EE3C11 2023-2024

Welcome to the course web site of the BSc course: Structured Electronics Design (EE3C11, Electronics part).

The course and this web site are developed and maintained by the instructors Chris Verhoeven and Anton Montagne

Next lecture:

• Date: Tuesday, March 26 2024

• Time: 10:45 - 12:30

• Location: Chip

• Web page

Educational method

At the beginning of the course, the application specification of an amplifier to be designed will be presented.

Step-by-step design of this amplifier will be discussed during the course.

Motivation of the design steps, their underlying theory and application to other designs will be elucidated.

Examples and exercises will help the participants to understand the design steps and their interaction.

The course will be concluded with a written exam (Brightspace Quiz).

Structure of the lectures

Preparation

Students need to prepare the lecture as follows:

• Study the sections in the book associated with that lecture

• Study the presentations of the lecture

• Watch the videos of the lecture

First hour

1. A classroom poll / discussion provides information about the preparation and the level of understanding.

2. Instructors will elucidate topics using:

   • Posters

   • Demonstrations

   • Ad hoc presentations

Second hour

Students work in groups on the design of the hearing loop antenna system.

Detailed course information

1. Read more about: Structured Electronics Design

2. Read: What you will know at the end of this course

3. For detailed information about the lectures, click the lecture in the list below.

   • 12-02-2024: Introduction
     • Short intro electronics part
     • Downloads
   • 13-02-2024: Electronics 1
     • Systems engineering and amplifier design
     • Case study
     • Demonstrations
     • Downloads
     • Homework
   • 16-02-2024: Electronics 2
     • Introduction to SLiCAP
     • Hearing loop system design
     • Downloads
     • Homework
   • 19-02-2024: Electronics 3
     • Knowledge Test
     • Amplifiers: types and modeling of ideal behavior
     • Downloads
     • Homework
   • 20-02-2024: Electronics 4
     • Homework previous lecture
     • Knowledge Test
     • Amplifiers: characterization and modeling of nonideal behavior
     • Downloads
     • Homework
   • 27-02-2024: Electronics 5
     • Knowledge Test
     • Homework previous lecture
     • Amplifiers: modeling of nonideal behavior
     • Demonstration
     • Homework
   • 01-03-2024: Electronics 6
     • Knowledge Test
     • Homework previous lecture
     • Amplifiers: modeling of small-signal dynamic behavior
     • Estimation of poles and zeros of electrical networks
     • Downloads
     • External links
     • Homework
   • 04-03-2024: Electronics 7
     • Knowledge Test
     • Homework previous lecture
     • Application of negative feedback
     • Downloads
     • Homework
   • 05-03-2024: Electronics 8
     • Homework previous lecture
     • Noise behavior of negative feedback amplifiers
     • Downloads
     • Exercises
     • Homework
   • 12-03-2024: Electronics 9
     • Knowledge Test
     • Homework previous lecture
     • Operational Amplifiers: types and modeling techniques
     • Operational Amplifiers: negative feedback amplifiers with OpAmps as controller
     • Homework
   • 15-03-2024: Electronics 10
     • Knowledge Test
     • Homework previous lecture
     • Introduction to biasing
     • Biasing example
     • Homework
   • 18-03-2024: Electronics 11
     • Knowledge Test
     • Modeling of negative feedback circuits
     • Downloads
     • Homework
   • 19-03-2024: Electronics 12
     • Knowledge Test
     • Negative feedback biasing
     • Port impedance of single-loop feedback amplifiers
     • Accuracy, bandwidth and frequency stability of negative feedback amplifiers
     • Derive controller requirements from amplifier specifications
     • Downloads
     • Homework
   • 26-03-2024: Electronics 13
     • Knowledge Test
     • Frequency stability of negative-feedback amplifiers
     • Downloads
     • Root-locus technique
     • Demonstration frequency (in)stability and frequency compensation
     • Phantom-zero frequency compensation
   • 02-04-2024: Electronics 14
     • Putting it all together: a complete design example
     • Demonstrations
     • Recap and lab preparation
   • 09-04-2024: Electronics 15
     • Poster presentations
   • 10-04-2024: Electronics 16
     • Practicum hearing loop system assembly
   • Exam EE3C11 2024
     • Chapters

Course material

1. The course book can be downloaded for free: Structured Electronics Design - 3rd edition

2. SLiCAP and LTspice source files of this book SED1_5_LTSPICE_SLiCAP.zip

3. A PYTHON-based symbolic SPICE simulator for deriving and solving design equations for electronic circuits. Course participants require a laptop with SLiCAP installed. See SLiCAP for installation instructions.

4. LTspice can be downloaded and installed from here.

5. Posters

   1. Poster EE3C11

   2. Poster Object Performance Specification

   3. Poles and Zeros

   4. Application of Negative Feedback

   5. Modeling of negative feedback

   6. Derive Controller Requirements from Amplifier Specifications

   7. Frequency compensation

Links

• Email: Chris Verhoeven

• Email: Anton Montagne