Lecture 1: Overview of 6.012 (
PDF)
Lecture 2: Introduction to Semiconductors: Electrons and Holes, Donors and Acceptors (
PDF)
Lecture 3: Carrier Transport: Drift and Diffusion (
PDF)
Lecture 4: Electrostatics in Semiconductors; the "60 mV rule" (
PDF)
Lecture 5: p-n Junction Electrostatics in Thermal Equilibrium (
PDF)
Lecture 6: p-n Junction Electrostatics under Bias, Depletion Capacitance (
PDF)
Lecture 7: MOS Electrostatics in Thermal Equilibrium (
PDF)
Lecture 8: MOS Electrostatics under Bias, MOS Capacitance (
PDF)
Lecture 9: MOSFET: I-V Characteristics (
PDF)
Lecture 10: MOSFET: Backgate Effect (
PDF)
Lecture 11: MOSFET Equivalent Circuit Models (
PDF)
Lecture 12: Logic Concepts; Inverter Characteristics; NMOS Inverter (
PDF)
Lecture 13: CMOS Inverter: Transfer Characteristics (See announcements above) (
PDF)
Lecture 14: CMOS Inverter: Delay; CMOS Scaling, VLSI (
PDF)
Lecture 15: p-n Junction Diode I-V Characteristics (
PDF)
Lecture 16: p-n Junction Equivalent Circuit Models, Charge Storage, Diffusion Capacitance (
PDF)
Lecture 17: BJT Electrostatics, Forward Active Regime (
PDF)
Lecture 18: Other Regimes of Operation of BJT; Equivalent Circuit Models (
PDF)
Lecture 19: Single-Stage Amplifiers; Common-Source Amplifier Stage (
PDF)
Lecture 20: Other MOSFET Amplifier Stages (
PDF)
Lecture 21: Multistage Amplifiers (
PDF)
Lecture 22: Current Sources and Sinks (
PDF)
Lecture 23: Frequency Response of Common-Source Amplifier; Miller Effect (
PDF 1.5 MB)
Lecture 24: Frequency Response of Other Amplifier Stages; notes on OCTC (
PDF)
Lecture 25: Differential Amplifier: DC Analysis, Incremental Analysis (
PDF)
Lecture 26: Differential Amplifier: Large-Signal, ECL; 6.012 Wrap-up: Key Conclusions (
PDF)