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Table of Contents

Circuits I & II

These course materials combine techniques for the analysis and simulation of linear electric circuits, and measurements of their properties. Topics include resistive and energy-storage circuit elements, controlled sources and operational amplifiers, systematic analysis methods, AC steady state, power systems, magnetic coupling and transformers, transients, frequency response, and Laplace transform and computer simulation methods using LTspice. Circuit analysis techniques such as Kirchhoff’s Laws, node voltages, and mesh currents. Thevenin and Norton equivalent circuits, sinusoidal steady state and phasors.

The textbooks and teaching materials provided on this wiki are considered open source and available for free use in non-commercial educational and academic settings. The only requirement is that they continue to retain the attribution to Analog Devices Inc. Supplying them on the ADI wiki allows registered users to contribute to the materials posted here improving the content and keeping them up to date.

Table of Contents:

The following are suggested topics selected from Wikipedia and Khan Academy

Circuits I

Title
Chapter 1: Circuit Analysis FundamentalsElectrical networks
The Voltage source
The Current source
Ohm's Law
Circuit analysis
Chapter 2: Circuit ReductionSimplifying resistor networks
Chapter 3: Nodal and Mesh AnalysisNodal Analysis
Mesh Analysis
Chapter 4: Systems and Network TheoremsElectrical Circuit, Network analysis
Chapter 5 - Series And Parallel Circuits Series, Parallel Circuits
Chapter 6 - Divider CircuitsVoltage Divider Circuits
Current Divider Circuits
Chapter 7 - Kirchhoff's LawsKirchhoff's Circuit Laws
Chapter 8 - Series-parallel Combination CircuitsSuperposition theorem
Linear circuits
Chapter 9 Thévenin's theorem
Norton's theorem
Source transformation
Maximum power transfer theorem
RMS Power vs. Average Power

Useful YouTube Videos:
An Introduction to Simple Electric Circuits (3rd Edition)
Essential & Practical Circuit Analysis: Part 1- DC Circuits
Essential & Practical Circuit Analysis: Part 2- Op-Amps

Circuits II

Title
Chapter 1 - Operational AmplifiersIdeal Voltage Feedback (VFB) Op Amp
Inverting Amplifier
Inverting Summing Amplifier
Chapter 2 - RC and L/R Time ConstantsRC circuits
RC time constant
RL circuits
RLC circuits
LC circuits
Chapter 3 - Reactance and Impedance - Inductive
Chapter 4 - Reactance And Impedance - Capacitive
Chapter 5 - Reactance And Impedance - R, L, And C
Chapter 6 - ResonanceElectrical resonance
Chapter 8 - FiltersFilters
Low pass filter
High pass filter
Band pass filter
Chapter 9 - Transformers
Chapter 11 - Power FactorPower Factor

Circuits I & Circuits II Lab Exercises



Other Resources

Analog Device Supplied Content

Supplemental Reading

Definitions

Blogs and FAQs

Wikipedia

While Analog Devices is not responsible for, nor can it guarantee the accuracy of the content on Wikipedia, there might be value to the readers by providing links to topics related to the subjects covered in the above chapters as an Introduction to Electronics.

To that end, the following list is provided:

  1. Root Mean Square, Average electrical power
  2. Test Probe, Oscilloscope probes
  3. Ringing
  4. Pulse-width modulation
  5. Sample and hold
  6. Passive
    1. linear elements
    2. Resistor
    3. Capacitor
    4. Capacitor (component)
  7. Passive
    1. nonlinear elements
    2. Diode
    3. Light-emitting diode (LED)
  8. Active elements
    1. Transistor
      1. Bipolar Junction Transistor- (BJT)
      2. Field-Effect Transistor (FET)
        1. MOSFET - Body Effect
        2. JFET
        3. MESFET
      3. Thermal runaway
    2. Darlington transistor (high current transistor configuration)
    3. Sziklai pair (high current transistor configuration, similar to Darlington pair)
    4. Operational amplifier
    5. Operational amplifier applications – Common Op Amp configurations.
    6. Comparator
    7. Vacuum tube (“valves”)
    8. Current source
  9. Voltage regulator
    1. Linear regulator
      1. Zener diode
      2. Low dropout (LDO) regulator
      3. Bandgap voltage reference
      4. Brokaw bandgap reference – Another bandgap voltage reference topology.
    2. Switched-mode power supply (SMPS or “switching regulator”)
  10. Oscillator-related
    1. 555 timer IC
    2. Relaxation oscillator
    3. Schmitt trigger
    4. Multivibrator
    5. Latch (electronics)(like an SR latch)
    6. Flip–flop
  11. Electronic amplifier
    1. Amplifier classes-
      1. Class A
      2. Class B and AB
      3. Class C
      4. Class D
      5. Amplifier circuit Schematic shows a differential amplifier with output tied to a common emitter amplifier that drives a class AB push–pull amplifier. In an example amplifier, we drive a similar push–pull output stage with a common collector (i.e., emitter follower) stage, and so our current amplifier will have no voltage gain.
    2. Crossover distortion
    3. Switching amplifier
    4. Overdrive (music)
      1. Linear range
      2. Distortion
        1. Harmonics
        2. Total harmonic distortion (THD)
        3. Intermodulation
      3. Clipping
    5. Preamplifier
    6. Tube amplifier
  12. Passivity (engineering) – Passive filter
    1. RLC circuit
  13. Active (linear) filtering
    1. Damping
    2. Damping ratio
    3. Q factor
    4. Butterworth filter
    5. Sallen–Key filter topology
    6. Linear phase

End of Document

university/courses/circuits.1609336946.txt.gz · Last modified: 30 Dec 2020 15:02 by Robin Getz

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