EE220 2024 Noise Analysis and Simulation: Difference between revisions

• Instructions: This activity is structured as a tutorial with an activity at the end. Should you have any questions, clarifications, or issues, please contact your instructor as soon as possible.
• At the end of this activity, the student should be able to:

1. Perform noise simulations using Cadence Spectre using the GlobalFoundries 22nm FDSOI design kit.

Activity 1: NMOS Noise

Bias a 0.8V SLVT NMOS transistor with ${\displaystyle V_{GS}=0.4\mathrm {V} }$ and ${\displaystyle V_{DS}=0.4\mathrm {V} }$. For a width of ${\displaystyle 1\mathrm {\mu m} }$ and a length of ${\displaystyle L_{\min }}$:

• What is the resulting DC drain current?
• What is the transistor's ${\displaystyle g_{m}}$ and ${\displaystyle V^{*}={\frac {2I_{D}}{g_{m}}}}$?

Run a noise analysis from ${\displaystyle 1\mathrm {Hz} }$ to ${\displaystyle 100\mathrm {GHz} }$.

• Plot the drain current noise power spectral density, ${\displaystyle {\frac {\overline {i_{dn}^{2}\left(f\right)}}{\Delta f}}}$.
  • Identify the regions where thermal noise and flicker noise dominates.
  • What is the flicker noise corner?
  • Estimate the value of ${\displaystyle \gamma }$.
  • Estimate the value of ${\displaystyle {\frac {K_{f}}{C_{ox}}}}$
• What is the total integrated drain current noise power?

Recall that the MOSFET drain current noise can be modeled as:

${\displaystyle {\overline {i_{dn}^{2}}}={\frac {K_{f}I_{D}}{C_{ox}L^{2}}}{\frac {\Delta f}{f}}+4kT\gamma g_{m}\Delta f}$

Change the length of the transistor to ${\displaystyle 2L_{\min }}$ and ${\displaystyle 3L_{\min }}$. Identify and explain any changes in the drain current noise power spectral density.

Activity 2: PMOS Noise

Repeat Activity 1 but with a 0.8V SLVT PMOS transistor with the same size and with ${\displaystyle V_{GS}=-0.4\mathrm {V} }$ and ${\displaystyle V_{DS}=-0.4\mathrm {V} }$.

Activity 3: Cascode Amplifier Noise Analysis

Consider the cascoded NMOS amplifier (biased with an ideal current source) shown in Fig. 1. Ignoring all other capacitances except ${\displaystyle C_{L}}$, and given the small-signal parameters ${\displaystyle g_{m1}}$, ${\displaystyle g_{m2}}$, ${\displaystyle r_{o1}}$ and ${\displaystyle r_{o2}}$:

Figure 1: A cascode amplifier.

1. Calculate the small-signal gain of the cascode amplifier, ${\displaystyle A_{v}\!\left(s\right)={\frac {v_{out}}{v_{in}}}}$. Assume ${\displaystyle g_{m1}r_{o1}\gg 1}$ and ${\displaystyle g_{m2}r_{o2}\gg 1}$.
2. Calculate the noise spectral density, ${\displaystyle {\overline {v_{out}^{2}\left(f\right)}}}$, and the total integrated output noise, ${\displaystyle {\overline {v_{out,T}^{2}}}}$. Assuming that ${\displaystyle r_{o1}\rightarrow \infty }$ and ${\displaystyle r_{o2}\rightarrow \infty }$, and that the flicker noise is zero.
3. Repeat (2) but with finite ${\displaystyle r_{o1}}$ and ${\displaystyle r_{o2}}$. How does this affect the output noise?

Activity 4: Input-Referred Noise

Given the gate-source capacitance, ${\displaystyle C_{GS}}$, of transistor ${\displaystyle M_{1}}$ of the cascode amplifier in Fig. 1, calculate:

• The input equivalent voltage noise generator, ${\displaystyle {\overline {v_{i,eq}^{2}\left(f\right)}}}$.
• The input equivalent current noise generator, ${\displaystyle {\overline {i_{i,eq}^{2}\left(f\right)}}}$.

Note that when calculating the output noise, you can assume that ${\displaystyle r_{o1}\rightarrow \infty }$ and ${\displaystyle r_{o2}\rightarrow \infty }$, but when calculating the gains, assume finite ${\displaystyle r_{o1}}$ and ${\displaystyle r_{o2}}$.

Report Guide

Write up a report (maximum of 5 pages including figures) answering the questions above. Include annotated graphs if needed.