Equivalent circuits using a trans-conductance parameter for the low and high-frequency operation of BJTs and FETs
Ebers-Moll model view; design and analysis of single/multistage amplifiers, wideband /narrowband amplifiers
Differential amplifiers
Current mirror-different configurations
Feedback amplifiers
Oscillators and waveform generators
Power amplifiers- class AB/class B push-pull/class C
Op-amp design: different stages of op-amp-a case study
Active filter design
Switched capacitor circuits
ADC, DAC
Switching algebra
Minimizing functions using maps
Different logic families, TTL, ECL, NMOS, CMOS, pass transistor logic
Combinational logic circuits:- adders/subtractor, demultiplexers, encoders, decoders , ROMs, PLAs
Sequential logic circuits:- flip flops and latches, shifters, counters, finite state machine, state transition diagrams, and state transition tables
Memory elements: -ROM, PROM, RAM-SRAM, DRAM.
Case studies: a simple computer, RTL micro-instruction, instruction decoders timing and controller circuits, data path unit.
Experiment 1: Inverting Op amp
Experiment 2: Summing Amplifier
Experiment 3: Difference Amplifier
Experiment 4: Differential Amplifier
Experiment 5: Integrating Amplifier
Experiment 6: Basic Logic Gates Operations (NOT, AND, OR)
Experiment 7: Logic Gates Operations (NAND, NOR)
Experiment 8: Implementing Logic Functions Using Logic Gates.
Ohm's Law, Series and Parallel Circuits
Kirchhoff's Voltage and Current Laws
Mesh Analysis and Nodal Analysis
Wye-Delta Conversion
Source Transformation, Superposition Theorem
Thevenin's Theorem and Maximum Power Transfer Theorem
Multi-range Voltmeter and Ammeter
Watt-meter and energy meter
Average and RMS values of alternating current and voltage
Phasor Algebra
RLC Circuits
AC Power Analysis
Balanced Three-phase circuits
Power System (Generation, Transmission, and Distribution)
Power Plants
Experiment 1: Resistor Color Code and Functions of a Bread-Board.
Experiment 2a: Verification of KCL and Current Divider Rule.
Experiment 2b: Verification of KVL and Voltage Divider Rule.
Experiment 3: Verification of Mesh and Nodal Analysis.
Experiment 4: Verification of superposition theorem.
Experiment 5: Verification of Thevenin’s Theorem.
Experiment 6: Verification of Maximum Power Transfer Theorem.
Experiment 7: Familiarization with alternating current (AC) waves and Oscilloscopes.
Experiment 8: Study of Diode Characteristics.
Experiment 9: Half Wave Rectifier.
Experiment 10: Full Wave Rectifier.
Experiment 11: Simulation of Electrical Circuits in Proteus.
Ohm's Law, Series and Parallel Circuits
Kirchhoff's Voltage and Current Laws
Mesh Analysis and Nodal Analysis
Wye-Delta Conversion
Source Transformation, Superposition Theorem
Thevenin's Theorem and Maximum Power Transfer Theorem
Average and RMS values of alternating current and voltage
Phasor Algebra
RLC Circuits
p-n junctions
Transistors
Half Wave Rectifiers
Full Wave Rectifiers
Transformers, Motors, Generators
Base Conversion ( Decimal, Binary, Octal, Hexadecimal)
Logic Function and Truth Table
Logic Function Optimization and Synthesis of Logic Network
Making Logic Gates using CMOS
8086 Microprocessor Internal and External Architecture
Assembly Language
Interrupt Structure
Robotics
Control System
Microsoft Word
Microsoft Excel
Google Docs, Google Sheets
Google Forms
Introduction to a compiler (CODE BLOCKS)
Getting familiarized with Data type and Variable
Getting familiarized with Input, Output Functions
Conditional Statements
'For' Loops
Nested 'For' Loops
'While' Loops
Experiment 1: Resistor Color Code and Functions of a Bread-Board.
Experiment 2a: Verification of KCL and Current Divider Rule.
Experiment 2b: Verification of KVL and Voltage Divider Rule.
Experiment 3: Verification of superposition theorem.
Experiment 4: Verification of Thevenin’s Theorem.
Experiment 5: Verification of Maximum Power Transfer Theorem.
Experiment 6: Familiarization with alternating current (AC) waves and Oscilloscopes.
Experiment 7: Study of Diode Characteristics.
Experiment 8: Half Wave Rectifier.
Experiment 9: Full Wave Rectifier.