Process of applying the correct voltage and current to the source of the IGBT

Process of applying the correct voltage and current to the gate of the IGBT

Process of applying the correct voltage and current to the collector of the IGBT

Process of applying the correct voltage and current to the drain of the IGBT

To decrease its performance and efficiency

To make it more difficult to turn on and off

To make it less reliable

To ensure proper turn-on and turn-off characteristics, as well as to optimize its performance and efficiency.

Base drive circuit and gate drive circuit

Gate bias circuit and collector bias circuit

Base voltage circuit and gate voltage circuit

Emitter drive circuit and collector drive circuit

Voltage biasing applies a fixed voltage to the base of the transistor, while current biasing applies a fixed current to the base of the transistor.

Voltage biasing applies a fixed voltage to the collector of the transistor, while current biasing applies a fixed current to the base of the transistor.

Voltage biasing applies a fixed current to the base of the transistor, while current biasing applies a fixed voltage to the base of the transistor.

Voltage biasing and current biasing are the same thing.

No impact on efficiency, increased power loss, and worse thermal performance

Improved efficiency, reduced power loss, and better thermal performance

Increased power loss, reduced efficiency, and poor thermal performance

Decreased efficiency, increased power loss, and no impact on thermal performance

Reduces switching losses and improves efficiency

Causes overheating and decreases the lifespan of the device

Has no effect on the performance of the device

Increases switching losses and reduces efficiency

Improved power loss and increased efficiency

Decreased power loss and improved efficiency

No impact on power loss or efficiency

Increased power loss and reduced efficiency

Increasing the collector current

Using a gate resistor

Using a base resistor

Decreasing the gate voltage