User:Sj/EdX

Anant Agarwal and MIT are releasing course videos from EdX's and MIT's popular intro electronics course (taught by Agarwal and Gerry Sussman) - now under a free license. This is an overview of the videos and other materials from the course, as I'm looking at where they might be instructive.

README for the project
A guide to converting an EdX course to a set of Commons media + files, a Wikiversity course, and video clips embedded in articles.
Outlining a course, uploading + embedding video, handling subtitles

Circuits and Electronics 1: Basic Circuit Analysis

Right now, you need to register for the course (anyone can do this at any time) to see these videos and materials:

Textbook

Overview

Introduction to Circuits and Electronics

Welcome lecture for MITx's 6.002x course.
  • Welcome to 6.002x
  • Motivation for 6.002x
  • Course Overview
  • Topics Covered

Using the Tools

  • Circuit Simulator
  • Circuit Simulator - DC Analysis
  • Circuit Simulator - Transient Analysis
  • Circuit Simulator - AC Analysis

Circuit Sandbox

Math Review

First Order Differential Equations

  • 1st Order Differential Equations

Complex Numbers

  • Complex Arithmetic
  • Complex Geomtery
  • POLAR COORDINATES, PART 1
  • POLAR COORDINATES, PART 2
  • Euler's Formula
  • Inverse Euler
  • complex exponentials
  • complex replacement
  • COMPLEX ROOTS, PART 1
  • COMPLEX ROOTS, PART 2

Auto-generated version

Circuits and Electronics 1: Basic Circuit Analysis

Textbook

Textbook

Overview

Introduction to Circuits and Electronics

  • Welcome to 6.002x *
  • Motivation for 6.002x *
  • Course Overview *
  • Topics Covered *

Using the Tools

  • Circuit Simulator *
  • Circuit Simulator - DC Analysis *
  • Circuit Simulator - Transient Analysis *
  • Circuit Simulator - AC Analysis *

Circuit Sandbox

Math Review

First Order Differential Equations

  • 1st Order Differential Equations *

Second Order Differential Equations

Complex Numbers

  • Complex Arithmetic *
  • Complex Geomtery *
  • POLAR COORDINATES, PART 1 *
  • POLAR COORDINATES, PART 2 *
  • Euler's Formula *
  • Inverse Euler *
  • complex exponentials *
  • complex replacement *
  • COMPLEX ROOTS, PART 1 *
  • COMPLEX ROOTS, PART 2 *

Calculus at Length

Entrance Survey

Entrance Survey

Week 1

Circuit Elements

  • Welcome to Circuits and Electronics 1 *
  • S1V4: Lumped element abstraction *
  • S1V5: Lumped element abstraction *
  • S1V6: Lumped element abstraction *
  • S1V7: Lumped element abstraction *
  • S1V8: Demo Setup - Lumped Elements *
  • S1V9: Demo - Taking Abstraction Too Far *
  • S1V10: Lumped Element Abstraction *
  • S1V11: Lumped Element Abstraction *
  • S1V12: KVL, KCL *
  • S1V13: Summary *

Circuit Analysis Toolchest

  • S2V1: Review KVL, KCL *
  • S2V2: Demo- KVL, KCL *
  • S2V3: Method 1 - KVL, KCL method *
  • S2V4: Method 1 - KVL, KCL method *
  • S2V5: Method 2 - Element combination rules *
  • S2V6: Method 3 - Node Analysis *
  • S2V7: Method 3 - Node Analysis *
  • S2V8: Method 3 - Node Analysis *
  • S2V9: Method 3 - Node Analysis *
  • S2V10: Method 3 - Node Analysis *
  • S2V11: Matrix formulation *

Week 1 Tutorials

  • Tutorial intro by Piotr and Gerry *
  • Series resistors *
  • Parallel Resistors *
  • Combination Rules *
  • Nodal analysis *
  • Nodal Analysis with Floating Voltage Source *

Homework 1

Lab 1

Week 2

Linearity and Superposition

  • S3V1: Introduction to Linearity *
  • S3V2: Properties of Linearity *
  • S3V3: Superposition *
  • S3V4: Superposition *
  • S3V5: Superposition *
  • S3V6: Demo Superposition *
  • S3V7: Thevenin Method *
  • S3V8: Thevenin Method *
  • S3V9: Thevenin Method *
  • S3V10: Norton Method *
  • S3V11: Summary *

Static Discipline and Boolean Logic

  • S4V1: Intro, Review *
  • S4V2: Why Digital *
  • S4V3: Why Digital *
  • S4V4: Why Digital *
  • S4V5: Static Discipline *
  • S4V6: Static Discipline *
  • S4V7: Static Discipline *
  • S4V8: Static Discipline *
  • S4V9: Static Discipline *
  • S4V10: Digital Logic Circuits *
  • S4V11: Digital Logic Circuits *
  • S4V12: Digital Logic Circuits *
  • S4V13: Digital Logic Circuits *
  • S4V14: Digital Logic Circuits *
  • S4V15: Demo Setup - Chain Saw *
  • S4V16: Demo - Chain Saw *

Week 2 Tutorials

  • How good is the lightbulb model? *
  • Using nodal analysis *
  • Using superposition *

Homework 2

Lab 2

Week 3

Inside the Gate

  • S5V1: Review, Gates *
  • S5V2: Demo Setup - Gates *
  • S5V3: Demo - Gates *
  • S5V4: How to Use a Gate *
  • S5V5: Switch Model *
  • Duplicate of 'S5V5: Switch Model' *
  • S5V6: Switch Model *
  • S5V7: Switch Model *
  • S5V8: Switch Model *
  • S5V9.1: MOSFET Device, S Model, Demo Setup *
  • S5V9.2: MOSFET Device, S Model, Demo Setup *
  • S5V10: MOSFET Device, S Model, Demo Setup *
  • S5V11: DEMO MOSFET Switch Device, S Model Curve *
  • S5V12: MOSFET Inverter *
  • S5V13: MOSFET Inverter *
  • S5V14: SR Model *
  • S5V15: DEMO SR Model Curve *
  • S5V16: Inverters Based on SR Model *
  • S5V17: Static Power in Digital Circuits, Insights *
  • S5V18: Demo - Shatter a Mouse *

Circuits with Nonlinear Elements

  • S6V1: Review of the Course So Far *
  • S6V2: Nonlinear Elements *
  • S6V3: Method 1 - Analytical Method *
  • S6V4: Method 1 - Analytical Method *
  • S6V5: Method 1 - Analytical Method *
  • S6V6: Method 2 - Graphical Method *
  • S6V7: Method 2 - Graphical Method *
  • S6V8: Method 3 - Piecewise Linear Method *
  • S6V9: Method 3 - Piecewise Linear Method *
  • S6V10: Method 3 - Piecewise Linear Method *
  • S6V11: Method 4 - Motivate the Incremental Method *
  • S6V12: Method 4 - Motivate the Incremental Method *
  • S6V13: Demo - Distorted Music with Nonlinear Element *
  • S6V14: If Only Circuits Were Linear... *

Week 3 Tutorials

Homework 3

Lab 3

Week 4

Incremental Analysis

  • S7V1: Review *
  • S7V2: Intro - Setup for Demo, Curve Plotting Animation *
  • S7V3: DEMO - Music Over a Light Beam, Distorted Sinusoid and Music *
  • S7V4: Incremental Method Insight *
  • S7V5: Incremental Method Insight *
  • S7V6: DEMO - Music Over a Light Beam, Distortion and No Distortion *
  • S7V7: Mathematical Meaning *
  • S7V8: Mathematical Meaning *
  • S7V9: Mathematical Meaning *
  • S7V10: Graphical Meaning *
  • S7V11: Circuit Model *
  • S7V12: Circuit Model *
  • S7V13: Small Signal Circuit Elements *
  • S7V14: Small Signal Circuit Elements *
  • S7V15: Small Signal Circuit Solution Example *
  • S7V16: Small Signal Circuit Solution Example *

Dependent Sources and Amplifiers

  • S8V1: Review *
  • S8V2: Intro to Dependent Sources *
  • S8V3: Example Dependent Source Circuit *
  • S8V4: Various Types of Dependent Sources *
  • S8V5: Another Dependent Source Example *
  • S8V6: Another Dependent Source Example *
  • S8V7: Superposition with (Linear) Dependent Sources *
  • S8V8: Intro to Amplifiers, Why Amplify *
  • S8V9: Intro to Amplifiers, Why Amplify *
  • S8V10: Build Amplifier with Abstract Dependent Source *
  • S8V11: Build Amplifier with Abstract Dependent Source *
  • S8V12: DEMO - Amplification *
  • S8V13: What Happens to Amplifier When Dependent Source has to Source Power *
  • S8V14: What Happens to Amplifier When Dependent Source has to Source Power *
  • S8V15: What Happens to Amplifier When Dependent Source has to Source Power *
  • S8V16: DEMO - Amplifier Transfer Function Stops Behaving Well *
  • Conclusion *

Week 4 Tutorials

  • Load Line Experimental Demo *
  • Small signal model *
  • An abstract element *
  • Small signal model of a diode *
  • Good schematics *

Homework 4

Lab 4

Practice Exam Problems (Not Graded)

Practice Exam Problems

Fall 2015 Final Exam Beta

Fall 2015 Final Beta

Additional Problems

Exit Survey

Exit Survey

Final Exam

Final