The circuit can be explained by viewing the transistor as being under the control of negative feedback. From this viewpoint, a common-collector stage (Fig. 1) is an amplifier with full series negative feedback. In this configuration (Fig. 2 with β = 1), the entire output voltage V_out is placed contrary and in series with the input voltage V_in. Thus the two voltages are subtracted according to Kirchhoff's voltage law (KVL) (the subtractor from the function block diagram is implemented just by the input loop), and their difference V_diff = V_in − V_out is applied to the base–emitter junction. The transistor continuously monitors V_diff and adjusts its emitter voltage to equal V_in minus the mostly constant V_BE by passing the collector current through the emitter resistor R_E. As a result, the output voltage follows the input voltage variations from V_BE up to V₊; hence the name "emitter follower".

Intuitively, this behavior can be also understood by realizing that V_BE is very insensitive to bias changes, so any change in base voltage is transmitted (to good approximation) directly to the emitter. It depends slightly on various disturbances (transistor tolerances, temperature variations, load resistance, a collector resistor if it is added, etc.), since the transistor reacts to these disturbances and restores the equilibrium. It never saturates even if the input voltage reaches the positive rail.

The common-collector circuit can be shown mathematically to have a voltage gain of almost unity:

${\displaystyle A_{v}={\frac {v_{\text{out}}}{v_{\text{in}}}}\approx 1.}$ 

A small voltage change on the input terminal will be replicated at the output (depending slightly on the transistor's gain and the value of the load resistance; see gain formula below). This circuit is useful because it has a large input impedance

${\displaystyle r_{\text{in}}\approx \beta _{0}R_{\text{E}},}$ 

so it will not load down the previous circuit, and a small output impedance

${\displaystyle r_{\text{out}}\approx {\frac {R_{\text{E}}\parallel R_{\text{source}}}{\beta _{0}}},}$ 

so it can drive low-resistance loads.

Typically, the emitter resistor is significantly larger and can be removed from the equation:

${\displaystyle r_{\text{out}}\approx {\frac {R_{\text{source}}}{\beta _{0}}}.}$ 

The common collector amplifier's low output impedance allows a source with a large output impedance to drive a small load impedance without changing its voltage. Thus this circuit finds applications as a voltage buffer. In other words, the circuit has current gain (which depends largely on the h_FE of the transistor) instead of voltage gain. A small change to the input current results in much larger change in the output current supplied to the output load.

One aspect of buffer action is transformation of impedances. For example, the Thévenin resistance of a combination of a voltage follower driven by a voltage source with high Thévenin resistance is reduced to only the output resistance of the voltage follower (a small resistance). That resistance reduction makes the combination a more ideal voltage source. Conversely, a voltage follower inserted between a small load resistance and a driving stage presents a large load to the driving stage—an advantage in coupling a voltage signal to a small load.

This configuration is commonly used in the output stages of class-B and class-AB amplifiers. The base circuit is modified to operate the transistor in class-B or AB mode. In class-A mode, sometimes an active current source is used instead of R_E (Fig. 4) to improve linearity and/or efficiency.^[1]

At low frequencies and using a simplified hybrid-pi model, the following small-signal characteristics can be derived. (Parameter ${\displaystyle \beta =g_{m}r_{\pi }}$  and the parallel lines indicate components in parallel.)

Where ${\displaystyle R_{\text{source}}\ }$  is the Thévenin equivalent source resistance.

Derivations edit

Figure 5 shows a low-frequency hybrid-pi model for the circuit of Figure 3. Using Ohm's law, various currents have been determined, and these results are shown on the diagram. Applying Kirchhoff's current law at the emitter one finds:

${\displaystyle (\beta +1){\frac {v_{\text{in}}-v_{\text{out}}}{R_{\text{S}}+r_{\pi }}}=v_{\text{out}}\left({\frac {1}{R_{\text{L}}}}+{\frac {1}{r_{\text{O}}}}\right).}$ 

Define the following resistance values:

${\displaystyle {\begin{aligned}{\frac {1}{R_{\text{E}}}}&={\frac {1}{R_{\text{L}}}}+{\frac {1}{r_{\text{O}}}},\\[2pt]R&={\frac {R_{\text{S}}+r_{\pi }}{\beta +1}}.\end{aligned}}}$ 

Then collecting terms the voltage gain is found:

${\displaystyle A_{\text{v}}={\frac {v_{\text{out}}}{v_{\text{in}}}}={\frac {1}{1+{\frac {R}{R_{\text{E}}}}}}.}$ 

From this result, the gain approaches unity (as expected for a buffer amplifier) if the resistance ratio in the denominator is small. This ratio decreases with larger values of current gain β and with larger values of ${\displaystyle R_{\text{E}}}$ . The input resistance is found as

${\displaystyle {\begin{aligned}R_{\text{in}}&={\frac {v_{\text{in}}}{i_{\text{b}}}}={\frac {R_{\text{S}}+r_{\pi }}{1-A_{\text{v}}}}\\&=\left(R_{\text{S}}+r_{\pi }\right)\left(1+{\frac {R_{\text{E}}}{R}}\right)\\&=R_{\text{S}}+r_{\pi }+(\beta +1)R_{\text{E}}.\end{aligned}}}$ 

The transistor output resistance ${\displaystyle r_{\text{O}}}$  ordinarily is large compared to the load ${\displaystyle R_{\text{L}}}$ , and therefore ${\displaystyle R_{\text{L}}}$  dominates ${\displaystyle R_{\text{E}}}$ . From this result, the input resistance of the amplifier is much larger than the output load resistance ${\displaystyle R_{\text{L}}}$  for large current gain ${\displaystyle \beta }$ . That is, placing the amplifier between the load and the source presents a larger (high-resistive) load to the source than direct coupling to ${\displaystyle R_{\text{L}}}$ , which results in less signal attenuation in the source impedance ${\displaystyle R_{\text{S}}}$  as a consequence of voltage division.

Figure 6 shows the small-signal circuit of Figure 5 with the input short-circuited and a test current placed at its output. The output resistance is found using this circuit as

${\displaystyle R_{\text{out}}={\frac {v_{\text{x}}}{i_{\text{x}}}}.}$ 

Using Ohm's law, various currents have been found, as indicated on the diagram. Collecting the terms for the base current, the base current is found as

${\displaystyle (\beta +1)i_{\text{b}}=i_{\text{x}}-{\frac {v_{\text{x}}}{R_{\text{E}}}},}$ 

where ${\displaystyle R_{\text{E}}}$  is defined above. Using this value for base current, Ohm's law provides

${\displaystyle v_{\text{x}}=i_{\text{b}}\left(R_{\text{S}}+r_{\pi }\right).}$ 

Substituting for the base current, and collecting terms,

${\displaystyle R_{\text{out}}={\frac {v_{\text{x}}}{i_{\text{x}}}}=R\parallel R_{\text{E}},}$ 

where || denotes a parallel connection, and ${\displaystyle R}$  is defined above. Because ${\displaystyle R}$  generally is a small resistance when the current gain ${\displaystyle \beta }$  is large, ${\displaystyle R}$  dominates the output impedance, which therefore also is small. A small output impedance means that the series combination of the original voltage source and the voltage follower presents a Thévenin voltage source with a lower Thévenin resistance at its output node; that is, the combination of voltage source with voltage follower makes a more ideal voltage source than the original one.

• Common base
• Common emitter
• Common gate
• Common drain
• Common source
• IC power-supply pin
• Open collector
• Two-port network

• NPN Common Collector Amplifier — HyperPhysics
• Theodore Pavlic: ECE 327: Transistor Basics; part 6: npn Emitter Follower