Design: A Simple Common-Source Amplifier: 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. Design a simple common-source amplifier.

Activity 1: Transistor Intrinsic Gain

We can determine the intrinsic NMOS small-signal gain, ${\displaystyle a_{0}=g_{m}\cdot r_{o}}$, for a desired DC operating point, i.e for a given drain current, ${\displaystyle I_{DC}}$, and drain-to-source voltage, ${\displaystyle V_{DS}}$. This implies a certain gate-to-source voltage, ${\displaystyle V_{GS}}$. For square-law devices, we can easily calculate the required ${\displaystyle V_{GS}}$ that corresponds to ${\displaystyle I_{DC}}$ and ${\displaystyle V_{DS}}$. However, for deep submicron devices that do not follow the square law, we can either run simulations to determine this ${\displaystyle V_{GS}}$, or instead, we can let SPICE calculate ${\displaystyle V_{GS}}$ for us. As seen in Fig. 1, we can use negative feedback to obtain the appropriate ${\displaystyle V_{GS}}$.

Figure 1: The NMOS intrinsic gain simulation setup.

Figure 2: The NMOS intrinsic gain.

Using the circuit in Fig. 1, with ${\displaystyle W=40\mathrm {\mu m} }$, ${\displaystyle L=0.15\mathrm {\mu m} }$, ${\displaystyle I_{D}=1\mathrm {mA} }$, and the ideal amplifier gain, ${\displaystyle A_{v}=1000}$:

• Sweep ${\displaystyle V_{DS}}$ from 200mV to 1.8V, and plot ${\displaystyle V_{GS}}$ as a function of ${\displaystyle V_{DS}}$.
• From the ${\displaystyle V_{GS}}$ vs. ${\displaystyle V_{DS}}$ plot, derive the NMOS instrinsic gain, ${\displaystyle a_{0}=\left({\frac {\partial V_{GS}}{\partial V_{DS}}}\right)^{-1}}$, as a function of ${\displaystyle V_{DS}}$.
• Repeat for transistor lengths of ${\displaystyle 0.20\mathrm {\mu m} }$, ${\displaystyle 0.25\mathrm {\mu m} }$, ${\displaystyle 0.30\mathrm {\mu m} }$, ${\displaystyle 0.35\mathrm {\mu m} }$, and ${\displaystyle 0.40\mathrm {\mu m} }$, and generate the graphs in Fig. 2.

Note that you can use a voltage-controlled voltage source (VCVS) to model the ideal amplifier.

Design: A Common-Source Amplifier

Figure 3: A simple NMOS common-source amplifier.

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.