Chapter 4: Difference between revisions

Bipolar Junction Transistor

Base, Emitter, Collector

• NPN: Not Pointing iN
• PNP: Pointing iN Please
• The arrow is for the emitter current. For an NPN the current flows into the collector. For a PNP the current flows out of the collector.

How a BJT works

Large-Signal DC models

Base-Emitter	Collector-Base	Region	Notes
FB	FB	Saturation	${\displaystyle I_{B}>0}$ and ${\displaystyle \beta I_{B}>I_{C}>0}$
FB	RB	Active	${\displaystyle I_{B}>0}$ and ${\displaystyle V_{CE}>0.2}$
RB	FB	Reverse Active
RB	RB	Cutoff

Region	NPN	PNP
Saturation	${\displaystyle I_{B}>0}$ and ${\displaystyle \beta I_{B}>I_{C}>0}$	${\displaystyle I_{B}>0}$ and ${\displaystyle \beta I_{B}>I_{C}>0}$
Active	${\displaystyle I_{B}>0}$ and ${\displaystyle V_{CE}>0.2}$	${\displaystyle I_{B}>0}$ and ${\displaystyle V_{CE}<-0.2}$
Cutoff	${\displaystyle V_{BE}<0.5}$ and ${\displaystyle V_{BC}<0.5}$	${\displaystyle V_{BE}>-0.5}$ and ${\displaystyle V_{BC}>-0.5}$

• Active: The normal mode of operation. This mode has the largest common-emitter current gain.
• Reverse Active: The collector and emitter roles are reversed. Most BJTs are not symmetrical, thus ${\displaystyle \alpha }$ and ${\displaystyle \beta }$ take on different values.
• Saturation:
• Cutoff:

• What are the Saturation, Reverse Active and Cutoff regions used for?
• Why do we always seem to use a common emitter configuration?
• What does the Reverse Active large-signal model look like? How about graphically?
• What is the Triode region?
• For the Saturation region, why is 0.2V the magic number for V_CE?