Common base

Last updated September 16, 2024

In electronics, a common-base (also known as grounded-base) amplifier is one of three basic single-stage bipolar junction transistor (BJT) amplifier topologies, typically used as a current buffer or voltage amplifier.

Applications

This arrangement is not very common in low-frequency discrete circuits, where it is usually employed for amplifiers that require an unusually low input impedance, for example to act as a preamplifier for moving-coil microphones. However, it is popular in integrated circuits and in high-frequency amplifiers, for example for VHF and UHF, because its input capacitance does not suffer from the Miller effect, which degrades the bandwidth of the common-emitter configuration, and because of the relatively high isolation between the input and output. This high isolation means that there is little feedback from the output back to the input, leading to high stability.

This configuration is also useful as a current buffer, since it has a current gain of approximately unity (see formulae below). Often a common base is used in this manner, preceded by a common-emitter stage. The combination of these two form the cascode configuration, which possesses several of the benefits of each configuration, such as high input impedance and isolation.

Low-frequency characteristics

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 BJT has been employed. The input signal is represented by a Thévenin voltage source v_s with a series resistance R_s and the load is a resistor R_L. This circuit can be used to derive the following characteristics of the common base amplifier.

	Definition	Expression	Approximate expression	Conditions
Open-circuit voltage gain	${A_{v}}=\left.{\frac {v_{\text{o}}}{v_{\text{i}}}}\right\|_{R_{L}=\infty }$	${\frac {(g_{m}r_{\text{o}}+1)R_{C}}{R_{C}+r_{o}}}$	$g_{m}R_{C}$	$r_{o}\gg R_{C}$
Short-circuit current gain	$A_{i}=\left.{i_{\text{o}} \over i_{\text{i}}}\right\|_{R_{L}=0}$	${\frac {r_{\pi }+\beta r_{o}}{r_{\pi }+(\beta +1)r_{o}}}$	$1$	$\beta \gg 1$
Input resistance	$R_{\text{in}}={\frac {v_{i}}{i_{i}}}$	${\frac {(r_{o}+R_{C}\parallel R_{L})r_{E}}{r_{o}+r_{E}+{\frac {R_{C}\parallel R_{L}}{\beta +1}}}}$	$r_{e}\left(\approx {\frac {1}{g_{m}}}\right)$	$r_{o}\gg R_{C}\parallel R_{L}\quad \left(\beta \gg 1\right)$
Output resistance	$R_{\text{out}}=\left.{\frac {v_{o}}{-i_{o}}}\right\|_{v_{s}=0}$	$R_{C}\parallel \left([1+g_{m}(r_{\pi }\parallel R_{S})]r_{o}+r_{\pi }\parallel R_{S}\right)$	${\begin{aligned}R_{C}&\parallel r_{o}\\R_{C}&\parallel \left(r_{o}\left[1+g_{m}\left(r_{\pi }\parallel R_{S}\right)\right]\right)\end{aligned}}$	${\begin{aligned}R_{S}&\ll r_{E}\\R_{S}&\gg r_{E}\end{aligned}}$

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.

Active loads

For voltage amplification, the range of allowed output voltage swing in this amplifier is tied to voltage gain when a resistor load R_C is employed, as in Figure 1. That is, large voltage gain requires large R_C, and that in turn implies a large DC voltage drop across R_C. For a given supply voltage, the larger this drop, the smaller the transistor V_CB and the less output swing is allowed before saturation of the transistor occurs, with resultant distortion of the output signal. To avoid this situation, an active load can be used, for example, a current mirror. If this choice is made, the value of R_C in the table above is replaced by the small-signal output resistance of the active load, which is generally at least as large as the r_O of the active transistor in Figure 1. On the other hand, the DC voltage drop across the active load has a fixed low value (the compliance voltage of the active load), much less than the DC voltage drop incurred for comparable gain using a resistor R_C. That is, an active load imposes less restriction on the output voltage swing. Notice that active load or not, large AC gain still is coupled to large AC output resistance, which leads to poor voltage division at the output except for large loads R_L ≫ R_out.

For use as a current buffer, gain is not affected by R_C, but output resistance is. Because of the current division at the output, it is desirable to have an output resistance for the buffer much larger than the load R_L being driven, so large signal currents can be delivered to a load. If a resistor R_C is used, as in Figure 1, a large output resistance is coupled to a large R_C, again limiting the signal swing at the output. (Even though current is delivered to the load, usually a large current signal into the load implies a large voltage swing across the load as well.) An active load provides high AC output resistance with much less serious impact upon the amplitude of output signal swing.

Overview of characteristics

Several example applications are described in detail below. A brief overview follows.

The amplifier input impedance R_in looking into the emitter node is very low, given approximately by

R_{\text{in}}=r_{E}={\frac {V_{T}}{I_{E}}},

where V_T is the thermal voltage, and I_E is the DC emitter current.

For example, for V_T = 26 mV and I_E = 10 mA, rather typical values, R_in = 2.6 Ω. If I_E is reduced to increase R_in, there are other consequences like lower transconductance, higher output resistance and lower β that also must be considered. A practical solution to this low-input-impedance problem is to place a common-emitter stage at the input to form a cascode amplifier.

Because the input impedance is so low, most signal sources have larger source impedance than the common-base amplifier R_in. The consequence is that the source delivers a current to the input rather than a voltage, even if it is a voltage source. (According to Norton's theorem, this current is approximately i_in = v_S / R_S). If the output signal also is a current, the amplifier is a current buffer and delivers the same current as is input. If the output is taken as a voltage, the amplifier is a transresistance amplifier and delivers a voltage dependent on the load impedance, for example v_out = i_inR_L for a resistor load R_L much smaller in value than the amplifier output resistance R_out. That is, the voltage gain in this case (explained in more detail below) is

v_{\text{out}}=i_{\text{in}}R_{L}=v_{s}{\frac {R_{L}}{R_{S}}}\Rightarrow A_{v}={\frac {v_{\text{out}}}{v_{S}}}={\frac {R_{L}}{R_{S}}}.

Note that for source impedances such that R_S ≫ r_E the output impedance approaches R_out = R_C || [g_m (r_π || R_S) r_O].

For the special case of very low-impedance sources, the common-base amplifier does work as a voltage amplifier, one of the examples discussed below. In this case (explained in more detail below), when R_S ≪ r_E and R_L ≪ R_out, the voltage gain becomes

A_{v}={\frac {v_{\text{out}}}{v_{S}}}={\frac {R_{L}}{r_{E}}}\approx g_{m}R_{L},

where g_m = I_C / V_T is the transconductance. Notice that for low source impedance, R_out = r_O || R_C.

The inclusion of r_O in the hybrid-pi model predicts reverse transmission from the amplifiers output to its input, that is the amplifier is bilateral. One consequence of this is that the input/output impedance is affected by the load/source termination impedance, hence, for example, the output resistance R_out may vary over the range r_O || R_C ≤ R_out ≤ (β + 1) r_O || R_C, depending on the source resistance R_S. The amplifier can be approximated as unilateral when neglect of r_O is accurate (valid for low gains and low to moderate load resistances), simplifying the analysis. This approximation often is made in discrete designs, but may be less accurate in RF circuits, and in integrated-circuit designs, where active loads normally are used.

Voltage amplifier

For the case when the common-base circuit is used as a voltage amplifier, the circuit is shown in Figure 2.

The output resistance is large, at least R_C || r_O, the value which arises with low source impedance (R_S ≪ r_E). A large output resistance is undesirable in a voltage amplifier, as it leads to poor voltage division at the output. Nonetheless, the voltage gain is appreciable even for small loads: according to the table, with R_S = r_E the gain is A_v = g_m R_L / 2. For larger source impedances, the gain is determined by the resistor ratio R_L / R_S, and not by the transistor properties, which can be an advantage where insensitivity to temperature or transistor variations is important.

An alternative to the use of the hybrid-pi model for these calculations is a general technique based upon two-port networks. For example, in an application like this one where voltage is the output, a g-equivalent two-port could be selected for simplicity, as it uses a voltage amplifier in the output port.

For R_S values in the vicinity of r_E the amplifier is transitional between voltage amplifier and current buffer. For R_S ≫ r_E the driver representation as a Thévenin source should be replaced by representation with a Norton source. The common base circuit stops behaving like a voltage amplifier and behaves like a current follower, as discussed next.

Current follower

Figure 3 shows the common base amplifier used as a current follower. The circuit signal is provided by an AC Norton source (current I_S, Norton resistance R_S) at the input, and the circuit has a resistor load R_L at the output.

As mentioned earlier, this amplifier is bilateral as a consequence of the output resistance r_O, which connects the output to the input. In this case the output resistance is large even in the worst case (it is at least r_O || R_C and can become (β + 1) r_O || R_C for large R_S). Large output resistance is a desirable attribute of a current source because favorable current division sends most of the current to the load. The current gain is very nearly unity as long as R_S ≫ r_E.

An alternative analysis technique is based upon two-port networks. For example, in an application like this one where current is the output, an h-equivalent two-port is selected because it uses a current amplifier in the output port.

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The diamond buffer or diamond follower is a four-transistor, two-stage, push-pull, translinear emitter follower, or less commonly source follower, in which the input transistors are folded, or placed upside-down with respect to the output transistors. Like any unity buffer, the diamond buffer does not alter the phase and magnitude of input voltage signal; its primary purpose is to interface a high-impedance voltage source with a low-impedance, high-current load. Unlike the more common compound emitter follower, where each input transistor drives the output transistor of the same polarity, each input transistor of a diamond buffer drives the output transistor of the opposite polarity. When the transistors operate in close thermal contact, the input transistors stabilize the idle current of the output pair, eliminating the need for a bias spreader.

References

External links

ECE 327: Transistor Basics — Gives example common base circuit (i.e., current source) with explanation.

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v t e Transistor amplifiers
	Bipolar junction transistor:	Common emitter Common collector Common base
	Field-effect transistor:	Common source Common drain Common gate
	Multiple transistors:	Darlington transistor Complementary feedback pair Cascode Long-tailed pair