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.

Electronic circuits are disclosed. One electronic circuit includes: a transistor device having a load path and a drive input; a first drive circuit configured to receive a supply voltage and generate a drive signal for the transistor device based on the supply voltage; and a biasing circuit connected in parallel with the load path of the transistor device. The biasing circuit includes a bias voltage circuit configured to receive the supply voltage and generate a bias voltage higher than the supply voltage based on the supply voltage.

In an embodiment, a digital output driver circuit comprises an output stage having first and second transistors. A drive stage is configured to drive control terminals of the first and second transistors and comprising switching circuitry and current generator circuitry. In a first configuration, the driver circuit is configured to connect a control terminal of the second transistor to the reference node to turn off the second transistor; and connect a first capacitance to the current generator circuitry and to a control terminal of the first transistor to turn on the first transistor. In a second configuration, the driver circuit is configured to turn off the first transistor and connect the control terminal of the second transistor to the current generator circuitry and to the second capacitance to turn on the second transistor.

A driving apparatus includes a current output unit, a reference voltage output unit, a comparator, and a drive control unit. The current output unit is switchable to either a first ON resistance or a second ON resistance that is N times (N>1) the first ON resistance. The reference voltage output unit outputs a fist reference voltage during a large current time period, and outputs a second reference voltage that is M times (M>1) the first reference voltage during a small current time period. The drive control unit performs control to perform switching to the first ON resistance during the large current time period, and to perform switching to the second ON resistance during the small current time period.

A circuit includes a first power node configured to carry a first voltage having a first voltage level, a second power node configured to carry a second voltage having a second voltage level, an output node, and first and second cascode transistors coupled between the first power node and the output node and to each other at a node. A bias circuit uses the first and second cascode transistors to generate an output signal at the output node that transitions between the first voltage level and a third voltage level, and a delay circuit generates a transition in a first signal from one of the first or second voltage levels to the other of the first or second voltage levels, the transition having a time delay based on the output signal. A contending transistor couples the node to the second power node responsive to the first signal.

In an embodiment, a digital output driver circuit comprises an output stage having first and second transistors. A drive stage is configured to drive control terminals of the first and second transistors and comprising switching circuitry and current generator circuitry. In a first configuration, the driver circuit is configured to connect a control terminal of the second transistor to the reference node to turn off the second transistor; and connect a first capacitance to the current generator circuitry and to a control terminal of the first transistor to turn on the first transistor. In a second configuration, the driver circuit is configured to turn off the first transistor and connect the control terminal of the second transistor to the current generator circuitry and to the second capacitance to turn on the second transistor.

An adjuster includes a power transfer circuit, a negative feedback circuit, a constant current source circuit and a control circuit. Two inputs of an error amplifier in the negative feedback circuit receive a reference voltage and a feedback voltage corresponding to an output signal of the adjuster respectively, and the error amplifier is configured to output a first voltage signal when the feedback voltage is less than the reference voltage, and output a second voltage signal when the feedback voltage is greater than the reference voltage, during the starting process of the adjuster. The control circuit is configured to control the negative feedback circuit to be turned off and the constant current source circuit to be turned on, and control the constant current source circuit to be turned off and the negative circuit to be turned on according to the second voltage signal.

In a gate driver, a comparator input is adapted to be coupled through a resistor and a diode to a first transistor. A latch input is coupled to a comparator output. A second transistor has a first control terminal and a first output terminal. The first output terminal is adapted to be coupled to a control terminal of the first transistor. A third transistor is smaller than the second transistor. The third transistor has a second control terminal and a second output terminal. The second output terminal is adapted to be coupled to the control terminal of the first transistor. Control logic has a logic input and first and second logic outputs. The logic input is coupled to a latch output. The first logic output is coupled to the first control terminal. The second logic output is coupled to the second control terminal.

In an embodiment, a digital output driver circuit comprises an output stage having first and second transistors. A drive stage is configured to drive control terminals of the first and second transistors and comprising switching circuitry and current generator circuitry. In a first configuration, the driver circuit is configured to connect a control terminal of the second transistor to the reference node to turn off the second transistor; and connect a first capacitance to the current generator circuitry and to a control terminal of the first transistor to turn on the first transistor. In a second configuration, the driver circuit is configured to turn off the first transistor and connect the control terminal of the second transistor to the current generator circuitry and to the second capacitance to turn on the second transistor.

A power-switch-system (PSS) having a low-side transistor (LSS) and a high-side transistor (HSS), which are switchable to be conductive or switched to be blocking in respectively alternating time-segments of a switching-period of the PSS. A source-terminal of the LSS is connected to a load-terminal, and a drain-terminal of the LSS is connected to a supply-voltage via a storage-inductor. A drain-terminal of the HSS is connected to the load-terminal, and a source-terminal of the HSS is connected to the supply-voltage via the storage-inductor. Provided is a PSS of this kind, the LSS having at least two transistor-segments. At least two of the transistor-segments have a different electrical resistance in the connection to the storage-inductor. The PSS provides that at least two of the transistor-segments are switched at a different point in time during a switching operation of the PSS to reduce unwanted voltage fluctuations, without markedly increasing switching losses.