A linear voltage regulator includes a voltage input and a voltage output. The linear voltage regulator includes a buffer having a voltage node, an input node, an output node and a control node and a power transistor having a control node coupled to the output node of the buffer, an input node coupled to the voltage input and an output node coupled to the voltage output. The linear voltage regulator includes a dropout detection module having a control node coupled to the control node of the power transistor, a voltage input node coupled to the voltage input, a voltage output node coupled to the voltage output and an output node. The linear voltage regulator includes a feedforward module having an input node coupled to the output node of the dropout detection module and an output node coupled to the control node of the buffer.

A voltage regulator and a corresponding method of regulating a voltage are presented. The voltage regulator includes an N-type power switch, an error amplifier, and a switch capacitor circuit. The switch capacitor circuit includes a first capacitor coupled to a network of switches, the switch capacitor circuit has a first port coupled to an output the error amplifier, a second port coupled to an output terminal of the power switch, and a third port coupled to a control terminal of the power switch. The switch capacitor circuit is iteratively operable between a first phase and a second phase. In the first phase the first port is coupled to ground via a path comprising the first capacitor, and in the second phase the second port is coupled to the third port via a path comprising the first capacitor. The voltage regulator may be implemented as a low dropout regulator.

A voltage regulator and a corresponding method of regulating a voltage are presented. The voltage regulator includes an N-type power switch, an error amplifier, and a switch capacitor circuit. The switch capacitor circuit includes a first capacitor coupled to a network of switches, the switch capacitor circuit has a first port coupled to an output the error amplifier, a second port coupled to an output terminal of the power switch, and a third port coupled to a control terminal of the power switch. The switch capacitor circuit is iteratively operable between a first phase and a second phase. In the first phase the first port is coupled to ground via a path comprising the first capacitor, and in the second phase the second port is coupled to the third port via a path comprising the first capacitor. The voltage regulator may be implemented as a low dropout regulator.

A low dropout amplifier may include an error amplifier having first and second inputs coupled to a reference signal and a feedback signal, respectively. The error amplifier may be configured to generate first and second error signals at first and second outputs, respectively, with the first and second error signals based upon a difference between the reference signal and the feedback signal. A sink stage may be coupled to the first output and configured to generate a sink current based upon the first error signal. A source stage may be coupled to the second output and configured to generate a source current based upon the second error signal. An output node may be coupled to receive the sink and source currents.

A low dropout amplifier may include an error amplifier having first and second inputs coupled to a reference signal and a feedback signal, respectively. The error amplifier may be configured to generate first and second error signals at first and second outputs, respectively, with the first and second error signals based upon a difference between the reference signal and the feedback signal. A sink stage may be coupled to the first output and configured to generate a sink current based upon the first error signal. A source stage may be coupled to the second output and configured to generate a source current based upon the second error signal. An output node may be coupled to receive the sink and source currents.

A low-dropout regulator includes a voltage divider circuit, an operation amplifier, a regulator circuit and an output circuit. The voltage divider circuit divides a power supply voltage to generate a predetermined voltage. The operational amplifier generates a bias voltage according to the predetermined voltage and an output voltage of an output terminal. The regulator circuit generates a first regulated voltage and a second regulated voltage according to the bias voltage. The output circuit adjusts a difference between a first current and a second current according to the first regulated voltage and the second regulated voltage to regulate the output voltage.

A low-dropout regulator includes a voltage divider circuit, an operation amplifier, a regulator circuit and an output circuit. The voltage divider circuit divides a power supply voltage to generate a predetermined voltage. The operational amplifier generates a bias voltage according to the predetermined voltage and an output voltage of an output terminal. The regulator circuit generates a first regulated voltage and a second regulated voltage according to the bias voltage. The output circuit adjusts a difference between a first current and a second current according to the first regulated voltage and the second regulated voltage to regulate the output voltage.

A voltage regulator receives a reference voltage and generates a regulated voltage using a MOSFET having a gate terminal configured to receive a control voltage. A charge pump receives the regulated voltage and generates a charge pump voltage in response to an enable signal and a clock signal generated in response to the enable signal. The voltage regulator further includes a first switched capacitor circuit coupled to the gate terminal and configured to selectively charge a first capacitor with a first current and impose a first voltage drop on the control voltage in response to assertion of the enable signal. The voltage regulator also includes a second switched capacitor circuit coupled to the gate terminal and configured to selectively charge a second capacitor with a second current and impose a second voltage drop on the control voltage in response to one logic state of the clock signal.

A level conversion circuit includes a first pin, a second pin, a target pin, a core module and a switch. A first terminal of the switch is connected to the first pin, a second terminal of the switch is connected to the second pin, and the core module is connected to the target pin, the second pin and a control terminal of the switch respectively. The core module is configured to: when a voltage connected to the target pin is at a first reference high level, control the switch to turn on to transmit a signal with a specified voltage amplitude, and pull the first pin to the first reference high level and the second pin to a second reference high level based on the first reference high level; where the first reference high level is higher than the second reference high level.

A level conversion circuit includes a first pin, a second pin, a target pin, a core module and a switch. A first terminal of the switch is connected to the first pin, a second terminal of the switch is connected to the second pin, and the core module is connected to the target pin, the second pin and a control terminal of the switch respectively. The core module is configured to: when a voltage connected to the target pin is at a first reference high level, control the switch to turn on to transmit a signal with a specified voltage amplitude, and pull the first pin to the first reference high level and the second pin to a second reference high level based on the first reference high level; where the first reference high level is higher than the second reference high level.