including a switch configured to conduct to provide a regulated output characteristic at an output of the power converter, and method of operating the same. In one embodiment, the controller includes a linear control circuit, coupled to the output, configured to provide a first control signal for the switch as a function of the output characteristic. The controller also includes a nonlinear control circuit, coupled to the output, configured to provide a second control signal for the switch as a function of the output characteristic. The controller is configured to select one of the first and second control signals for the switch in response to a change in an operating condition of the power converter.