27-12-2014, 11:19 PM
Analog Electronics Full Hand Written Lecture Notes from Reputed Institutions and Faculties. Useful for Electrical Engineers , Specially for Candidates Appearing for GATE Exams.
Content :
Introduction to electronics
Mobility
Mobility of electron
Temperature with standing capacity
Crystal lattice
Semiconductor
Trivalent impurity
Doping
Drift current
Current density
Diffusion current
Diode application
Clippers
Technique in clamper
Voltage multiplier
Problems
Alternator
Single branch design
Diode resistance
Mathematical analysis
Junction capacitance
BJT
Content :
Introduction to electronics
Mobility
Mobility of electron
Temperature with standing capacity
- 1. Leakage current
- 2. Temperature with standing capacity
- 3. Peak inverse voltage
Crystal lattice
Semiconductor
- 1. Intrinsic semiconductor (pure)
- 2. Extrinsic semiconductor (impure)
Trivalent impurity
Doping
- 1. Ordinary p-n diodes
- 2. Zener diode
- 3. Tunnel diode
Drift current
Current density
Diffusion current
Diode application
- 1. Linear resistor
- 2. Ideal diode
- 3. Practical diode
- 4. Piece-wise linear model
Clippers
- 1. Shint clipper
- 2. Series clipper
- 3. Output following input design
- 4. Two independent level clipping
- 5. Alternators
- 6. Single branch design
- 7. Multi branch design
Technique in clamper
Voltage multiplier
Problems
Alternator
Single branch design
Diode resistance
- 1. Static resistance
- 2. Dynamic resistance
Mathematical analysis
Junction capacitance
- 1. Transition capacitance
- 2. Diffusion capacitance
- 1. Half wave rectifier
- 2. Full wave rectifier with centre tap
- 3. Bridge rectifier
BJT
- Principle of BJT
- 1. Emitter injection efficiency
- 2. Base transport factor
- 3. Large signal current gain
- BJT configuration
- Common base
- Common emitter
- Common collector
- CE amplifier
- AC analysis
- AC load line
- Stability factor
- Biasing circuits
- 1. Stabilization technique
- a. Fixed bias
- b. Collector to base
- c. Voltage divider bias
- 2. Compensation
- a. Diode
- b. Thermistor
- c. sensistor
- Compensation through sensistor
- Position of Q point on DC load line
- Conclusion
- Thermal runaway
- Thermal parameters
- Power transistor
- BJT application
- CE amplifier
- RC coupled BJT amplifier
- Direct coupled BJT amplifier
- Analysis of CE amplifier
- Properties of CE amplifier
- Miller theorem
- CC amplifier
- Early effect
- Output resistance
- Breakdown mechanism in BJT
- 1. thermal runaway
- 2. punch through
- 3. avalanche breakdown
- Small signal analysis of BJT
- Types of basic amplifier
- 1. voltage amplifier
- 2. current amplifier
- 3. transconductance amplifier
- 4. transresistance amplifier
- Linear 2 port network
- Y parameters
- H parameters
- G parameters
- Low frequency analysis of BJT
- Typical value of h-parameters
- Amplifier analysis at low frequencies
- BJT characteristics analysis
- 1. current gain
- 2. input impedance
- 3. voltage gain
- 4. output impedence
- Approximation method of CE
- CE amplifier
- High frequency analysis of BJT
- Hybrid PIE parameters
- Capacitance
- 1. internal capacitance
- a. cd-diffusion
- b. ct-transition
- External capacitance
- a. cc-coupling
- b. ce-bypass
- Low frequency range
- High frequency range
- Mid band range
- Practical amplifier design
- 1. CE bypass amplifier
- 2. CE un bypass amplifier
- 3. CC amplifier
- 4. CB amplifier
- Feedback theory
- Topology
- 1. Block diagram analysis
- 2. Practical circuit analysis
- Procedure for feedback
- Integrated theory
- Multistage amplifier
- Effect of cascading on BW
- High cut-off frequency
- 1. Cascade amplifier
- 2. Darlington pair
- Emitter follower
- Coupling design
- 1. RC coupling
- 2. Direct coupling
- Direct coupled amplifier
- Testing of differential amplifier for various output
- Common input
- Large difference input
- Small difference input
- AC analysis
- Dc analysis
- Swamping resistor technique
- Current mirror biasing
- 1. Simple current mirror
- 2. Modified current mirror
- 3. Micro level current mirror
- CMRR (common mode rejection ratio)
- Application of op-amp
- Linear application
- Non-linear application
- 1. Inverting amplifier
- 2. Non-inverting amplifier
- 3. Phase shifter
- 4. Voltage follower
- 5. Differential amplifier
- 6. Subtractor
- 7. Inverter adder
- 8. Non-inverting adder
- 9. Current to voltage converter
- 10. Voltage to current converters
- 11. Voltage limiter
- 12. Logarithmic amplifier
- 13. Antilog amplifier
- 14. Precision rectifier
- 15. Instrumental amplifier
- 16. Modulator
- 17. Demodulator
- 18. Integrator
- 19. Differentiator
- 20. Active filter
- Frequency domain analysis
- Band reject filter
- All pass filter
- Non-linear application
- Communication system
- Problems
- Mono stable multi vibrator
- Introduction
- Types
- 1. N-channel
- 2. P-channel
- Working principle
- FET parameters
- 1. AC drain resistance
- 2. Transconductance
- 3. Amplification
- FET biasing
- FET amplifier
- N-channel enhancement mosfet (NMOS)
- Power amplifier
- Class A amplifier
- Dc condition
- Power dissipation
- Class B power amplifier
- Push pull class B power amplifier
- Cross over distortion