A Physical Unclonable Function, PUF, apparatus is disclosed. The apparatus comprises a plurality of PUF cells that each comprise a first potential divider and a second potential divider. The apparatus also comprises a determination unit that comprises a selection unit for selecting at least one of the plurality of PUF cells, and a readout unit coupled to each selected PUF cell. The readout unit is configured to determine a PUF value for the selected PUF cell based on a difference between a first analog voltage at the first potential divider and a second analog voltage at the second potential divider.

An Uninterrupted Power Supply (UPS) power supply system is provided, which includes: a filter module connected to a mains supply and configured to filter an input from the mains supply; a BOOST module, where a first terminal of the BOOST module is connected to the filter module via a first switch group and connected to a battery via a second switch group, and a second terminal of the BOOST module is connected to a positive bus and a negative bus; and a bi-directional Direct Current/Direct Current (DC/DC) module, where a first terminal of the bi-directional DC/DC module is connected to the battery, and a second terminal of the bi-directional DC/DC module is connected to the positive bus and the negative bus.

An Uninterrupted Power Supply (UPS) power supply system is provided, which includes: a filter module connected to a mains supply and configured to filter an input from the mains supply; a BOOST module, where a first terminal of the BOOST module is connected to the filter module via a first switch group and connected to a battery via a second switch group, and a second terminal of the BOOST module is connected to a positive bus and a negative bus; and a bi-directional Direct Current/Direct Current (DC/DC) module, where a first terminal of the bi-directional DC/DC module is connected to the battery, and a second terminal of the bi-directional DC/DC module is connected to the positive bus and the negative bus.

A dual-output flyback voltage conversion circuit and a display device are provided. The dual-output flyback voltage conversion circuit includes an input module, a voltage transformation module, an output module, and a feedback module. The input module is used for rectifying and filtering an input voltage. The voltage transformation module is used for performing a voltage conversion process on the input voltage which is obtained after rectifying and filtering. The output module is used for outputting a first output voltage and a second output voltage according to conversion voltages. The feedback module is used for controlling the voltage transformation module to output the input voltage which is obtained after rectifying and filtering according to the first output voltage and the second output voltage.

Embodiments of the present invention relate to the battery monitoring field, and provide a load power supply circuit and a terminal. The load power supply circuit includes a charging manager and a step-up circuit. The charging manager includes a first pin, a second pin, and a third pin. The first pin of the charging manager is electrically connected to a load, and the second pin of the charging manager is electrically connected to a battery. The step-up circuit includes a first end, a second end, and a control end. The first end of the step-up circuit is electrically connected to the load, the second end of the step-up circuit is electrically connected to the battery, and the control end of the step-up circuit is electrically connected to the third pin of the charging manager.

A dual-output flyback voltage conversion circuit is provided, including an input module, a voltage transformation module, an output module, and a feedback module. The input module is used for rectifying and filtering an input voltage. The voltage transformation module is used for performing a voltage conversion process on the input voltage which is obtained after rectifying and filtering. The output module is used for outputting a first output voltage and a second output voltage according to conversion voltages. The feedback module is used for controlling the voltage transformation module to output the input voltage which is obtained after rectifying and filtering according to the first output voltage and the second output voltage.

According to an embodiment, a semiconductor device includes: a first modulation circuit configured to generate a reference signal based on a first clock signal; a second modulation circuit configured to generate a feedback signal with a phase negative relative to a phase of the reference signal based on a second clock signal with a phase negative relative to a phase of the first clock signal; a comparator configured to compare the reference signal with the feedback signal to determine duty and generate a comparator signal; and a driver configured to output a drive signal.

According to an embodiment, a semiconductor device includes: a first modulation circuit configured to generate a reference signal based on a first clock signal; a second modulation circuit configured to generate a feedback signal with a phase negative relative to a phase of the reference signal based on a second clock signal with a phase negative relative to a phase of the first clock signal; a comparator configured to compare the reference signal with the feedback signal to determine duty and generate a comparator signal; and a driver configured to output a drive signal.

According to an embodiment, a semiconductor device includes: a first modulation circuit configured to generate a reference signal based on a first clock signal; a second modulation circuit configured to generate a feedback signal with a phase negative relative to a phase of the reference signal based on a second clock signal with a phase negative relative to a phase of the first clock signal; a comparator configured to compare the reference signal with the feedback signal to determine duty and generate a comparator signal; and a driver configured to output a drive signal.

According to an embodiment, a semiconductor device includes: a first modulation circuit configured to generate a reference signal based on a first clock signal; a second modulation circuit configured to generate a feedback signal with a phase negative relative to a phase of the reference signal based on a second clock signal with a phase negative relative to a phase of the first clock signal; a comparator configured to compare the reference signal with the feedback signal to determine duty and generate a comparator signal; and a driver configured to output a drive signal.