Common gate

From Wikipedia, the free encyclopedia

Figure 1: Basic N-channel common gate circuit (neglecting biasing details); current source I_D represents an active load; signal is applied at node V_in and output is taken from node V_out; output can be current or voltage

In electronics, a common gate amplifier is one of three basic single-stage field effect transistor (FET) amplifier topologies, typically used as a current buffer or voltage amplifier. In this circuit the source terminal of the transistor serves as the input, the drain is the output and the gate is common to both, hence its name. An analogous circuit called the common base is constructed using bipolar junction transistors.

1 Applications
2 Low-frequency characteristics
- 2.1 Closed circuit voltage gain
3 References
4 See also
5 External Links

[edit] Applications

This configuration is used less often than the common source or source follower, but is useful in CMOS RF receivers, especially when pushing the frequency limitations of the FETs, because of the ease of impedance matching and potentially lower noise. As a general reference for this circuit, see Gray and Meyer.^[1]

[edit] Low-frequency characteristics

Figure 2: Small-signal low-frequency hybrid-pi model for amplifier driven by a Norton signal source

At low-frequencies and under small-signal conditions, the circuit in Figure 1 can be represented by that in Figure 2, where the hybrid-pi model for the MOSFET has been employed.

Figure 3: Hybrid pi model with test source i_x at output to find output resistance

The amplifier characteristics are summarized below in Table 1. The approximate expressions use the assumptions (usually accurate) r_O >> R_L and g_mr_O >> 1.

Table 1	Definition	Expression	Approximate expression
Short circuit current gain	${A_{i}} = {i_\mathrm{out} \over i_\mathrm{S}} \Big\|_{R_{L}=0}$	$\ 1$
Open circuit voltage gain	${A_{v}} = {v_\mathrm{out} \over v_\mathrm{S}} \Big\|_{R_{L}=\infty}$	$\begin{matrix} (g_m r_\mathrm{O}+1) \frac {R_L} {r_O + R_L} \end{matrix}$	$\ g_m R_L$
Input resistance	$R_\mathrm{in} = \frac{v_{S}}{i_{S}}$	${{R_L+r_O} \over {g_m r_O +1}}$	$\begin{matrix} \frac {1} {g_m} \end{matrix}$
Output resistance	$R_\mathrm{out} =\frac{v_{x}}{i_{x}}$	$\ (1+g_m r_O)R_S + r_O$

Note: Parallel lines (||) indicate components in parallel.

In general the overall voltage/current gain may be substantially less than the open/short circuit gains listed above (depending on the source and load resistances) due to the loading effect.

[edit] Closed circuit voltage gain

Taking input and output loading into consideration, the closed circuit voltage gain (that is, the gain with load R_L and source with resistance R_S both attached) of the common gate can be written as:

${A_\mathrm{v}} \approx \begin{matrix} \frac {g_m R_\mathrm{L}} {1+g_mR_S} \end{matrix}$ ,

which has the simple limiting forms

$A_\mathrm{v} = \begin{matrix} \frac {R_L}{R_S}\end{matrix} \ \ \mathrm{ or } \ \ A_\mathrm{v} = g_m R_L$ ,

depending upon whether g_mR_S is much larger or much smaller than one.

In the first case the circuit acts as a current follower, as understood as follows: for R_S >> 1/g_m the voltage source can be replaced by its Norton equivalent with Norton current v_Thév / R_S and parallel Norton resistance R_S. Because the amplifier input resistance is small, the driver delivers by current division a current v_Thév / R_S to the amplifier. The current gain is unity, so the same current is delivered to the output load R_L, producing by Ohm's law an output voltage v_out = v_ThévR_L / R_S, that is, the first form of the voltage gain above.

In the second case R_S << 1/g_m and the Thévenin representation of the source is useful, producing the second form for the gain, typical of voltage amplifiers.

Because the input impedance of the common gate amplifier is very low, the cascode amplifier often is used instead. The cascode places a common source amplifier between the voltage driver and the common gate circuit to permit voltage amplification using a driver with R_S >> 1/g_m.

[edit] References

^ Paul R. Gray, Paul J. Hurst, Stephen H. Lewis, Robert G. Meyer (2001). Analysis and Design of Analog Integrated Circuits, Fourth Edition, New York: Wiley, pp. 186-191. ISBN 0471321680.

[edit] See also

[edit] External Links

A 24GHz CMOS Front-end

v • d • e Transistor amplifiers

	Bipolar junction transistor: Common emitter • Common collector • Common base Field-effect transistor: Common source • Common drain • Common gate Multiple transistors: Darlington pair • Sziklai pair • Cascode • Long-tailed pair