Course Brochure
Analog IC design also has specializations in power IC design and RF IC design. Analog IC design is used in the design of op-amps, linear regulators, phase locked loops, oscillators and active filters. Analog design is more concerned with the physics of the semiconductor devices such as gain, matching, power dissipation, and resistance. Fidelity of ...
Validity Unlimited 
All Level 
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Analog IC design also has specializations in power IC design and RF IC design. Analog IC design is used in the design of op-amps, linear regulators, phase locked loops, oscillators and active filters. Analog design is more concerned with the physics of the semiconductor devices such as gain, matching, power dissipation, and resistance. Fidelity of ...
Course introduction; Negative feedback control
50m
Negative feedback amplifier
50m
Step response, sinusoidal steady state response
51m
Loop gain and unity loop gain frequency; Opamp
49m
Opamp realization using controlled sources; Delay in the loop
51m
Negative feedback amplifier with ideal delay-small delays
49m
Negative feedback amplifier with ideal delay-large delays
52m
Negative feedback amplifier with parasitic poles and zeros
52m
Negative feedback amplifier with parasitic poles and zeros; Nyquist criterion
48m
Nyquist criterion; Phase margin
51m
Phase margin
51m
Single stage opamp realization
51m
Two stage miller compensated opamp
49m
Two stage miller compensated opamp
49m
Two and three stage miller compensated opamps; Feedforward compensated opamp
48m
Feedforward compensated opamp
49m
Feedforward compensated opamp
47m
Feedforward compensated opamp; typical opamp data sheet
49m
Opamp offset and CMRR; Transimpedance amplifier using an opamp
1h 63 min
Components available in a CMOS process
1h 63 min
MOS transistors-basics
49m
MOS transistors-parasitics, mismatch
48m
MOS transistors-mismatch, speed
54m
Noise in resistors
53m
Noise in MOS transistors; Input and output referred noise
51m
Noise scaling; Basic amplifier stages-Common source, common gate
52m
Basic amplifier stages-Common drain; Frequency response of amplifiers
52m
Common source amplifier frequency response; Differential amplifier
50m
Differential and common mode half circuits; Differential pair with active load
52m
Differential pair with current mirror load
51m
Single stage opamp characteristics
48m
Opamp with single and dual supplies; Single stage opamp tradeoffs
46m
Telescopic cascode opamp
51m
Telescopic cascode opamp; Folded cascode opamp
52m
Folded cascode opamp
50m
Two stage opamp
50m
Two stage opamp; Three stage and triple cascode opamps
51m
Common mode rejection ratio; Example
51m
Fully differential circuits
52m
Fully differential single stage opamp
48m
Common mode feedback
52m
Fully differential single stage opamp
50m
Fully differential two stage opamp; Fully differential versus pseudo-differential
51m
Circuit simulators and analyses
52m
Phase locked loop as frequency multiplier
51m
Phase domain model
49m
Type I PLL transfer function and reference feedthrough
47m
Type II PLL
51m
Type II PLL transfer functions; Implementation
46m
Type II PLL-extra poles; Random noise in a PLL
52m
Oscillator phase noise
50m
PLL phase noise; LC and ring Oscillators
1h 64 min
Generating PTAT and constant MOS gm bias currents
51m
Reducing supply sensitivity; Bandgap voltage reference
51m
Fractional bandgap reference; Low dropout regulators
50m
Low dropout regulators; Continuous-time active filters
52m
Continuous-time active filters
52m
Continuous-time active filters
47m
Discrete-time active filters
52m
Transistor sizing in practice; Course summary
52m
1 Enrollments
Validity Unlimited 
1 Enrollments
Validity Unlimited 
