Download EL6413 Catalog Description

EL6413 Analog and High Frequency Amplifier Design, Credits:
3.00
Catalog Description
Basic semiconductor physics, small-signal low frequency models for bipolar junction
transistors, biasing, and temperature compensation techniques. Physics, models, and
biasing for field-effect transistors. General treatment of nonlinear controlled
sources. High frequency models. Single and multistage broadband small signal
amplifiers. Harmonic distortion analysis of amplifiers. Emitter follower analysis at
high frequencies. Operational amplifiers, discrete, and analog integrated circuits.
Nonlinear Op-Amp applications. Circuit design techniques to increase Op-Amp slew
rate.
EL6413 Course Syllabus
1)
Bipolar Junction Transistors (BJT)
a) BJT Common Emitter and Common Base Terminal Characteristics
2)
b)
DC Circuit Models
c)
Small signal common emitter and common base AC models
d)
Biasing techniques including temperature compensation
BJT Linear Amplifiers
a)
b)
3)
4)
Common Emitter Amplifiers (gain, input impedance, output
impedance, and maximum output swing
Constant Current Biased Amplifier (Harmonic Distortion Analysis)
Differential Pair Amplifier
a)
Transfer Characteristic
b)
DC Analysis
c)
Small signal AC model
d)
Gain, input impedance, output impedance, harmonic distortion
Differential Pair Amplifier (continued)
a)
Practical Realizations of constant current biasing
b)
Differential and Common Mode signals and gains
c)
5)
Common Mode Rejection Ratio
Op-Amps
a)
Basic features
b)
Amplifier Stages
c)
Dc Voltage Level Shifters
d)
Current Mirrors
e)
Push-Pull to Single Ended Converters
6) Op-Amp Output Stages
a) Emitter Follower
b) Complementary Symmetry Class B
c) Class AB
d) Output Short Circuit Protection
e) 741 Op-Amp (dc and ac analysis)
7) Op-Amps (continued)
a)Slew Rate ( definition and example, cause for slew rate distortion, design
techniques to improve slew rate distortion)
b)Op-Amp Applications (Inverting Amplifier, Non-inverting Amplifier,
Voltage Follower, Summer, Integrator, Differentiator, Low Pass Filter,
Active Resonant Bandpass Filter, Nonlinear applications [Log-Amp, Half
Wave Rectifier, Full Wave Rectifier, Limiter, Peak Detector])
8) Field Effect Transistors
a)JFET and MOSFET (symbols, volt-ampere characteristics, dc biasing,
small signal models)
b)Common Source Amplifier (gain, input impedance, output impedance,
distortion)
c) Common Drain [Source Follower] (gain, input impedance, output
impedance)
d) Differential Pair
e) Op-Amp with FET Input
9) High Frequency Response of Amplifiers
a)BJT Hybrid Pi Model
b)Common Emitter Amplifier at High Frequency (Miller’s Theorem)
c) Common Base Amplifier at High Frequency
d) FET High Frequency Models
e) Common Source Amplifier at High Frequency
10) High Frequency Response of Amplifiers (continued)
a) Emitter Follower at high frequency (stability issues)
b) Frequency response of multi-stage amplifiers
11) Frequency Response of Op-Amp with Feedback
a)Inverting Amplifier
b)Non-inverting Amplifier
c) Gain Bandwidth Product Rule
12) Frequency Compensation of OP-Amps
a) Uncompensated Op-Amp
b) Lag (Dominant Pole) Compensation
c) Lag-Lead Compensation
d) Lead Compensation
Text: Gray, Hurst, Lewis, Meyer, ANALYSIS AND DESIGN OF ANALOG INTEGRATED
CIRCUITS, 5th Edition, John Wiley and Sons, Inc., 2009,
ISBN 978-0-470-24599-6
GRADING POLICY
Homeworks 20%
Midterm
35%
Final Exam 45%