Difference between revisions of "Nonlinearity"
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\end{align}</math>|{{EquationRef|3}}}} | \end{align}</math>|{{EquationRef|3}}}} | ||
− | Recall that we can express any term in the binomial expansion of <math>\left(x + x^{-1}\right)^n as: | + | Recall that we can express any term in the binomial expansion of <math>\left(x + x^{-1}\right)^n</math> as: |
{{NumBlk|::|<math>{n \choose k} x^{n-k} x^{-k} = {n \choose k} x^{n-2k}</math>|{{EquationRef|4}}}} | {{NumBlk|::|<math>{n \choose k} x^{n-k} x^{-k} = {n \choose k} x^{n-2k}</math>|{{EquationRef|4}}}} | ||
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Thus, for odd <math>n</math>, we get odd powers on of <math>x</math>, and they appear as pairs of positive and negative exponentials. This means that we only generate the odd harmonic frequencies. | Thus, for odd <math>n</math>, we get odd powers on of <math>x</math>, and they appear as pairs of positive and negative exponentials. This means that we only generate the odd harmonic frequencies. | ||
− | For even <math>n</math>, we get the even powers of <math>x</math>, generating only the even harmonics. Also, we get an unpaired middle term that corresponds to the DC component <math>{2k \choose k}e^{jk\theta} \cdot e^{-jk\theta} = {2k \choose k}</math> | + | For even <math>n</math>, we get the even powers of <math>x</math>, generating only the even harmonics. Also, we get an unpaired middle term that corresponds to the DC component: |
+ | |||
+ | {{NumBlk|::|<math>{2k \choose k}e^{jk\theta} \cdot e^{-jk\theta} = {2k \choose k}</math>|{{EquationRef|5}}}} | ||
+ | |||
+ | |||
== Gain Compression == | == Gain Compression == |
Revision as of 09:02, 20 September 2020
Most of the time, we want our amplifiers to be linear. However, since the transistors that we use are inherently nonlinear, our circuits are also inherently nonlinear. One way to analyze nonlinear circuits is to use small-signal analysis, where we assume the circuit is linear for very small signals. In this module, we will look at the effects of nonlinearity that are not seen when performing small-signal analysis.
In this module, we will assume that we have memoryless systems, i.e. systems whose output is an instantaneous function of the input. Thus, we neglect the contribution of energy-storage elements like capacitors and inductors.
Contents
Harmonic Distortion
Consider a memoryless system with input and output . In general, we can express the output as a power series:
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(1)
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Note that for a linear system, is the gain, and for . Let us consider the case when the input is a sinusoid, . Let us further assume that the higher-order terms ( for ) are negligible. We can then express the output as:
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(2)
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Note that the output contains:
- A DC term
- A component with frequency equal to the input frequency, or the fundamental frequency.
- A component at twice the input frequency, or the second harmonic frequency.
- A component at thrice the input frequency, or the third harmonic frequency.
General Distortion Terms
We can use the Binomial Theorem to get for any :
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(3)
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Recall that we can express any term in the binomial expansion of as:
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(4)
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Thus, for odd , we get odd powers on of , and they appear as pairs of positive and negative exponentials. This means that we only generate the odd harmonic frequencies.
For even , we get the even powers of , generating only the even harmonics. Also, we get an unpaired middle term that corresponds to the DC component:
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(5)
-