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The '''open-loop gain''' of an electronic [[amplifier]] is the [[
Open loop gain, in some amplifiers, can be exceedingly high. An ''ideal'' [[operational amplifier]] (op-amp) has infinite open-loop gain. Typically an op-amp may have a maximal open-loop gain of around <math>10^5</math>. The very high open-loop gain of the op-amp allows a wide range of feedback levels to be applied to achieve the desired performance. ▼
▲
Normally, feedback is applied around an amplifier with high open loop gain so that the effective gain [[electrical network|circuit]] is defined and kept to a desired figure. ▼
▲Normally, [[negative feedback]] is applied around an amplifier with high open
==Definition==
The definition of open-loop gain (at a fixed frequency) is
:<math>A_\text{OL} = \frac{V_\text{out}}{V^+ - V^-},</math>▼
where <math>V^ + -V^-</math> is the input voltage difference that is being amplified. (The dependence on frequency is not displayed here.)▼
▲<math>A_\text{OL} = \frac{V_\text{out}}{V^+ - V^-},</math>
▲where <math>V^ + -V^-</math> is the input voltage difference that is being amplified. The dependence on frequency is not displayed here.
== Role in non-ideal gain ==▼
The open-loop gain is a physical attribute of an operational amplifier that is often finite in comparison{{Clarify|date=March 2016}} to the usual gain, denoted <math>G</math>. While open-loop gain is the gain when there is no feedback in a circuit, an operational amplifier will often be configured to use a feedback configuration such that its gain will be controlled by the feedback circuit components.▼
Take the case of an inverting operational amplifier configuration. If the resistor between the single output node and the inverting input node is <math>R_2</math> and the resistor between a source voltage and the inverting input node is <math>R_1</math>, then the ideal gain for such a circuit at the output terminal is defined, ideally, to be:▼
▲The open-loop gain is a physical attribute of an operational amplifier that is often finite in comparison
▲Take the case of an inverting operational amplifier configuration. If the resistor between the single output node and the inverting input node is <math>R_2</math> and the resistor between a source voltage and the inverting input node is <math>R_1</math>, then the
:<math>G = - \frac{R_2}{R_1}</math>
However,
:<math>G = \frac{-\frac{R_2}{R_1}}{1 + (1+{\frac{R_2}{R_1}})\frac{1}{A}}</math>▼
For example, if <math>\frac{R_2}{R_1} = 2</math> and <math>A = 10^4</math>, then <math>G =</math> −1.9994 instead of exactly −2.
▲<math>G = \frac{-\frac{R_2}{R_1}}{1 + (1+{\frac{R_2}{R_1}})\frac{1}{A}}</math>
==Operational amplifiers==
The open-loop gain of an operational amplifier falls very rapidly with increasing [[frequency]]. Along with [[slew rate]], this is one of the reasons why operational amplifiers have limited [[
== See also ==▼
* [[Loop gain]] (includes both the open-loop gain and the feedback attenuation)▼
*[[Gain–bandwidth product]]
*[[Negative-feedback amplifier#Summary of terms|Summary of negative feedback amplifier terms]]
[[Category:Electrical parameters]]
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