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).

Disclosed is a semiconductor integrated circuit for a regulator for forming a low current consumption type DC power supply device. The semiconductor integrated circuit includes an output transistor, a control circuit, an operation control transistor and a soft start circuit. The output transistor is connected between an output terminal and a voltage input terminal to which a DC voltage is input. The control circuit controls the output transistor according to a feedback voltage of an output. The operation control transistor controls an operation state of the control circuit. The soft start circuit gradually changes a voltage applied to a control terminal of the operation control transistor and delays activation of the control circuit at a time of applying a power supply voltage to the voltage input terminal.

A voltage regulator is provided. The voltage regulator includes a main error amplifier, a first buffer, a second buffer, and multiple main zero compensation loops. The main error amplifier generates a first voltage signal according to a reference voltage signal and a feedback voltage signal. The first buffer provides a second voltage signal according to the first voltage signal. The second buffer provides an output voltage signal according to the second voltage signal. The main zero compensation loops are respectively coupled between an output terminal of the main error amplifier and an output terminal of the first buffer. The main zero compensation loops provide different zero compensations.

An auxiliary power supply circuit operating within a wide input voltage range has a voltage follower unit and a voltage comparison unit. The voltage follower unit has an electronic switch, a resistor, and a Zener diode. The electronic switch has a first terminal electrically connected to a voltage input terminal of the working voltage conversion circuit, a second terminal electrically connected to a voltage output terminal of the working voltage conversion circuit, and a control terminal. The resistor is electrically connected between the first terminal and the control terminal of the electronic switch. The Zener diode has a cathode electrically connected to the control terminal of the electronic switch. The voltage comparison unit has a detecting terminal electrically connected to the voltage input terminal of the working voltage conversion circuit, and an output terminal electrically connected to the control terminal of the electronic switch.

A power manager circuit is provided. The power manager circuit includes a bandgap reference circuit, first and second monitoring circuits, and a reference buffer. The bandgap reference circuit generates a first voltage, based on an external voltage that is external to the power manager circuit. The first monitoring circuit determines a logical value of a first alarm signal, based on whether a first voltage level of the first voltage is within a first range. The reference buffer generates a second voltage, based on the first voltage. The second monitoring circuit determines a logical value of a second alarm signal, based on whether a second voltage level of the second voltage is within a second range.

A reference voltage generation circuit includes a band gap reference circuit configured to generate a first reference voltage that depends on a band gap reference voltage and a supply voltage, and a conversion circuit configured to convert the first reference voltage into a second reference voltage. The second reference voltage depends on the band gap reference voltage and a ground voltage. The ground voltage is lower than the supply voltage.

Voltage regulation schemes for powering multiple circuit blocks are disclosed. In certain embodiments, a front end system includes a reference voltage circuit that receives power from a power supply voltage and generates a reference voltage, a group of circuit blocks each selectively enabled by a corresponding one of a group of enable signals, and a programmable voltage regulator that generates a programmable regulated voltage based on the reference voltage and provides the programmable regulated voltage to the circuit blocks. The programmable regulated voltage has a voltage level that changes based on a selection of the circuit blocks that are enabled by the enable signals.

In described examples, a circuit includes a first current mirror circuit. The first current mirror circuit is coupled to a power input terminal. A first stage is coupled to the first current mirror circuit, and a second stage is coupled to the first stage and to the first current mirror circuit. An amplifier is coupled to the first and second stages. The amplifier has first and second input terminals. The first input terminal is coupled to the first stage, and the second input terminal is coupled to the second stage. A second current mirror circuit is coupled to the first stage, the second stage and the amplifier.

An on-chip resistor correction circuit includes a first MOS transistor connected between VDD and a reference resistor, the other end of the reference resistor being grounded; an operational amplifier for outputting a first control signal based on a reference voltage and a voltage of the reference resistor; a second MOS transistor connected between VDD and a reference node; a branch where each of the on-chip resistors is located is controllably connected between the reference node and ground; a comparator for generating a comparison signal based on the voltage of the reference node and the reference voltage; and a controller for generating a control signal under the action of the comparison signal to control the branch where each of the on-chip resistors is located to turn on or off.

A voltage regulator coupled between a first node and second node includes a first (full-power) regulator circuit and a second (low-power) regulator circuit. In a first mode: the first regulator circuit is activated (with the second regulator circuit inactive) when the voltage at the first node is a battery voltage, and the voltage regulator is kept de-activated when the voltage at the first node is a ground voltage. In a second mode: the first regulator circuitry in is active (with the second regulator circuitry inactive) when the voltage at the first node is a battery voltage, and the voltage regulator is inactive when the voltage at the first node is a ground voltage. In a third mode: the second regulator circuitry is active (with the first regulator circuitry inactive) irrespective of the voltage at the first node being at the battery voltage or the ground voltage.