A buffer amplifier (sometimes simply called a buffer) is one that provides

electrical impedance In electrical engineering, impedance is the opposition to alternating current presented by the combined effect of resistance and reactance in a circuit. Quantitatively, the impedance of a two-terminal circuit element is the ratio of the com ...

transformation from one circuit to another, with the aim of preventing the signal source from being affected by whatever currents (or voltages, for a current buffer) that the load may be produced with. The signal is 'buffered from' load currents. Two main types of buffer exist: the voltage buffer and the current buffer.

Voltage buffer

A voltage buffer amplifier is used to transfer a voltage from a first circuit, having a high

output impedance The output impedance of an electrical network is the measure of the opposition to current flow (impedance), both static ( resistance) and dynamic ( reactance), into the load network being connected that is ''internal'' to the electrical source. The ...

level, to a second circuit with a low

input impedance The input impedance of an electrical network is the measure of the opposition to current ( impedance), both static ( resistance) and dynamic ( reactance), into the load network that is ''external'' to the electrical source. The input admittance (the ...

level. The interposed buffer amplifier prevents the second circuit from loading the first circuit unacceptably and interfering with its desired operation, since without the voltage buffer the voltage of the second circuit is influenced by output impedance of the first circuit (as it is larger than the input impedance of the second circuit). In the ideal voltage buffer in the diagram, the input resistance is infinite and the output resistance zero (output impedance of an ideal voltage source is zero). Other properties of the ideal buffer are: perfect linearity, regardless of signal amplitudes; and instant output response, regardless of the speed of the input signal. If the voltage is transferred unchanged (the voltage gain ''A_v'' is 1), the amplifier is a unity gain buffer; also known as a voltage follower because the output voltage ''follows'' or tracks the input voltage. Although the voltage gain of a voltage buffer amplifier may be (approximately) unity, it usually provides considerable current gain and thus power gain. However, it is commonplace to say that it has a gain of 1 (or the equivalent 0 dB), referring to the voltage gain. As an example, consider a Thévenin source (voltage ''V_A'', series resistance ''R_A'') driving a resistor load ''R_L''. Because of

voltage division Voltage, also known as electric pressure, electric tension, or (electric) potential difference, is the difference in electric potential between two points. In a static electric field, it corresponds to the work needed per unit of charge to ...

(also referred to as "loading") the voltage across the load is only ''V_A R_L / ( R_L + R_A )''. However, if the Thévenin source drives a unity gain buffer such as that in Figure 1 (top, with unity gain), the voltage input to the amplifier is ''V_A'', and with ''no voltage division'' because the amplifier input resistance is infinite. At the output the dependent voltage source delivers voltage ''A_v V_A = V_A'' to the load, again without voltage division because the output resistance of the buffer is zero. A Thévenin equivalent circuit of the combined original Thévenin source ''and'' the buffer is an ideal voltage source ''V_A'' with zero Thévenin resistance.

Current buffer

Typically a current buffer amplifier is used to transfer a current from a first circuit, having a low

level, to a second circuit with a high

level. The interposed buffer amplifier prevents the second circuit from loading the first circuit's current unacceptably and interfering with its desired operation. In the ideal current buffer in the diagram, the output impedance is infinite (an ideal current source) and the input impedance is zero (a short circuit). Again, other properties of the ideal buffer are: perfect linearity, regardless of signal amplitudes; and instant output response, regardless of the speed of the input signal. For a current buffer, if the current is transferred unchanged (the current gain ''β_i'' is 1), the amplifier is again a unity gain buffer; this time known as a current follower because the output current ''follows'' or tracks the input current. As an example, consider a Norton source (current ''I_A'', parallel resistance ''R_A'') driving a resistor load ''R_L''. Because of

current division Currents, Current or The Current may refer to: Science and technology * Current (fluid), the flow of a liquid or a gas ** Air current, a flow of air ** Ocean current, a current in the ocean *** Rip current, a kind of water current ** Current (stre ...

(also referred to as "loading") the current delivered to the load is only ''I_A R_A / ( R_L + R_A )''. However, if the Norton source drives a unity gain buffer such as that in Figure 1 (bottom, with unity gain), the current input to the amplifier is ''I_A'', with ''no current division'' because the amplifier input resistance is zero. At the output the dependent current source delivers current ''β_i I_A = I_A'' to the load, again without current division because the output resistance of the buffer is infinite. A Norton equivalent circuit of the combined original Norton source ''and'' the buffer is an ideal current source ''I_A'' with infinite Norton resistance.

Voltage buffer examples

Op-amp implementation

unity Unity may refer to: Buildings * Unity Building, Oregon, Illinois, US; a historic building * Unity Building (Chicago), Illinois, US; a skyscraper * Unity Buildings, Liverpool, UK; two buildings in England * Unity Chapel, Wyoming, Wisconsin, US; ...

gain buffer amplifier may be constructed by applying a full series negative feedback (Fig. 2) to an op-amp simply by connecting its output to its inverting input, and connecting the signal source to the non-inverting input (Fig. 3). Unity gain here implies a ''voltage gain'' of one (i.e. 0 dB), but significant ''current gain'' is expected. In this configuration, the entire output voltage (β = 1 in Fig. 2) is fed back into the inverting input. The difference between the non-inverting input voltage and the inverting input voltage is amplified by the op-amp. This connection forces the op-amp to adjust its output voltage to simply equal the input voltage (V_out follows V_in so the circuit is named op-amp voltage follower). The impedance of this circuit does not come from any change in voltage, but from the input and output impedances of the op-amp. The input impedance of the op-amp is very high (1 MΩ to 10 TΩ), meaning that the input of the op-amp does not load down the source and draws only minimal current from it. Because the output impedance of the op-amp is very low, it drives the load as if it were a perfect

voltage source A voltage source is a two-terminal device which can maintain a fixed voltage. An ideal voltage source can maintain the fixed voltage independent of the load resistance or the output current. However, a real-world voltage source cannot supply unl ...

. Both the connections to and from the buffer are therefore bridging connections, which reduce power consumption in the source,

distortion In signal processing, distortion is the alteration of the original shape (or other characteristic) of a signal. In communications and electronics it means the alteration of the waveform of an information-bearing signal, such as an audio signa ...

from overloading, crosstalk and other electromagnetic interference.

Single-transistor circuits

Other unity gain buffer amplifiers include the

bipolar junction transistor A bipolar junction transistor (BJT) is a type of transistor that uses both electrons and electron holes as charge carriers. In contrast, a unipolar transistor, such as a field-effect transistor, uses only one kind of charge carrier. A bipola ...

common-collector In electronics, a common collector amplifier (also known as an emitter follower) is one of three basic single-stage bipolar junction transistor (BJT) amplifier topologies, typically used as a voltage buffer. In this circuit the base terminal ...

configuration (called an ''emitter follower'' because the emitter voltage follows the base voltage, or a ''voltage follower'' because the output voltage follows the input voltage); the

field effect transistor The field-effect transistor (FET) is a type of transistor that uses an electric field to control the flow of current in a semiconductor. FETs (JFETs or MOSFETs) are devices with three terminals: ''source'', ''gate'', and ''drain''. FETs contro ...

in common-drain configuration (called a

source follower In electronics, a common-drain amplifier, also known as a source follower, is one of three basic single-stage field-effect transistor (FET) amplifier topologies, typically used as a voltage buffer. In this circuit (NMOS) the gate terminal of the ...

because the source voltage follows the gate voltage or, again, a ''voltage follower'' because the output voltage follows the input voltage); or similar configurations using

vacuum tube A vacuum tube, electron tube, valve (British usage), or tube (North America), is a device that controls electric current flow in a high vacuum between electrodes to which an electric potential difference has been applied. The type known as ...

s (

cathode follower An amplifier, electronic amplifier or (informally) amp is an electronic device that can increase the magnitude of a signal (a time-varying voltage or current). It may increase the power significantly, or its main effect may be to boost the ...

), or other active devices. All such amplifiers actually have a gain of slightly less than unity, but the difference is usually small and unimportant.

Impedance transformation using the bipolar voltage follower

Using the small-signal circuit in Figure 4, the impedance seen looking into the circuit is ::

R_ = \frac   = r_ + (\beta + 1) ( , ,  )

(The analysis uses the relation ''g_mr_π = (I_C /V_T) (V_T /I_B)'' = β, which follows from the evaluation of these parameters in terms of the bias currents.) Assuming the usual case where ''r_O'' >> ''R_L'', the impedance looking into the buffer is larger than the load ''R_L'' without the buffer by a factor of (β + 1), which is substantial because β is large. The impedance is increased even more by the added ''r_π'', but often ''r_π'' << (β + 1) R_L, so the addition does not make much difference

Impedance transformation using the MOSFET voltage follower

Using the small-signal circuit in Figure 5, the impedance seen looking into the circuit is no longer ''R_L'' but instead is infinite (at low frequencies) because the MOSFET draws no current. As frequency is increased, the parasitic capacitances of the transistors come into play and the transformed input impedance drops with frequency.

Chart of single-transistor amplifiers

Some configurations of single-transistor amplifier can be used as a buffer to isolate the driver from the load. For most digital applications, an NMOS voltage follower (common drain) is the preferred configuration. These amplifiers have high input impedance, which means that the digital system will not need to supply a large current.

Logic buffer amplifiers

A non-linear buffer amplifier is sometimes used in digital circuits where a high current is required, perhaps for driving more gates than the normal

fan-out In digital electronics, the fan-out is the number of gate inputs driven by the output of another single logic gate. In most designs, logic gates are connected to form more complex circuits. While no logic gate input can be fed by more than one ...

of the logic family used, or for driving displays, or long wires, or other difficult loads. It is common for a single package to contain several discrete buffer amplifiers. For example, a hex buffer is a single package containing 6 discrete buffer amplifiers, and an octal buffer is a single package containing 8 discrete buffer amplifiers. The terms inverting buffer and non-inverting buffer effectively correspond with high-current capability single-input NOR or OR gates respectively.

Speaker array amplifiers

The majority of amplifiers used to drive large speaker arrays, such as those used for rock concerts, are amplifiers with 26-36dB voltage gain capable of high amounts of current into low impedance speaker arrays where the speakers are wired in parallel.

Driven guards

A driven guard utilizes a voltage buffer to protect a very high impedance signal line by surrounding the line with a shield driven by a buffer to the same voltage as the line, the close voltage matching of the buffer prevents the shield from leaking significant current into the high impedance line while the low impedance of the shield can absorb any stray currents that could affect the signal line.

Current buffer examples

Simple unity gain buffer amplifiers include the

common-base 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. In this circuit the emitte ...

configuration, or the MOSFET in

common-gate 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 serve ...

configuration (called a ''current follower'' because the output current follows the input current). The current gain of a current buffer amplifier is (approximately) unity.

Single-transistor circuits

Figure 6 shows a bipolar current buffer biased with a current source (designated ''I_E'' for DC emitter current) and driving another DC current source as active load (designated ''I_C'' for DC collector current). The AC input signal current ''i_in'' is applied to the emitter node of the transistor by an AC Norton current source with Norton resistance ''R_S''. The AC output current ''i_out'' is delivered by the buffer via a large coupling capacitor to load ''R_L''. This coupling capacitor is large enough to be a short circuit at frequencies of interest. Because the transistor output resistance connects input and output sides of the circuit, there is a (very small) backward voltage feedback from the output to the input so this circuit is not unilateral. In addition, for the same reason, the input resistance depends (slightly) upon the output load resistance, and the output resistance depends significantly on the input driver resistance. For more detail see the article on

common base amplifier Common may refer to: Places * Common, a townland in County Tyrone, Northern Ireland * Boston Common, a central public park in Boston, Massachusetts * Cambridge Common, common land area in Cambridge, Massachusetts * Clapham Common, originally com ...

References

{{Reflist Electronic amplifiers

Voltage buffer

Current buffer

Voltage buffer examples

Op-amp implementation

Single-transistor circuits

Impedance transformation using the bipolar voltage follower

Impedance transformation using the MOSFET voltage follower

Chart of single-transistor amplifiers

Logic buffer amplifiers

Speaker array amplifiers

Driven guards

Current buffer examples

Single-transistor circuits

See also

References