A control circuit for turning on a power semiconductor switch comprises an input which is configured to receive a signal that characterizes the switch-on behavior of the power semiconductor switch, a variable current source which is configured to supply a current with a variable level to a control input of the power semiconductor switch in order to switch on the power semiconductor switch, wherein the control circuit is configured to control the variable current source in a closed control loop in response to the signal that characterizes the switch-on behavior of the power semiconductor switch.

Embodiments of the present invention provide for a core stage in an application-specific integrated circuit core which drives both a clock pulse signal and a clock pulse negative/complement signal concurrently, thereby resulting in perfectly aligned signals. The core stage can include a pulse generator, a clock distribution circuit, and a set of latches.

A driver includes a first level shifting unit generating a second signal swinging in a second threshold range in response to a first signal swinging in a first threshold range, a second level shifting unit generating a third signal swinging in a third threshold range in response to the second signal, a first pull-up driving unit driving an output terminal with a first high-voltage in response to the second signal, a first pull-down driving unit driving the output terminal with a first low voltage in response to the third signal, a second pull-down driving unit driving the output terminal with a second low voltage higher than the first low voltage in response to the fourth signal, and a first path coupling unit coupling the second pull-down driving unit with the output terminal in response to the second signal.

A power supply device is provided. The power supply device includes a power transistor, a detection circuit and a driving circuit. The power transistor is controlled by the driving circuit to generate an output current. A first end of the power transistor is coupled to a power voltage pin through a first bonding wire. A second end of the power transistor is configured to output the output current. The detection circuit is coupled between two ends of the first bonding wire to detect the output current and generate a control signal. The driving circuit generates a driving signal according to the control signal. When the output current value is larger than or equal to an over-current-protection current value, the driving circuit starts to adjust a voltage value of the driving signal, such that the output current value is kept at the over-current-protection current value.

The techniques of this disclosure may digitally generate a driver signal with a period (or frequency) at a finer resolution than can be achieved by simply counting clock cycles of a system clock. The driver signal may be configured to trigger based on single output clock signal that may be phase-shifted relative to the master system clock. A clock phase shift circuit may increment the phase shift of the output clock signal to any fraction relative to the master system clock. A driver signal generated based on the phase-shifted output clock may achieve the high resolution in frequency desirable when controlling some pulse-width modulated circuits, such as an LLC converter.

An electrical resonance network comprising a first capacitor and a first inductor whose resonance frequency can be tuned by means of a second capacitor and/or a second inductor. The resulting effective capacitor- or inductor value of a network period is controlled by a variable coupling respectively decoupling interval by means of at least one coupling switch. The coupling respectively decoupling interval is synchronized by a sign change of a current and/or voltage in the network.

One embodiment of the present application discloses a control circuit comprising a driving circuit which comprises a voltage adjusting circuit, a first transistor and a second transistor. The first transistor comprises: a first terminal; a second terminal; and a control terminal, for receiving a bias voltage generated from at least operating voltage of the control circuit. The second transistor comprises: a first terminal, coupled to a second terminal of the first transistor; a second terminal, for receiving a first predetermined voltage; and a control terminal, for receiving the control voltage. A control system comprising the control circuit is also disclosed.

A clock transmission circuit includes a first buffer, a second buffer, and an inductor unit. The first buffer is configured to receive a first clock which is one of differential clocks, and to buffer and output the first clock to a first clock wiring. The second buffer is configured to receive a second clock which is the other of the differential clocks, and to buffer and output the second clock to a second clock wiring. The inductor unit is connected between a first node of the first clock wiring and a second node of the second clock wiring, and configured to include a center tap to which a common voltage is applied.

A transistor device may include an n-type transistor. The transistor device may further include a first bias voltage unit, which is electrically connected to the n-type transistor and configured to apply a first positive bias voltage to a drain terminal of the n-type transistor when the n-type transistor is in an off state. The transistor device may further include a second bias voltage unit electrically, which is connected to the n-type transistor and configured to apply a second positive bias voltage to a source terminal of the n-type transistor when the n-type transistor is in the off state.

An output circuit has: a first driver circuit configured to receive a voltage of an input terminal and output a first voltage to an output terminal; a first comparison circuit configured to compare a first reference voltage with a voltage of the output terminal; a second driver circuit configured to receive the voltage of the input terminal and output a second voltage to the output terminal and become an off state according to a comparison result of the first comparison circuit; a second comparison circuit configured to compare a second reference voltage different from the first reference voltage with the voltage of the output terminal; and a third driver circuit configured to receive the voltage of the input terminal and output a third voltage to the output terminal and become an off state according to a comparison result of the second comparison circuit.