Difference between revisions of "Noise Analysis"

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== Noise in LTI Systems ==
 
== Noise in LTI Systems ==
[[File:Noise LTI.png|thumb|400px|Figure 1: Injecting noise in LTI systems.]]
+
[[File:Noise LTI.png|thumb|350px|Figure 1: Injecting noise in LTI systems.]]
 
Once we have our device models with the appropriate noise generators, we can determine the effects of these individual noise sources on the behavior of larger circuits. Consider the linear and time invariant (LTI) system with transfer function <math>H\left(f\right)</math> shown in Fig. 1. If we inject noise <math>S_i\left(f\right)</math>, we would get:
 
Once we have our device models with the appropriate noise generators, we can determine the effects of these individual noise sources on the behavior of larger circuits. Consider the linear and time invariant (LTI) system with transfer function <math>H\left(f\right)</math> shown in Fig. 1. If we inject noise <math>S_i\left(f\right)</math>, we would get:
  
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=== Passive Circuits ===
 
=== Passive Circuits ===
[[File:Noise passive RLC.png|thumb|400px|Figure 2: Noise in passive circuits.]]
+
[[File:Noise passive RLC.png|thumb|450px|Figure 2: Noise in passive circuits.]]
 
For the generalized passive circuit shown in Fig. 2, composed of only "noisy" resistors, plus ideal capacitors and inductors, and with an effective impedance across terminals <math>A</math> and <math>B</math> equal to <math>Z\left(f\right)</math>, the equivalent "spot noise" noise is:
 
For the generalized passive circuit shown in Fig. 2, composed of only "noisy" resistors, plus ideal capacitors and inductors, and with an effective impedance across terminals <math>A</math> and <math>B</math> equal to <math>Z\left(f\right)</math>, the equivalent "spot noise" noise is:
  
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==== Example: An RC Circuit ====
 
==== Example: An RC Circuit ====
 +
[[File:Noise RC example.png|thumb|200px|Figure 3: An RC Circuit.]]
 
Given the RC circuit in Fig. 3, we can calculate the equivalent impedance seen at the two terminals as:
 
Given the RC circuit in Fig. 3, we can calculate the equivalent impedance seen at the two terminals as:
  
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{{NumBlk|::|<math>\overline{v^2_o}=\sum_k \left|H_{k,o}\right|^2\cdot \overline{v^2_{n,k}}</math>|{{EquationRef|7}}}}
 
{{NumBlk|::|<math>\overline{v^2_o}=\sum_k \left|H_{k,o}\right|^2\cdot \overline{v^2_{n,k}}</math>|{{EquationRef|7}}}}
  
Where <math>\overline{v^2_{n,k}}</math> is the noise from the <math>k^\mathrm{th}</math> noise source, <math>H_{k,o}</math> is the gain from <math>k^\mathrm{th}</math> noise source to the port of interest, and we also assume the noise sources are independent of each other.
+
Where <math>\overline{v^2_{n,k}}</math> is the noise from the <math>k^\mathrm{th}</math> noise source, <math>H_{k,o}</math> is the gain from <math>k^\mathrm{th}</math> noise source to the port of interest when all other noise sources and inputs are set to zero, and we also assume the noise sources are independent of each other.
  
 
=== Input Equivalent Noise Generators ===
 
=== Input Equivalent Noise Generators ===
 +
[[File:Noise input referred.png|thumb|Figure 4: Input equivalent noise generators.]]
 
The output noise is a convenient metric to show how "noisy" a circuit is, since it is easy to measure. However, comparing the noise performance of different circuits solely based on the output noise can lead to erroneous results since the output noise also depends on the circuit gain. Hence, we are not sure if a large output noise is due to the inherent noise of the circuit, or possibly due to a relatively large gain. In order to remove this dependency on the circuit gain, we can instead model a "noisy" two-port network using input equivalent noise generators, as shown in Fig. 4.
 
The output noise is a convenient metric to show how "noisy" a circuit is, since it is easy to measure. However, comparing the noise performance of different circuits solely based on the output noise can lead to erroneous results since the output noise also depends on the circuit gain. Hence, we are not sure if a large output noise is due to the inherent noise of the circuit, or possibly due to a relatively large gain. In order to remove this dependency on the circuit gain, we can instead model a "noisy" two-port network using input equivalent noise generators, as shown in Fig. 4.
  
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We can calculate <math>\overline{v_n^2}</math> by shorting the input, calculating the output noise, then dividing the output noise with the square of the transfer function from the input voltage to the output. Note that by shorting the input, all the current from <math>\overline{i_n^2}</math> flows into the short, thus, only <math>\overline{v_n^2}</math> contributes to the output noise, as shown in Fig. 5. Similarly, we can calculate <math>\overline{i_n^2}</math> by leaving the input open-circuited, calculating the output noise, then dividing the output noise by the square of the transfer function from the input current to the output. Again, when we open-circuit the input, only the input current noise generator contributes to the output noise, as seen in Fig. 6.
 
We can calculate <math>\overline{v_n^2}</math> by shorting the input, calculating the output noise, then dividing the output noise with the square of the transfer function from the input voltage to the output. Note that by shorting the input, all the current from <math>\overline{i_n^2}</math> flows into the short, thus, only <math>\overline{v_n^2}</math> contributes to the output noise, as shown in Fig. 5. Similarly, we can calculate <math>\overline{i_n^2}</math> by leaving the input open-circuited, calculating the output noise, then dividing the output noise by the square of the transfer function from the input current to the output. Again, when we open-circuit the input, only the input current noise generator contributes to the output noise, as seen in Fig. 6.
 +
 +
{|
 +
| [[File:Noise input referred v.png|thumb|400px|Figure 5: Calculating <math>\overline{v_n^2}</math>.]]
 +
| [[File:Noise input referred i.png|thumb|400px|Figure 6: Calculating <math>\overline{i_n^2}</math>.]]
 +
|-
 +
|}
  
 
==== Example: BJT Input Equivalent Noise ====
 
==== Example: BJT Input Equivalent Noise ====
 +
[[File:CE BJT noise example.png|thumb|500px|Figure 7: The small signal model of a noisy common-emitter amplifier.]]
 +
Let us calculate the input equivalent noise of a common-emitter BJT amplifier, whose small signal model is shown in Fig. 7. To get the input equivalent current noise generator, <math>\overline{i_n^2}</math>, we open-circuit the base. Note the transfer functions <math>\tfrac{i_o}{i_b} = \beta</math> and <math>\tfrac{i_o}{i_c}=1</math>. The short-circuit output current noise is then:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
\overline{i^2_{o,\mathrm{oc}}} & =\overline{i^2_c} + \beta^2 \overline{i^2_b} \\
 +
& = \beta^2 \overline{i^2_n}\\
 +
\end{align}</math>|{{EquationRef|8}}}}
 +
 +
Thus, we get the input equivalent current noise generator:
 +
 +
{{NumBlk|::|<math>\overline{i^2_n}=\overline{i^2_b} + \frac{\overline{i^2_c}}{\beta^2} \approx \overline{i^2_b}</math>|{{EquationRef|9}}}}
 +
 +
To obtain the input equivalent noise generator <math>\overline{v_n^2}</math>, we short-circuit the base. Again note that <math>\tfrac{i_o}{v_{r_b}} = g_m\cdot \tfrac{Z_\pi}{Z_\pi + r_b}</math> where <math>Z_\pi = r_\pi \| \tfrac{1}{j\omega C_\pi}=\tfrac{\beta}{g_m}</math>. Thus,
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
\overline{i^2_{o,\mathrm{sc}}} & =\overline{i^2_c} + g_m^2 \cdot \overline{v^2_{r_b}}\cdot \left(\frac{Z_\pi}{Z_\pi + r_b}\right)^2 \\
 +
& =\overline{i^2_c} + \overline{v^2_{r_b}}\cdot \frac{\beta^2}{\left(Z_\pi + r_b\right)^2} \\
 +
& =\overline{v^2_n}\cdot \frac{\beta^2}{\left(Z_\pi + r_b\right)^2} \\
 +
\end{align}</math>|{{EquationRef|10}}}}
 +
 +
The input equivalent voltage noise generator is then:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
\overline{v^2_n} & =\overline{v^2_{r_b}} + \overline{i^2_c}\cdot \frac{\left(Z_\pi + r_b\right)^2}{\beta^2} \\
 +
& \approx \overline{v^2_{r_b}} + \overline{i^2_c}\cdot \frac{Z_\pi^2}{\beta^2} \\
 +
& \approx \overline{v^2_{r_b}} + \frac{\overline{i^2_c}}{g_m^2} \\
 +
\end{align}</math>|{{EquationRef|11}}}}
 +
 +
Thus, at low frequencies:
 +
 +
{{NumBlk|::|<math>\overline{v^2_n}\approx 4kTr_b\Delta f + \frac{2qI_C\Delta f}{g_m^2}</math>|{{EquationRef|12}}}}
 +
{{NumBlk|::|<math>\overline{i^2_n}\approx 2qI_B \Delta f = \frac{2q I_C \Delta f}{\beta}</math>|{{EquationRef|13}}}}
 +
 +
=== The Effect of Source Resistance ===
 +
[[File:Noise 2port Rs.png|thumb|500px|Figure 8: Driving a noisy two-port network with a source resistance <math>R_S</math>.]]
 +
Let <math>R_S</math> be the resistance of a source driving a two-port network, shown in Fig. 8. For the extreme case when <math>R_S=0</math>, only <math>\overline{v^2_n}</math> determines the output noise since the input looks like a short circuit when calculating the output noise. For the other extreme case when <math>R_S\rightarrow\infty</math>, the output noise is solely determined by <math>\overline{i^2_n}</math>. Thus, we can see that the output noise is dependent on the source resistance <math>R_S</math>. Therefore, intuitively, for large <math>R_S</math>, we want amplifiers with low <math>\overline{i^2_n}</math>, e.g. a MOSFET-based amplifier, while for small <math>R_S</math>, we want amplifiers with low <math>\overline{v^2_n}</math>, e.g. amplifiers using BJTs.
 +
 +
If the two-port network in Fig. 8 has a voltage gain <math>A_v</math> and an input impedance <math>R_\mathrm{in}</math>, we can express the output noise as:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
\overline{v^2_o} & = \left(\overline{v^2_n}\cdot A_v^2 + \overline{v^2_{R_S}}\cdot A_v^2 \right)\cdot \left(\frac{R_\mathrm{in}}{R_\mathrm{in} + R_S} \right)^2 + \overline{i^2_n}\cdot \left(\frac{R_\mathrm{in}}{R_\mathrm{in} + R_S} \right)^2 \cdot R_S^2\cdot A_v^2\\
 +
& = \left(\overline{v^2_n} + \overline{i^2_n} R_S^2+ \overline{v^2_{R_S}}\right)\cdot A_v^2 \cdot\left(\frac{R_\mathrm{in}}{R_\mathrm{in} + R_S} \right)^2 \\
 +
\end{align}</math>|{{EquationRef|14}}}}
 +
 +
If we define <math>\overline{v_{i,eq}^2} = \overline{v_n^2} + R_S^2\cdot \overline{i_n^2}</math>, we can calculate the noise figure as:
 +
 +
{{NumBlk|::|<math>F = 1 + \frac{N_\mathrm{amp,i}}{N_S}= 1 + \frac{\overline{v_{i,eq}^2}}{\overline{v^2_{R_S}}} = 1 + \frac{\overline{v_n^2} + R_S^2\cdot \overline{i_n^2}}{\overline{v^2_{R_S}}}</math>|{{EquationRef|15}}}}
 +
 +
If we further define <math>R_n</math> and <math>G_n</math> as:
 +
 +
{{NumBlk|::|<math>\overline{v^2_n}=4kT R_n \Delta f</math>|{{EquationRef|16}}}}
 +
{{NumBlk|::|<math>\overline{i^2_n}=4kT G_n \Delta f</math>|{{EquationRef|17}}}}
 +
 +
We get:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
F & = 1 + \frac{4kT R_n \Delta f + R_S^2 \cdot 4kT G_n \Delta f}{4kT R_S \Delta f} \\
 +
& = 1 + \frac{R_n}{R_S} + G_n R_S
 +
\end{align}</math>|{{EquationRef|18}}}}
 +
 +
Since <math>R_S</math> appears both at the numerator and denominator, we can conclude that there must be a value of <math>R_S</math> that minimizes the noise figure. Thus, taking the derivative of <math>F</math> with respect to <math>R_S</math>, we get:
 +
 +
{{NumBlk|::|<math>\frac{\partial F}{\partial R_S} = 0 = G_n - \frac{R_n}{R_S^2}</math>|{{EquationRef|19}}}}
 +
 +
Gives us:
 +
 +
{{NumBlk|::|<math>R_{S,\mathrm{opt}} = \sqrt{\frac{R_n}{G_n}}=\sqrt{\frac{\overline{v^2_n}}{\overline{i^2_n}}}</math>|{{EquationRef|20}}}}
 +
 +
Note that this assumes that <math>\overline{v^2_n}</math> and <math>\overline{i^2_n}</math> are uncorrelated. We can then calculate the minimum noise figure:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
F_\min & = 1 + G_n\cdot R_{S,\mathrm{opt}} + \frac{R_n}{R_{S,\mathrm{opt}}} \\
 +
& = 1 + G_n \cdot \sqrt{\frac{R_n}{G_n}} + R_n\cdot\sqrt{\frac{G_n}{R_n}} \\
 +
& = 1 + 2\sqrt{R_n  G_n}
 +
\end{align}</math>|{{EquationRef|21}}}}
 +
 +
Therefore, for a given <math>R_S</math>, there is an optimal ratio of <math>\overline{v^2_n}</math> to <math>\overline{i^2_n}</math>, or alternatively, for a given amplifier, there is an optimal source resistance that will give us the minimum noise figure. If we take the difference between an amplifier noise figure and the minimum noise figure, we get:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
F-F_\min & = 1 + G_n R_S + \frac{R_n}{R_S}- \left(1 + 2\sqrt{R_n G_n} \right)\\
 +
& = \frac{R_n}{R_S}\cdot \left(1 + \frac{G_n R_S^2}{R_n} -\frac{2R_S}{R_n}\cdot\sqrt{R_n G_n} \right) \\
 +
& = \frac{R_n}{R_S}\cdot\left(1 + \frac{R_S^2}{R_{S,\mathrm{opt}}^2} - 2\cdot\frac{R_S}{R_{S,\mathrm{opt}}}\right) \\
 +
& = \frac{R_n}{R_S}\cdot\left|\frac{R_S}{R_{S,\mathrm{opt}}}-1\right|^2 = R_n R_S\cdot \left|\frac{1}{R_{S,\mathrm{opt}}}-\frac{1}{R_S}\right|^2\\
 +
& = R_n R_S\cdot \left|G_{S,\mathrm{opt}} - G_S^2\right|^2\\
 +
\end{align}</math>|{{EquationRef|22}}}}
 +
 +
Or equivalently:
 +
 +
{{NumBlk|::|<math>F=F_\min + R_n R_S\cdot \left|G_{S,\mathrm{opt}} - G_S^2\right|^2</math>|{{EquationRef|23}}}}
 +
 +
Where <math>G_S=\tfrac{1}{R_S}</math> and <math>G_{S,\mathrm{opt}}=\tfrac{1}{R_{S,\mathrm{opt}}}</math>. We can then calculate how far our circuit is from the minimum noise figure, given how far we are from the optimal source resistance. Thus, <math>R_n</math> is sometimes called the ''noise sensitivity parameter''. We want to minimize <math>R_n</math> so that the noise match is not too sensitive to the changes in <math>G_S</math>.
 +
 +
==== Example: BJT Noise Figure ====
 +
Recall from the previous example that:
 +
 +
{{NumBlk|::|<math>\overline{v_n^2}=\overline{v_{r_b}^2} + \frac{\overline{i_c^2}}{g_m^2} = 4kT r_b\cdot \Delta f + \frac{2q I_c \Delta f}{g_m^2}</math>|{{EquationRef|24}}}}
 +
{{NumBlk|::|<math>\overline{i_n^2}=\overline{i_b^2} =2q I_B \Delta f = 2q \frac{I_C}{\beta} \Delta f</math>|{{EquationRef|25}}}}
 +
 +
Thus, the noise figure for the common-emitter BJT amplifier, driven by a source with source resistance <math>R_S</math>, is:
 +
 +
{{NumBlk|::|<math>\begin{align}
 +
F & = 1 + \frac{4kT r_b \Delta f + \frac{2q I_C \Delta f}{g_m^2}+ \frac{2q I_C \Delta f}{\beta} R_S^2}{4kT R_S \Delta f} \\
 +
& = 1 + \frac{r_b}{R_S} + \frac{1}{2 g_m R_S} + \frac{g_m R_S}{2\beta}
 +
\end{align}</math>|{{EquationRef|26}}}}
 +
 +
=== Correlated Noise Sources ===
 +
[[File:Correlated noise sources.png|thumb|250px|Figure 9: Correlated input equivalent noise sources.]]
 +
If <math>\overline{v_n^2}</math> and <math>\overline{i_n^2}</math> are correlated, we can partition the noise current into two components: (1) <math>i_u</math>, the component uncorrelated to <math>v_n</math>, and (2) <math>i_c</math>, the component correlated to <math>v_n</math>, such that:
 +
 +
{{NumBlk|::|<math>i_n = i_u + i_c</math>|{{EquationRef|27}}}}
 +
 +
As shown in Fig. 9. Since <math>i_u</math> and <math>v_n</math> are independent, we can write the dot product as:
 +
 +
{{NumBlk|::|<math>\langle i_u, v_n \rangle = 0</math>|{{EquationRef|28}}}}
 +
 +
Since <math>i_c</math> and <math>v_n</math> are correlated, we define the admittance <math>Y_C</math> as:
 +
 +
{{NumBlk|::|<math>i_c = Y_C\cdot v_n</math>|{{EquationRef|29}}}}
 +
 +
Thus, the input equivalent voltage noise is:
 +
 +
{{NumBlk|::|<math>v_{i,eq}=v_n\cdot \left(1 + Y_C Z_S\right) +  i_u \cdot Z_S</math>|{{EquationRef|30}}}}
 +
 +
Then we can express the noise power at the input as:
 +
 +
{{NumBlk|::|<math>\overline{v_{i,eq}^2}=\overline{v_n^2}\cdot \left|1 + Y_C Z_S\right|^2 +  \overline{i_u^2}\cdot \left|Z_S\right|^2</math>|{{EquationRef|31}}}}
 +
 +
The noise figure is then:
 +
 +
{{NumBlk|::|<math>F = 1 + \frac{\overline{v_n^2}\cdot \left|1 + Y_C Z_S\right|^2 +  \overline{i_u^2}\cdot \left|Z_S\right|^2}{\overline{v_S^2}}</math>|{{EquationRef|32}}}}
 +
 +
If we let <math>\overline{v^2_n}=4kT R_n \Delta f</math>, <math>\overline{v^2_S}=4kT R_S \Delta f</math>, and <math>\overline{i^2_u}=4kT G_u \Delta f</math>, we then get:
 +
 +
{{NumBlk|::|<math>F = 1 + \frac{R_n\cdot \left|1 + Y_C Z_S\right|^2 +  G_u\cdot \left|Z_S\right|^2}{R_S}</math>|{{EquationRef|33}}}}
 +
 +
And if we further define <math>Y_C = G_C + jB_C</math> and <math>Y_S=\tfrac{1}{Z_S} = G_S + jB_S</math>, then to minimize the noise figure, we get:
 +
 +
{{NumBlk|::|<math>B_{S,\mathrm{opt}}=-B_C</math>|{{EquationRef|34}}}}
 +
{{NumBlk|::|<math>G_{S,\mathrm{opt}}=\sqrt{\frac{G_u}{R_n} + G_C^2}</math>|{{EquationRef|35}}}}
 +
 +
We then get an expression for the minimum noise figure:
 +
 +
{{NumBlk|::|<math>F_\min = 1 + 2G_C R_n + 2\sqrt{R_n G_u + G_C^2 R_n^2}</math>|{{EquationRef|36}}}}
 +
 +
Note that for <math>G_C=0</math>, we arrive at the minimum noise figure for the uncorrelated case. And similarly, the noise figure, in terms of <math>F_\min</math> can be expressed as:
 +
 +
{{NumBlk|::|<math>F = F_\min + \frac{R_n}{G_S}\left|Y_S - Y_{S,\mathrm{opt}}\right|^2</math>|{{EquationRef|37}}}}
 +
 +
Where <math>Y_{S,\mathrm{opt}}=G_{S,\mathrm{opt}} + jB_{S,\mathrm{opt}}</math>. Again, if we cannot achieve the optimum source admittance or if we have significant variations in our system, we want to minimize <math>R_n</math> to reduce the sensitivity of the noise figure to the "distance" between the actual source admittance and the optimal source admittance.
 +
 +
{{Note|[[229-A2.2 | '''Activity A2.2''' Noise Analysis]] -- This activity walks you through the analysis of "noisy" circuits, and its effects on circuit behavior.|reminder}}

Latest revision as of 11:22, 11 October 2020

Noise in LTI Systems

Figure 1: Injecting noise in LTI systems.

Once we have our device models with the appropriate noise generators, we can determine the effects of these individual noise sources on the behavior of larger circuits. Consider the linear and time invariant (LTI) system with transfer function shown in Fig. 1. If we inject noise , we would get:

 

 

 

 

(1)

Thus, the output noise spectrum is shaped or "filtered" by the magnitude of the transfer function. Note that the phase is random and cannot be determined. The total integrated noise at the output of the LTI system is:

 

 

 

 

(2)

Passive Circuits

Figure 2: Noise in passive circuits.

For the generalized passive circuit shown in Fig. 2, composed of only "noisy" resistors, plus ideal capacitors and inductors, and with an effective impedance across terminals and equal to , the equivalent "spot noise" noise is:

 

 

 

 

(3)

Note that since is frequency dependent, the spectral density of the noise is shaped by the inductors and capacitors, even though only the resistors generate noise. We can then calculate the total integrated noise:

 

 

 

 

(4)

Example: An RC Circuit

Figure 3: An RC Circuit.

Given the RC circuit in Fig. 3, we can calculate the equivalent impedance seen at the two terminals as:

 

 

 

 

(5)

Where . Thus, the total integrated noise is:

 

 

 

 

(6)

Note that the total integrated noise is independent of . This is due to the fact that the thermal noise spectral density is proportional to , but the bandwidth is inversely proportional to , thus cancelling each other out.

Two-Port Noise Analysis

In general, we perform noise analysis in the small signal domain since, for most circuits, the noise signals are relatively small, allowing us to use superposition. Thus, for a circuit with "noisy" elements, we can calculate the noise seen at any port, e.g. the output port, as:

 

 

 

 

(7)

Where is the noise from the noise source, is the gain from noise source to the port of interest when all other noise sources and inputs are set to zero, and we also assume the noise sources are independent of each other.

Input Equivalent Noise Generators

Figure 4: Input equivalent noise generators.

The output noise is a convenient metric to show how "noisy" a circuit is, since it is easy to measure. However, comparing the noise performance of different circuits solely based on the output noise can lead to erroneous results since the output noise also depends on the circuit gain. Hence, we are not sure if a large output noise is due to the inherent noise of the circuit, or possibly due to a relatively large gain. In order to remove this dependency on the circuit gain, we can instead model a "noisy" two-port network using input equivalent noise generators, as shown in Fig. 4.

Thus, we can replace any noisy two-port network with a noiseless two-port network and (1) an equivalent input voltage noise source, , and (2) an equivalent current noise source, . Note that in general, these noise sources are correlated, but let us ignore the correlation for now.

We can calculate by shorting the input, calculating the output noise, then dividing the output noise with the square of the transfer function from the input voltage to the output. Note that by shorting the input, all the current from flows into the short, thus, only contributes to the output noise, as shown in Fig. 5. Similarly, we can calculate by leaving the input open-circuited, calculating the output noise, then dividing the output noise by the square of the transfer function from the input current to the output. Again, when we open-circuit the input, only the input current noise generator contributes to the output noise, as seen in Fig. 6.

Figure 5: Calculating .
Figure 6: Calculating .

Example: BJT Input Equivalent Noise

Figure 7: The small signal model of a noisy common-emitter amplifier.

Let us calculate the input equivalent noise of a common-emitter BJT amplifier, whose small signal model is shown in Fig. 7. To get the input equivalent current noise generator, , we open-circuit the base. Note the transfer functions and . The short-circuit output current noise is then:

 

 

 

 

(8)

Thus, we get the input equivalent current noise generator:

 

 

 

 

(9)

To obtain the input equivalent noise generator , we short-circuit the base. Again note that where . Thus,

 

 

 

 

(10)

The input equivalent voltage noise generator is then:

 

 

 

 

(11)

Thus, at low frequencies:

 

 

 

 

(12)

 

 

 

 

(13)

The Effect of Source Resistance

Figure 8: Driving a noisy two-port network with a source resistance .

Let be the resistance of a source driving a two-port network, shown in Fig. 8. For the extreme case when , only determines the output noise since the input looks like a short circuit when calculating the output noise. For the other extreme case when , the output noise is solely determined by . Thus, we can see that the output noise is dependent on the source resistance . Therefore, intuitively, for large , we want amplifiers with low , e.g. a MOSFET-based amplifier, while for small , we want amplifiers with low , e.g. amplifiers using BJTs.

If the two-port network in Fig. 8 has a voltage gain and an input impedance , we can express the output noise as:

 

 

 

 

(14)

If we define , we can calculate the noise figure as:

 

 

 

 

(15)

If we further define and as:

 

 

 

 

(16)

 

 

 

 

(17)

We get:

 

 

 

 

(18)

Since appears both at the numerator and denominator, we can conclude that there must be a value of that minimizes the noise figure. Thus, taking the derivative of with respect to , we get:

 

 

 

 

(19)

Gives us:

 

 

 

 

(20)

Note that this assumes that and are uncorrelated. We can then calculate the minimum noise figure:

 

 

 

 

(21)

Therefore, for a given , there is an optimal ratio of to , or alternatively, for a given amplifier, there is an optimal source resistance that will give us the minimum noise figure. If we take the difference between an amplifier noise figure and the minimum noise figure, we get:

 

 

 

 

(22)

Or equivalently:

 

 

 

 

(23)

Where and . We can then calculate how far our circuit is from the minimum noise figure, given how far we are from the optimal source resistance. Thus, is sometimes called the noise sensitivity parameter. We want to minimize so that the noise match is not too sensitive to the changes in .

Example: BJT Noise Figure

Recall from the previous example that:

 

 

 

 

(24)

 

 

 

 

(25)

Thus, the noise figure for the common-emitter BJT amplifier, driven by a source with source resistance , is:

 

 

 

 

(26)

Correlated Noise Sources

Figure 9: Correlated input equivalent noise sources.

If and are correlated, we can partition the noise current into two components: (1) , the component uncorrelated to , and (2) , the component correlated to , such that:

 

 

 

 

(27)

As shown in Fig. 9. Since and are independent, we can write the dot product as:

 

 

 

 

(28)

Since and are correlated, we define the admittance as:

 

 

 

 

(29)

Thus, the input equivalent voltage noise is:

 

 

 

 

(30)

Then we can express the noise power at the input as:

 

 

 

 

(31)

The noise figure is then:

 

 

 

 

(32)

If we let , , and , we then get:

 

 

 

 

(33)

And if we further define and , then to minimize the noise figure, we get:

 

 

 

 

(34)

 

 

 

 

(35)

We then get an expression for the minimum noise figure:

 

 

 

 

(36)

Note that for , we arrive at the minimum noise figure for the uncorrelated case. And similarly, the noise figure, in terms of can be expressed as:

 

 

 

 

(37)

Where . Again, if we cannot achieve the optimum source admittance or if we have significant variations in our system, we want to minimize to reduce the sensitivity of the noise figure to the "distance" between the actual source admittance and the optimal source admittance.

Activity A2.2 Noise Analysis -- This activity walks you through the analysis of "noisy" circuits, and its effects on circuit behavior.