The present disclosure relates to a constant current source calibration circuit, a constant current source drive circuit, a drive chip, and an electronic device. The current calibration circuit includes a resistor and a calibration circuit connected to the resistor for adjusting a voltage drop across two ends of the resistor; and a selector or a switch connected to the two ends of the resistor, and configured to select one end of the resistor to be connected to a constant current source output channel and the corresponding other end to be supplied with a first bias voltage VD. Since the first bias voltage VD is a fixed constant, the voltage drop across the two ends of the resistor is adjusted.

The present disclosure relates to a constant current source calibration circuit, a constant current source drive circuit, a drive chip, and an electronic device. The current calibration circuit includes a resistor and a calibration circuit connected to the resistor for adjusting a voltage drop across two ends of the resistor; and a selector or a switch connected to the two ends of the resistor, and configured to select one end of the resistor to be connected to a constant current source output channel and the corresponding other end to be supplied with a first bias voltage VD. Since the first bias voltage VD is a fixed constant, the voltage drop across the two ends of the resistor is adjusted.

A low-dropout regulator system includes a low-dropout regulator. A comparator circuit generates a comparison voltage according to a reference voltage and a feedback voltage. An amplifier circuit generates an amplifying voltage according to the comparison voltage. A transistor receives an input voltage and is controlled by the amplifying voltage to generate an output voltage at an output terminal. A first resistor circuit is coupled between a first node and a ground terminal. A second resistor circuit is coupled between the output terminal and the first node. At a start-up timing point of the low-dropout regulator, a resistance value of the second resistor circuit is a first resistance value. After the input voltage reaches a maximum voltage, the resistance value of the second resistor circuit is a second resistance value. The second resistance value is larger than the first resistance value.

A low-dropout regulator system includes a low-dropout regulator. A comparator circuit generates a comparison voltage according to a reference voltage and a feedback voltage. An amplifier circuit generates an amplifying voltage according to the comparison voltage. A transistor receives an input voltage and is controlled by the amplifying voltage to generate an output voltage at an output terminal. A first resistor circuit is coupled between a first node and a ground terminal. A second resistor circuit is coupled between the output terminal and the first node. At a start-up timing point of the low-dropout regulator, a resistance value of the second resistor circuit is a first resistance value. After the input voltage reaches a maximum voltage, the resistance value of the second resistor circuit is a second resistance value. The second resistance value is larger than the first resistance value.

A method for regulating a voltage reference signal includes providing a first output current during a first interval and a boosted output current during a second interval to generate a low-dropout voltage reference signal based on a first power supply voltage, a second power supply voltage, and a reference voltage level. The method includes, during the second interval, compensating for a voltage drop caused by providing the boosted output current. The first output current may be provided in a first mode of operation. The boosted output current and voltage drop compensation may be provided in a boosted mode of operation.

A method for regulating a voltage reference signal includes providing a first output current during a first interval and a boosted output current during a second interval to generate a low-dropout voltage reference signal based on a first power supply voltage, a second power supply voltage, and a reference voltage level. The method includes, during the second interval, compensating for a voltage drop caused by providing the boosted output current. The first output current may be provided in a first mode of operation. The boosted output current and voltage drop compensation may be provided in a boosted mode of operation.

A linear regulator includes a pass transistor, a buffer transistor, and a low-pass filter circuit. The pass transistor is configured to pass a current from an input terminal to an output terminal. The buffer transistor is coupled to the input terminal and the pass transistor, and is configured to control the pass transistor. The low-pass filter circuit is coupled to the input terminal and the buffer transistor, and is configured to modulate a threshold voltage of the buffer transistor responsive to a transient at the input terminal.

A linear regulator includes a pass transistor, a buffer transistor, and a low-pass filter circuit. The pass transistor is configured to pass a current from an input terminal to an output terminal. The buffer transistor is coupled to the input terminal and the pass transistor, and is configured to control the pass transistor. The low-pass filter circuit is coupled to the input terminal and the buffer transistor, and is configured to modulate a threshold voltage of the buffer transistor responsive to a transient at the input terminal.

A voltage regulation circuit, device, and method are disclosed, which relate to the field of electronic technologies, to reduce a voltage regulation time, and improve a system response and user experience. The voltage regulation circuit (1) includes: a first power supply circuit (11), configured to receive a voltage setting signal (S.sub.SET), and output a first supply voltage (V1) and a second reference voltage (V.sub.REF2) according to the voltage setting signal (S.sub.SET) and a difference between a first feedback voltage (V.sub.F1) and a second feedback voltage (V.sub.F2), where the first feedback voltage (V.sub.F1) is used to indicate the first supply voltage (V1), and the second feedback voltage (V.sub.F2) is used to indicate a second supply voltage (V2); and a second power supply circuit (12), configured to output the second supply voltage (V2) based on the second reference voltage (V.sub.REF2).

A voltage regulation circuit, device, and method are disclosed, which relate to the field of electronic technologies, to reduce a voltage regulation time, and improve a system response and user experience. The voltage regulation circuit (1) includes: a first power supply circuit (11), configured to receive a voltage setting signal (S.sub.SET), and output a first supply voltage (V1) and a second reference voltage (V.sub.REF2) according to the voltage setting signal (S.sub.SET) and a difference between a first feedback voltage (V.sub.F1) and a second feedback voltage (V.sub.F2), where the first feedback voltage (V.sub.F1) is used to indicate the first supply voltage (V1), and the second feedback voltage (V.sub.F2) is used to indicate a second supply voltage (V2); and a second power supply circuit (12), configured to output the second supply voltage (V2) based on the second reference voltage (V.sub.REF2).