59:55

Feedback Circuit Analysis and Design (Overview)

29:29

New Structures and Architectures for Communication Systems

58:48

Time and Transfer Constants in Circuits (High Frequency Circuit Analysis)

28:53

The Flexible Future of RF (Keynote at RFIC 2020) by Prof. Ali Hajimiri

01:48

Ferrofluid and Magnet Fun

01:14:10

040. Transformers: Behavior and Circuit Models

09:15

037. Sub-sampling

01:19:14

188N. Intro. to RF power amplifiers

30:58

187N. Intro. to phase-locked loops (PLL) noise

14:55

186N. Oscillator design, noise shifting oscillator example

01:32:39

185N. Phase noise in oscillators (introduction)

47:58

184N. Oscillator general topology, large signal Gm, amplitude and frequency calculation

48:42

183N. Basic analog-to-digital converter architectures

52:24

182N. Basic digital-to-analog converter architectures

34:11

181N. Intro to data converters metrics, basic DAC

16:31

180N. Latch dynamics, latched comparator

01:13:22

179N. Intro to comparators and offset cancellation

14:52

189N. Brief course summary

01:18:43

178N. Noise behavior of basic stages, input-referred noise vs. frequency, Friis formula

34:09

177N. Input-referred noise, 2-port noise model, common-emitter

16:28

176N. Intro. to amplifier noise, output noise, and input-referred noise

29:08

175N. Noise models for pn-junction diode, bipolar transistor, and MOS transistor

39:45

174N. Shot noise, burst noise, flicker(1/f) noise, avalanche noise

01:02:03

173N. Thermal white noise physics, properties, and spectrum, KT/C noise, total available noise power

47:50

172N. Overview of random variable, PSD, auto- and cross-correlation

01:01:11

171N. Circuit compensation techniques, one- and two-stage op-amp, Miller compensation

53:09

170N. Feedback amplifier compensation, general view for 1st, 2nd, and 3rd order system

14:52

169N. Phase margin and gain margin

28:07

168N. Nonlinear stability criteria: Circle criterion, off-axis circle criterion

56:31

167N. Stability criteria: Routh-Hurwitz, Nyquist derivation

33:29

166N. Instability and conditional stability, circuit examples.

29:20

165N. Bilateral loop gain, derivation, feedback

36:13

164N. Unilateral Loop gain, voltage and current loop gains

01:09:36

163N. Port Impedance under Feedback, Blackman Formula

45:17

162N. Active feedback, dual feedback loop, Source dependence of return ratio examples.

01:22:04

161N. Return Ratio, Asymptotic Gain Formula, Direct forward transfer

24:59

160N. Effect of Feedback on Nonlinearity

49:07

159N. Feedback dynamics, forward and feedback path frequency effect, feedback sensitivity reduction

01:00:54

158N. Feedback: Asymptotic Transfer Function, 1st Order Analysis, Rapid design

26:54

157N. Broadband amplifiers, gain-bandwidth product, optimum gain per stage

37:43

156N. Discrete vs. Integrated Variations, Low Cut-Off Estimation with IVT example

22:45

155N. Low Cut-off Frequency Estimation, Infinite value time-constants (IVT)

21:50

154N. Uncoupled time-constants, independent poles and zeros, observable dynamics

54:46

153N. High Frequency behavior of basic amplifier stages (CS, CE, CD, CC, CG, CB) using TTC

42:07

152N.TTC Examples, negative resistance, oscillator, RLC circuit

58:11

151N. TTC Examples, 2nd Order System, Quality Factor and Natural Frequency

09:51

148N. Creation of zeros: series RC branch in parallel

25:07

150N. Generalized Time- and Transfer constants; higher order terms

26:27

149N. Creation of zeros: parallel signal paths

17:10

147N.Taking zeros into account in ZVT bandwidth estimate

01:01:01

146N. When ZVT bandwidth estimation fails

01:09:46

145N. Bandwidth estimation using ZVT, High-frequency Amplifier design example

45:43

144N. Zero-value time and transfer constants (ZVT), b1 and a1 term calculation

31:44

143N. Miller multiplication and effect, input impedance of common-source

20:25

142N. Zero/pole in 1st order system, step response, undershoot and overshoot

54:22

141N. 1st Order high-frequency TTC analysis of common source and common drain

43:28

140N. Time- and transfer-constants in 1st order system

01:04:15

139N. High frequency: transfer functions, lower pass and high pass response.

52:16

138N. BJT Op-Amp Design Example

01:13:16

137N. MOS Op-Amp Design Examples