Lecture 1 - An Introduction to the course and outline of the course
Lecture 2 - Historical overview of the development of microwave devices
Lecture 3 - Applications of semiconductor microwave devices
Lecture 4 - Applications of semiconductor microwave devices (Continued...)
Lecture 5 - Heterojunction device physics
Lecture 6 - Heterojunction device physics (Continued...) and III-nitrides
Lecture 7 - III-nitrides and polarization
Lecture 8 - III-nitride high electron mobility transistors
Lecture 9 - Varactors and Schottky multipliers
Lecture 10 - Varactors and Schottky multipliers (Continued...)
Lecture 11 - Diodes for microwave applications
Lecture 12 - IMPATT diode
Lecture 13 - Tunnel diodes and Introduction to Gunn diodes
Lecture 14 - Gunn diode and its modes
Lecture 15 - Introduction to MESFETs
Lecture 16 - Advanced concepts of GaAs MESFETs
Lecture 17 - GaAs MESFET fabrication and practical aspects
Lecture 18 - Practical aspects of FET design and small-signal model
Lecture 19 - GaAs MESFETs: cut-off frequency and aspects of power devices
Lecture 20 - GaAs MESFETs for power amplifiers
Lecture 21 - Modulation doping in compound semiconductors
Lecture 22 - Band diagram of MODFETs/HEMTs
Lecture 23 - Design issues and methodology for microwave HEMTs
Lecture 24 - Small-signal model and noise in HEMTs
Lecture 25 - The concept of pseudomorphic or pHEMTs
Lecture 26 - Multi-finger HEMTs
Lecture 27 - pHEMTs for low noise and introduction to InP HEMT
Lecture 28 - InP HEMTs for power and the concept of metamorphic HEMTs
Lecture 29 - AlGaN/GaN HEMT: applications, structure, substrates and FOM
Lecture 30 - AlGaN/GaN HEMT: device basics, current collapse and passivation
Lecture 31 - AlGaN/GaN HEMT: gate process, field-plate and trade-offs in design
Lecture 32 - AlGaN/GaN HEMT: Practical aspects and commercial HEMTs
Lecture 33 - GaN RF HEMT on eval board, and emerging topics of research
Lecture 34 - Linearity in GaN HEMTs - A device perspective
Lecture 35 - Nanoscale MOSFETs and short channel effects
Lecture 36 - Parasitic resistances and capacitances in nanoscale MOSFETs
Lecture 37 - RF MOSFET Layout and RF Silicon-on-insulator
Lecture 38 - Noise in MOSFETs and Introduction to LDMOS
Lecture 39 - Working of LDMOS and VDMOS
Lecture 40 - LDMOS: Parasitics, and the concept of RESURF
Lecture 41 - LDMOS: HCI, snapback, finger layout and some aspects of commercial devices
Lecture 42 - BJT: common base and common emitter from the device point of view
Lecture 43 - BJT: Kirk effect, Ebers-Moll model and base transit time
Lecture 44 - BJT: small-signal model, gain and cut-off frequency
Lecture 45 - BJT: Emitter and base designs and drift transistor
Lecture 46 - Collector design in modern BJT and Introduction to HBTs
Lecture 47 - HBT: base current and collapse of the current gain
Lecture 48 - High-frequency HBT and Introduction to SiGe HBT
Lecture 49 - SiGe HBT: various resistances and capacitances, scaling and aspects of BiCMOS
Lecture 50 - Basics of microwave: transmission line theory
Lecture 51 - Waveguides, T-lines and introduction to 2-port networks
Lecture 52 - S-parameters and the basics of Smith Chart
Lecture 53 - Smith chart and matching
Lecture 54 - Impedance matching using Smith Chart and stub line
Lecture 55 - Passives in microwave circuits
Lecture 56 - Inductors in microwave circuits
Lecture 57 - More on passive elements in microwave circuits
Lecture 58 - On-wafer measurement and S-parameters
Lecture 59 - On-wafer de-embedding
Lecture 60 - On-wafer and fixture-based measurements and calibration
Lecture 61 - More on fixtures and basic transistor concepts for power amplifiers
