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EE 40: Introduction to Microelectronic Circuits

Electrical Engineering 40: Introduction to Microelectronic Circuits (Fall 2010, UC Berkeley). Instructor: Professor Bernhard E. Boser. Fundamental circuit concepts and analysis techniques. Basic circuit characteristics, Ohm's Law, KCL, KVL. Resistive circuits, capacitors and inductors. Node voltage analysis, linearity, superposition, Thevenin & Norton equivalent circuits. Operational amplifiers. Transient and AC analysis, Bode plots and transfer function. Digital circuits; transistors, memory & sequential circuits.

Lecture 20 - RC Circuits: Timers and Clocks, PWM DAC and PWM Filter


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Lecture 01 - Electronic Circuit Design
Lecture 02 - Lumped Circuits, Schematic Diagrams, Circuit Diagrams: Voltage & Current
Lecture 03 - Circuit Diagrams: Measuring Voltage & Current, KVL, KCL, Power
Lecture 04 - Power and Energy, Batteries, Circuit Elements
Lecture 05 - Circuit Components
Lecture 06 - Resistive Circuits: Series, Parallel, Dividers
Lecture 07 - Resistive Circuits Applications: DVM, Sensors
Lecture 08 - Source Transforms
Lecture 09 - Thevenin & Norton Equivalents, Power Transfer, Circuit Analysis
Lecture 10 - Node Voltage Analysis, Linearity, Superposition
Lecture 11 - Circuit Simulation, Operational Amplifiers
Lecture 12 - Operational Amplifiers: Feedback Theory
Lecture 13 - Operational Amplifiers: Feedback
Lecture 14 - Op Amps: Input Resistance, Applications
Lecture 15 - Op Amps: Output Resistance, R-2R Ladder, Instrumentation Amplifier
Lecture 16 - Resistive Circuits & Op Amps
Lecture 17 - Capacitors
Lecture 18 - Switched Capacitor Circuits
Lecture 19 - Resistor Capacitor Circuits: RC Response, Applications
Lecture 20 - RC Circuits: Timers and Clocks, PWM DAC and PWM Filter
Lecture 21 - Inductors: C vs. L, Time Varying Load
Lecture 22 - Inductor Current, Voltage Booster, Buck Converter
Lecture 23 - Inductor Applications, Microcontrollers
Lecture 24
Lecture 25 - Digital Circuits: Transistor Model
Lecture 26 - Maximum Speed of Digital Circuits: Delay Calculation, Fan-Out, Power Dissipation
Lecture 27 - Minimizing Power, Energy Per Computation
Lecture 28 - Memory & Sequential Circuits
Lecture 29 - Review
Lecture 30
Lecture 31 - Frequency Domain & Circuit Analysis: Phasors, Impedance
Lecture 32 - RLC Components Impedances, Admittances, Transfer Functions
Lecture 33 - Transfer Functions and Frequency Response, deciBel, Bode Plots
Lecture 34 - Frequency Response of a Transfer Function H(s)
Lecture 35 - Bode Plot of a Transfer Function H(s)
Lecture 36 - Frequency Response of Op Amps
Lecture 37 - Frequency Selective Filters
Lecture 38 - Conclusion