A circuit includes a first bipolar junction transistor (BJT) including a first base, a first collector, and a first emitter, the first collector connected to a first supply voltage node and a second BJT including a second base, a second collector, and a second emitter, the second collector connected to the first emitter at an output node. The circuit also includes a capacitor including a first capacitor terminal and a second capacitor terminal, the first capacitor terminal connected to the second emitter of the second BJT and the second capacitor terminal connected to a second supply voltage node. A current source device is also included that is connected in parallel with the capacitor.

An operational amplifier, a driving interface, a measurement and control device, a driving circuit and a driver are provided. The operational amplifier is used as at least one of an input interface and output interface, and when the operational amplifier corresponds to one transistor (Q), an external circuit of the transistor further includes: a first port (Vdj), connected with a base (B) of the transistor (Q) through a first resistor (Rb); a second port (I/Oe), connected with an emitter E of the transistor (Q); a third port (I/Oc), connected with a collector (C) of the transistor (Q); and a fourth port (GND), connected with the emitter (E) of the transistor (Q) through a second resistor and used as a public port for signal input and signal output.

A power supply device includes an output circuit configured to be supplied with electric power from a power supply, and to output a current, a driving circuit configured to control an output operation of the output circuit to output a current, an overcurrent detection circuit configured to output a detection signal to a first node when detecting an overcurrent in the output circuit, an off-state fixing circuit configured to output an off-state fixing signal to the driving circuit for performing a forcible suspension of the output operation of the output circuit based on a detection signal inputted to the first node, regardless of whether a control signal is outputted, and a control unit configured to receive the detection signal and to output the control signal for controlling the output operation to the driving circuit in order to cause the driving circuit to control the output operation.

The integrated circuit connection device (1) enables an external component to be connected. The integrated circuit is powered by a supply voltage (V.sub.DD) and part of the circuit operates using at least one internal regulated voltage (V.sub.REG). The connection device includes two active transistors (N1, P1) of different conductivity connected in series between the supply voltage (V.sub.DD) and earth (V.sub.SS). The drains of these two active transistors (N1, P1) are connected to each other so as to form an external contact pad (2). The gates of these active transistors are controlled by voltage signals that have the same amplitude (V.sub.esd). The connection device further includes switching means (3) for modifying the control signals (V.sub.esd) applied across the active transistor gates, without exceeding the highest voltage between the supply voltage (V.sub.DD) and the internal regulated voltage (V.sub.REG). This allows the voltage range of said integrated circuit to be adapted to an external component connected to the external contact pad (2).

The present disclosure provides a level shifter including: a level shifter section that is driven by a first power source voltage, and that, in accordance with switching of an input signal of a voltage lower than the first power source voltage, switches an output signal that has been level-shifted, from the first power source voltage to a voltage lower than the first power source voltage; and a threshold voltage changing circuit that, in accordance with a switching direction of the input signal, changes a threshold voltage of the input signal for switching the output signal.

A receiver includes the following: a signal receiving circuit, including a first MOS transistor and a second MOS transistor, where a gate of the first MOS transistor is configured to receive a reference signal and a gate of the second MOS transistor is configured to receive a data signal, and the signal receiving circuit is configured to output a comparison signal, the comparison signal being configured to represent a magnitude relationship between a voltage value of the reference signal and a voltage value of the data signal; and an adjusting circuit, including a third MOS transistor, where a source of the third MOS transistor is connected to a source of the first MOS transistor, a drain of the third MOS transistor is connected to a drain of the first MOS transistor, and a gate of the third MOS transistor is configured to receive an adjusting signal.

A voltage level shifter including a voltage level shifting circuit and a boost circuit is provided. The voltage level shifting circuit includes a first reference input end, a second reference input end, a first boosted input end, and a second boosted input end. The voltage level shifting circuit operates between a first voltage and a second voltage. The boost circuit is coupled to the voltage level shifting circuit. The boost circuit boosts the first boosted input end and the second boosted input end according to voltage values of the first reference input end and the second reference input end to reduce a transient current that flows from the first voltage to the second voltage.

A power supply device includes an output circuit configured to be supplied with electric power from a power supply, and to output a current, a driving circuit configured to control an output operation of the output circuit to output a current, an overcurrent detection circuit configured to output a detection signal to a first node when detecting an overcurrent in the output circuit, an off-state fixing circuit configured to output an off-state fixing signal to the driving circuit for performing a forcible suspension of the output operation of the output circuit based on a detection signal inputted to the first node, regardless of whether a control signal is outputted, and a control unit configured to receive the detection signal and to output the control signal for controlling the output operation to the driving circuit in order to cause the driving circuit to control the output operation.

The invention relates to a level converter for adjusting a first reference potential and/or a first communication voltage of a first component to a second reference potential and/or a second communication voltage of a second component, wherein the level converter is arranged between the first component and the second component, wherein the level converter has a first transistor with a downstream first resistor, wherein the level converter is configured in such a way that the second reference potential drops at the first resistor in a blocked state of the first transistor and that the second communication voltage drops at the first resistor in an open state of the first transistor.

A low-voltage-drop rectifier circuit includes a first MOSFET (Metal Oxide Semiconductor Field Effect Transistor), a second MOSFET, a comparator, and a level adjustment circuit. The first MOSFET has a gate terminal for receiving a control voltage, a source terminal connected to a connection node, a drain terminal connected to an input node, and a body terminal connected to the connection node. The second MOSFET has a gate terminal for receiving the control voltage, a source terminal connected to an output node, a drain terminal connected to the connection node, and a body terminal connected to the output node. The comparator generates a first comparison voltage and a second comparison voltage according to an input voltage at the input node and an output voltage at the output node. The level adjustment circuit generates and fine-tunes the control voltage according to the first comparison voltage and the second comparison voltage.