A triggered sink circuit for a linear voltage regulator, such as low-dropout voltage regulator (LDO), is disclosed. The triggered sink circuit is activated only when needed to sink current from an output in response to a transient load change. The triggered sink circuit includes a large sink transistor that when activated drains current from the output of the LDO to quickly restore an output voltage back towards a regulated value, thereby improving a load transient response to the load change. The improved load transient response prevents the output transistor of the LDO from being completely deactivated to restore regulation. Accordingly, the LDO's response to a subsequent load transient can be improved.

A triggered sink circuit for a linear voltage regulator, such as low-dropout voltage regulator (LDO), is disclosed. The triggered sink circuit is activated only when needed to sink current from an output in response to a transient load change. The triggered sink circuit includes a large sink transistor that when activated drains current from the output of the LDO to quickly restore an output voltage back towards a regulated value, thereby improving a load transient response to the load change. The improved load transient response prevents the output transistor of the LDO from being completely deactivated to restore regulation. Accordingly, the LDO's response to a subsequent load transient can be improved.

A shunt regulator includes: a capacitor, connected between an output terminal and a ground terminal; a voltage divider circuit and an output transistor, connected between the output terminal and the ground terminal; an error amplifier, controlling the output transistor based on a voltage at an output terminal of the voltage divider circuit and a reference voltage; a non-volatile memory; a memory control circuit, outputting a data read signal to the non-volatile memory; and a voltage detection circuit, detecting that a voltage at the output terminal has reached a predetermined voltage which permits a data reading operation of the non-volatile memory, and outputting a detection signal to the memory control circuit. An operating current of the non-volatile memory is supplied from the capacitor.

A shunt regulator includes: a capacitor, connected between an output terminal and a ground terminal; a voltage divider circuit and an output transistor, connected between the output terminal and the ground terminal; an error amplifier, controlling the output transistor based on a voltage at an output terminal of the voltage divider circuit and a reference voltage; a non-volatile memory; a memory control circuit, outputting a data read signal to the non-volatile memory; and a voltage detection circuit, detecting that a voltage at the output terminal has reached a predetermined voltage which permits a data reading operation of the non-volatile memory, and outputting a detection signal to the memory control circuit. An operating current of the non-volatile memory is supplied from the capacitor.

The present disclosure uses a capacitive voltage divider to supply a voltage that can be more readily handled by main-stream semiconductor and magnetic components (generally less than 1000 volts). The divided system voltage, expected to be between 500 and 1000 volts, is then converted to a power supply voltage to be used by the measuring equipment. For safety reasons, this voltage is frequently required to be less than approximately 50 volts if it is delivered via a connectorized cable with exposed contacts.

A multistage amplifier for outputting a first output signal includes: an input stage circuit, a middle stage circuit and an output stage circuit. The input stage circuit includes at least one amplifying circuit, which receives the first output signal and a reference signal, thereby to generate a second output signal at an output terminal of the input stage circuit. The middle stage circuit is used to perform frequency compensation on the multistage amplifier. The output stage circuit is used to generate the first output signal at an output terminal of the output stage circuit according to the second output signal. The output stage circuit includes at least one current limiting circuit, where the current limiting circuit is controlled by the second output signal, thereby to adjusting a voltage level of the first output signal.

A power supply includes a voltage converter to produce an output voltage to power a load. The power supply further includes a reference voltage generator and a controller. The reference voltage generator is operative to generate a floor reference voltage that varies as a function of the output voltage depending on a setting of one or more adjustable (programable) resistor-capacitor paths in the floor reference voltage generator. The controller produces control signals to control the voltage converter as a function of the floor reference voltage and the output voltage.

A power supply includes a voltage converter to produce an output voltage to power a load. The power supply further includes a reference voltage generator and a controller. The reference voltage generator is operative to generate a floor reference voltage that varies as a function of the output voltage depending on a setting of one or more adjustable (programable) resistor-capacitor paths in the floor reference voltage generator. The controller produces control signals to control the voltage converter as a function of the floor reference voltage and the output voltage.

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 triggered sink circuit for a linear voltage regulator, such as low-dropout voltage regulator (LDO), is disclosed. The triggered sink circuit is activated only when needed to sink current from an output in response to a transient load change. The triggered sink circuit includes a large sink transistor that when activated drains current from the output of the LDO to quickly restore an output voltage back towards a regulated value, thereby improving a load transient response to the load change. The improved load transient response prevents the output transistor of the LDO from being completely deactivated to restore regulation. Accordingly, the LDO's response to a subsequent load transient can be improved.