Activity: Noise Analysis: 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 NGSPICE.

Activity 1: NMOS Noise

Bias a 1.8V LVT NMOS transistor with ${\displaystyle V_{GS}=0.9\mathrm {V} }$ and ${\displaystyle V_{DS}=0.9\mathrm {V} }$. For a width of ${\displaystyle 10\mathrm {\mu m} }$ and a length of ${\displaystyle 0.35\mathrm {\mu m} }$:

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

Run a noise analysis from ${\displaystyle 1\mathrm {Hz} }$ to ${\displaystyle 100\mathrm {GHz} }$. You can use this sample schematic as a starting point.

• Plot the drain current noise power spectral density.
  • 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 ${\displaystyle 0.45\mathrm {\mu m} }$. Identify and explain any changes in the drain current noise power spectral density.

Activity 2: PMOS Noise

Repeat Activity 1 but with a 1.8V LVT PMOS transistor with the same size and with ${\displaystyle V_{GS}=-0.9\mathrm {V} }$ and ${\displaystyle V_{DS}=-0.9\mathrm {V} }$.

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.

Submission

This activity is for both graduate and undergraduate students. For UP students, the submission bin link will be posted in Piazza.