A semiconductor switch drive device (3) includes a drive unit (10), a power supply unit (20), a switch (39), and a control unit (50). The drive unit (10) supplies a control signal to a semiconductor switch (Q) of a main circuit (2) and drives the semiconductor switch (Q). The power supply unit (20) supplies electric power to the drive unit (10). The switch (39) cuts off supply of electric power to the power supply unit (20) by detecting or controlling an overvoltage state on a primary side of the power supply unit (20). The control unit (50) switches a conductive state of the switch (39) on the basis of a voltage of a control terminal of the semiconductor switch (Q).

An) electric machine with variable torque generation having a tunable Halbach array configuration. The electric machine includes a magnet assembly for generating a magnetic field. The magnet assembly includes a plurality of fixed magnets disposed in a ring arrangement so that fixed magnets having a north pole faced toward the rotor or stator are alternated with fixed magnets having a south pole faced toward the rotor or stator, a plurality of rotatable magnets disposed within a respective slot formed between two adjacent fixed magnets, a drive assembly for turning the rotatable magnets within the slots to vary the magnetic field generated by the magnet assembly in the rotor or stator, the drive assembly configured to turn the rotatable magnets between a first position wherein the magnetic field in the rotor or stator is augmented and a second position wherein the magnetic field in the rotor or stator is cancelled.

The disclosure provides a power switch that can be switched by a logic source in an ON or an OFF state. The switch comprises a component to output an optical signal responsive to the control signal and an optical sensitive device to react to the optical signal and self-conducting JFET in cascode configuration with the optical sensitive device.

The disclosure provides a power switch that can be switched by a logic source in an ON or an OFF state. The switch comprises a component to output an optical signal responsive to the control signal and an optical sensitive device to react to the optical signal and self-conducting JFET in cascode configuration with the optical sensitive device.

A system and method for high speed switching comprises receiving voltage inputs at a bridge rectifier, generating a control signal from a transistor, and driving a gate of a field effect transistor (FET) via the control signal of the transistor, wherein a source of the FET is connected to a negative output of the bridge rectifier and a drain of the FET is connected to a positive output of the bridge rectifier through a load. The system and method further comprises limiting current flowing to the gate of the FET through first and second resistors and first and second diodes connecting the voltage inputs to the gate of the FET and limiting voltage to the gate of the FET below a maximum voltage rating of the FET by a Zener diode connected to the gate of the FET.

A system and method for high speed switching comprises receiving voltage inputs at a bridge rectifier, generating a control signal from a transistor, and driving a gate of a field effect transistor (FET) via the control signal of the transistor, wherein a source of the FET is connected to a negative output of the bridge rectifier and a drain of the FET is connected to a positive output of the bridge rectifier through a load. The system and method further comprises limiting current flowing to the gate of the FET through first and second resistors and first and second diodes connecting the voltage inputs to the gate of the FET and limiting voltage to the gate of the FET below a maximum voltage rating of the FET by a Zener diode connected to the gate of the FET.

A power supply circuit includes an inductor, a power transistor configured to control an inductor current flowing through the inductor, and an integrated circuit driving the power transistor. The integrated circuit includes a first terminal that receives a power supply voltage for operating the integrated circuit, generated according to a variation in the inductor current, a second terminal to which a control electrode of the power transistor is coupled, a first drive circuit configured to drive the power transistor via the second terminal during a first time period to turn on the power transistor, and a second drive circuit configured to drive the power transistor via the second terminal during a second time period to turn on the power transistor, the second time period including at least a part of the first time period, driving capability of the second drive circuit being lower than that of the first drive circuit.

The present invention relates to a driver system that can include an optical power based isolated power supply. The driver system can include an optical receiver that can be in communication with an optical transmitter to receive an optical signal. The optical receiver can be configured to convert the optical signal to a drive signal having a determined drive strength. The driver system can further include a driving circuit that can be configured to drive an input of the transistor device based on the drive signal according to a control signal defining an on-time and off-time for the driving circuit over a time interval. In some examples, the driver system can be integrated with a protection system.

A drive circuit for a power semiconductor circuit may include input contact means for inputting a control signal, the control signal representing a switching command for the power semiconductor circuit, and also at least one output contact means, to which the power semiconductor circuit is connectable and which serves for outputting a switching signal to the power semiconductor circuit. Furthermore, the drive circuit comprises current path connection means for connecting the drive circuit to a current path to be switched by the power semiconductor circuit, and means for galvanically isolating the input contact means from the output contact means and the current path connection means. Circuit means which output a switching signal that switches on the power semiconductor circuit if a control signal representing the switch-on command for the power semiconductor circuit is input at the input contact means and also voltage is present at the current path connection means.

A drive circuit for a power semiconductor circuit may include input contact means for inputting a control signal, the control signal representing a switching command for the power semiconductor circuit, and also at least one output contact means, to which the power semiconductor circuit is connectable and which serves for outputting a switching signal to the power semiconductor circuit. Furthermore, the drive circuit comprises current path connection means for connecting the drive circuit to a current path to be switched by the power semiconductor circuit, and means for galvanically isolating the input contact means from the output contact means and the current path connection means. Circuit means which output a switching signal that switches on the power semiconductor circuit if a control signal representing the switch-on command for the power semiconductor circuit is input at the input contact means and also voltage is present at the current path connection means.