Operational amplifier applications

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This article illustrates some typical applications of solid-state integrated circuit operational amplifiers. A simplified schematic notation is used, and the reader is reminded that many details such as device selection and power supply connections are not shown.

The resistors used in these configurations are typically in the kΩ range. <1 kΩ range resistors cause excessive current flow and possible damage to the device. >1 MΩ range resistors cause excessive thermal noise and make the circuit operation susceptible to significant errors due to bias currents.

Note: It is important to realize that the equations shown below, pertaining to each type of circuit, assume that it is an ideal op amp. Those interested in construction of any of these circuits for practical use should consult a more detailed reference. See the External links and References sections.

Contents

[edit] Linear circuit applications

[edit] Differential amplifier

Differential amplifier
Differential amplifier

The circuit shown is used for finding the difference of two voltages each multiplied by some constant (determined by the resistors).

The name "differential amplifier" should not be confused with the "differentiator", also shown on this page.

 V_\mathrm{out} = V_2 \left( { \left( R_\mathrm{f} + R_1 \right) R_\mathrm{g} \over \left( R_\mathrm{g} + R_2 \right) R_1} \right) - V_1 \left( {R_\mathrm{f} \over R_1} \right)
  • Differential Zin (between the two input pins) = R1 + R2

[edit] Amplified difference

Whenever R1 = R2 and Rf = Rg,

[edit] Inverting amplifier

Inverting amplifier
Inverting amplifier

Inverts and amplifies a voltage (multiplies by a negative constant)

 V_\mathrm{out} = -V_\mathrm{in} ( R_\mathrm{f} / R_\mathrm{in} ) \!\
  • Zin = Rin (because V is a virtual ground)
  • A third resistor, of value R_\mathrm{f} \| R_\mathrm{in} = R_\mathrm{f} R_\mathrm{in} / (R_\mathrm{f} + R_\mathrm{in}) , added between the non-inverting input and ground, while not necessary, minimizes errors due to input bias currents.

[edit] Non-inverting amplifier

Non-inverting amplifier
Non-inverting amplifier

Amplifies a voltage (multiplies by a constant greater than 1)

 V_\mathrm{out} = V_\mathrm{in} \left( 1 + {R_2 \over R_1} \right)
  • Z_\mathrm{in} = \infin (realistically, at least the input impedance of the opamp itself, 1 MΩ to 10 TΩ. In many cases, the input impedance is significantly higher as a consequence of the feedback network)
  • A third resistor, of value R_\mathrm{f} \| R_\mathrm{in}, added between the Vin source and the non-inverting input, while not necessary, minimizes errors due to input bias currents.

[edit] Voltage follower

Voltage follower
Voltage follower

Used as a buffer amplifier, to eliminate loading effects or to interface impedances (connecting a device with a high source impedance to a device with a low input impedance). Due to the strong feedback, this circuit tends to get unstable when driving a high capacity load. This can be avoided by connecting the load through a resistor.

 V_\mathrm{out} = V_\mathrm{in} \!\
  • Z_\mathrm{in} = \infin (realistically, the differential input impedance of the op-amp itself, 1 MΩ to 1 TΩ)

[edit] Summing amplifier

Summing amplifier
Summing amplifier

Sums several (weighted) voltages

 V_\mathrm{out} = - R_\mathrm{f} \left( { V_1 \over  R_1 } + { V_2 \over R_2 } + \cdots + {V_n \over R_n} \right)
  • When R_1 = R_2 = \cdots = R_n, and Rf independent
 V_\mathrm{out} = - \left( {R_\mathrm{f} \over R_1} \right) (V_1 + V_2 + \cdots + V_n ) \!\
  • When R_1 = R_2 = \cdots = R_n = R_\mathrm{f}
 V_\mathrm{out} = - ( V_1 + V_2 + \cdots + V_n ) \!\
  • Output is inverted
  • Input impedance Zn = Rn, for each input (V is a virtual ground)

[edit] Integrator

Integrating amplifier
Integrating amplifier

Integrates the (inverted) signal over time

 V_\mathrm{out} = \int_0^t - {V_\mathrm{in} \over RC} \, dt + V_\mathrm{initial}

(where Vin and Vout are functions of time, Vinitial is the output voltage of the integrator at time t = 0.)

[edit] Differentiator

Differentiating amplifier
Differentiating amplifier

Differentiates the (inverted) signal over time.

The name "differentiator" should not be confused with the "differential amplifier", also shown on this page.

V_\mathrm{out} = - RC \left( {dV_\mathrm{in} \over dt} \right)

(where Vin and Vout are functions of time)

[edit] Comparator

Comparator
Comparator
Main article: Comparator

Compares two voltages and outputs the greater of the two states.

  •  V_\mathrm{out} = \left\{\begin{matrix} V_\mathrm{S+} & V_1 > V_2 \\ V_\mathrm{S-} & V_1 < V_2 \end{matrix}\right.

[edit] Instrumentation amplifier

Instrumentation amplifier
Instrumentation amplifier

Combines very high input impedance, high common-mode rejection, low DC offset, and other properties used in making very accurate, low-noise measurements

[edit] Schmitt trigger

Schmitt trigger
Schmitt trigger
Main article: Schmitt trigger

A comparator with hysteresis

Hysteresis from \frac{-R_1}{R_2}V_{sat} to \frac{R_1}{R_2}V_{sat}.

[edit] Inductance gyrator

Inductance gyrator
Inductance gyrator
Main article: Gyrator

Simulates an inductor.

[edit] Zero level detector

Voltage divider reference

  • Zener sets reference voltage

[edit] Negative impedance converter (NIC)

Negative impedance converter
Negative impedance converter

Creates a resistor having a negative value for any signal generator

  • In this case, the ratio between the input voltage and the input current (thus the input resistance) is given by:
R_\mathrm{in} = - R_3 \frac{R_1}{R_2}

for more information see the main article Negative impedance converter.

[edit] Non-linear configurations

[edit] Precision rectifier

Super diode
Super diode
Main article: Precision rectifier

Behaves like an ideal diode for the load, which is here represented by a generic resistor RL.

  • This basic configuration has some limitations. For more information and to know the configuration that is actually used, see the main article.


[edit] Logarithmic output

Logarithmic configuration
Logarithmic configuration
  • The relationship between the input voltage vin and the output voltage vout is given by:
v_\mathrm{out} = -V_{\gamma} \ln \left( \frac{v_\mathrm{in}}{I_\mathrm{S} \cdot R} \right)

where IS is the saturation current.

  • If the operational amplifier is considered ideal, the negative pin is virtually grounded, so the current flowing into the resistor from the source (and thus through the diode to the output, since the op-amp inputs draw no current) is:
\frac{v_\mathrm{in}}{R} = I_\mathrm{R} = I_\mathrm{D}

where ID is the current through the diode. As known, the relationship between the current and the voltage for a diode is:

I_\mathrm{D} = I_\mathrm{S} \left( e^{\frac{V_\mathrm{D}}{V_{\gamma}}} - 1 \right)

This, when the voltage is greater than zero, can be approximated by:

I_\mathrm{D} \simeq I_\mathrm{S} e^{V_\mathrm{D} \over V_{\gamma}}

Putting these two formulae together and considering that the output voltage is the negative of the voltage across the diode (Vout = − VD), the relationship is proven.

Note that this implementation does not consider temperature stability and other non-ideal effects.

[edit] Exponential output

Exponential configuration
Exponential configuration
  • The relationship between the input voltage vin and the output voltage vout is given by:
v_\mathrm{out} = - R I_\mathrm{S} e^{v_\mathrm{in} \over V_{\gamma}}

where IS is the saturation current.

  • Considering the operational amplifier ideal, then the negative pin is virtually grounded, so the current through the diode is given by:
I_\mathrm{D} = I_\mathrm{S} \left( e^{\frac{V_\mathrm{D}}{V_{\gamma}}} - 1 \right)

when the voltage is greater than zero, it can be approximated by:

I_\mathrm{D} \simeq I_\mathrm{S} e^{V_\mathrm{D} \over V_{\gamma}}

The output voltage is given by:

v_\mathrm{out} = -R I_\mathrm{D}\,

[edit] Other applications

[edit] See also

[edit] References

  • Paul Horowitz and Winfield Hill, "The Art of Electronics 2nd Ed. " Cambridge University Press, Cambridge, 1989 ISBN 0-521-37095-7
  • Sergio Franco, "Design with Operational Amplifiers and Analog Integrated Circuits," 3rd Ed., McGraw-Hill, New York, 2002 ISBN 0-07-232084-2

[edit] External links

Wikibooks
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