Official Course
Description: MCCCD Approval: 06/24/08 |
|
AVT128
2009 Spring 2012 Fall |
L+L
5.0 Credit(s) 7.0 Period(s) |
Advanced
Electrical and Electronics |
|
Advanced
electronics theory and application of diodes, bipolar transistors, field
effect transistors, AC (Alternating current) power control devices,
transistor amplifiers, sine wave oscillators, square wave generators, bistable circuits, operation amplifiers, and power supply
and voltage regulators. Prerequisites: AMT126, or permission of
the Department or Division. |
|
Go to Competencies Go to Outline
MCCCD
Official Course Competencies: |
|
|
|
AVT128 2009
Spring 2012 Fall |
Advanced Electrical and Electronics |
1.
|
Explain the theory of operation of semiconductors and
construct circuits. (I) |
2.
|
Explain the theory of operation of diodes and construct
circuits. (II) |
3.
|
Explain the theory of operation of special purpose diodes
and construct circuits. (III) |
4.
|
Explain the theory of operation of transistors and
construct circuits. (IV) |
5.
|
Explain the theory of operation of alternating current
power control devices and construct circuits. (V) |
6.
|
Explain the theory of operation of field effect
transistors and construct circuits. (VI) |
7.
|
Explain the theory of operation of transistor amplifiers
and construct circuits. (VII) |
8.
|
Explain the theory of operation of sine wave oscillators
and construct circuits. (VIII) |
9.
|
Explain the theory of operation of square wave generates
and construct circuits. (IX) |
10.
|
Explain the theory of operation of operation amplifiers
and construct circuits. (X) |
11.
|
Explain the application for the operation amplifier and
construct circuits. (XI) |
12.
|
Explain the theory of operation of power supplies and
construct circuits. (XII) |
Go to Description Go to top of
Competencies
MCCCD
Official Course Outline: |
|
|
|
AVT128 2009
Spring 2012 Fall |
Advanced Electrical and Electronics |
I. Semiconductors A. Theory of operation B. Atoms, crystals, and
energy state C. Conductivity D. Insulators E. Semiconductors F. Construct circuits II. Diodes A. Theory of operation B. Construction 1. Ideal diodes 2. Vacuum tube diodes 3. Semiconductors 4. Diode applications 5. Filtering rectifier
output 6. Diode clippers 7. Diode peak detectors
circuits 8. DC and AC voltage
invertors 9. Diode switches 10. Diode detectors C. Construct circuits III. Special Purpose Diodes
A. Theory of operation B. Types or diodes 1. Stabistor
2. Silicon solar cells 3. Light emitting 4. High voltage 5. ZENOR 6. Varactor
and stepm recovery 7. Pin 8 Schottky 9. Tunnel 10. Gunn C. Tunnel diode oscillators
D. Tunnel diode amplifiers E. Tunnel rectifiers F. Applications G. Construct circuits IV. Transistors A. Theory of operation B. Ideal control devices C. Basic transistor
amplifiers D. Ideal transistor
amplifiers E. Vacuum tubes F. Transistor input
characteristics G. Limitation in transistor
performance H. Transistor fabrication I. Testing transistors J. Construct circuits V. AC power control devices
A. Theory of operation B. Methods of controlling
alternating currents 1. Thyratons
2. Thyristors
3. Positive negative
positive diodes 4. Inert gas and voltage
regulators 5. Silicon rectifiers 6. Full-wave AC power 7. Dicas
and triacs C. Construct circuits VI. Field Effect
Transistors (FET) and Metal Oxide Semiconductors (MOS), (MOSFET) A. Theory of operation B. Junction FET C. FET regulator diodes D. MOSFET symbols E. MOSFET types and
construction 1. Negative MOS and
positive MOS 2. Complimentary MOSFETs
(CMOS) 3. Dual-gate MOSFETs 4. Vertical MOS (VMOS)power
transistors F. MOS transistor and
integrated circuits protection G. Storing loose MOSFETs in
circuits H. Installing MOSFETs in
circuits I. Built-in MOSFET
protection J. Construct circuits VII. Transistor amplifiers A. Theory of operation B. Impedance matching C. Basic transistor
amplifiers D. Emitter follower (common
collector amplifier) E. Common base amplifier F. Direct coupled
transistor amplifier G. Basic field effect
transistor H Alphabetic classification of amplifier I. Linearity and distortion
J. Amplifier classes 1. Class a 2. Class b 3. Class c 4. Class ab 5. Class d 6. Class e K. Biasing transistor
amplifier L Biasing class a amplifier M Static and
dynamic amplifier characteristics N. Construct circuits VIII. Sine Wave Oscillators
A. Theory of operation B. Types 1. Phase shift oscillators 2. Resonant circuits
oscillators 3. Colpitts
and Hartly oscillators 4. Crystal oscillators 5. Armstrong oscillators 6. Regenerative oscillators
C. Construct circuits IX. Square Wave Generators A. Theory of operation B. Types 1. Multivibrator
2. Bistable
flip flap 3. Bistable
flip-flops as memory 4. Stable multivibrators 5. Synchronized multivibrators 6. Monostable
multivibrator 7. Schmitt trigger, zero
crossing detectors, and comparators 8. Unijunction
transistor oscillators C Integrated timing D. Construct circuits X. Operation Amplifier A. Theory of operation B. Types 1. Op-amp amplifier 2. Differential amplifier 3. Inverting and
non-inverting inputs 4. Operational amplifier
design 5. Compactors 6. Voltage follower 7. Precision diodes 8. Operational amplifier
with controlled voltage gain 9. Balancing operational
amplifier 10. Thermocouple amplifiers
11. Single-power supply
amplifiers 12. Op-amp output impedance
C. Construct circuits XI. Application for
Operation Amplifier A. Theory of operation B. Types of circuits 1. Operational amplifier as
differential amplifiers 2. Summing amplifier 3
Active frequency filter 4. Logarithmic amplifier 5. Integrators and
differentiators 6. Integrator sweep
circuits 7. Operational
differentiators 8. Voltage to current
converter C. Construct circuits XII. Power Supplies A. Theory of operation B. Types of circuits 1. Power supply design
goals 2. Parallel voltage
regulators 3. Series voltage
regulators 4. Current limiter circuits
5. Terminal integrated
voltage regulators 6. Energy gap voltage
standards 7. Varistors
8. Switching power supplies
9. Isolated power supply
and photo isolators 10. Constant AC voltage C. Construct circuits |