Digital Electronics: A Step-By-Step Guide To Mastery

Learn Digital Electronics from Fundamentals to Advanced concept with 15+ years of experienced Faculty

What you'll learn

Number System

Boolean Algebra

Logic Gates

Combinational Circuits

Karnaugh Map

Logic Families

Sequential Circuits

Semiconductor Memory

Analog to Digital Converter

Digital to Analog Converter

Can be able to solve most of Digital Electronics Problems

Requirements

There is not specific requirements. You will get all the basics step by step.

Description

This Digital Electronics course is specially designed for students who want to enter the field of Embedded systems, VLSI, and other branches of Computer Science. It is also helpful for working professionals. This is a unique course in the online marketplace.This course applies to many branches of Degree/Diploma Engineering such as Electrical, EC, Computer, IT, and Instrumentation. After completing this course students will be able to understand from basic to advance level concepts of Digital Electronics which will be a stepping stone for starting many lucrative career fields.This course is also helpful in many competitive examinations and not only that it will also be helpful in interviews.This course covers the following topics.- Number Representations: binary, hex, octal, decimal, BCD, integer, and floating-point- numbers and many more.- Boolean Algebra: Laws of B.A, SOP, POS, Minterms, Maxterms, Quine McCluskey Technique- Combinatorial circuits: Minimization of functions using Boolean identities and many other circuits like converters, multiplexers, decoders etc.- Karnaugh Map: Prime Implicants, 3,4,5 and 6 variable K Map- Logic Gates: AND, OR, NOT, XOR, XNOR, NAND and NOR- Logic Families: DTL, RTL, TTL, CMOS, Boolean Function Implementations- Sequential Circuits: Flip Flops, Counters, Shift Registers, State Machines- Memory: ROM, RAM, PLA, PAL, DAC, ADCSo, go through this entire course step by step and I am sure you will get thorough knowledge about the course of Digital Electronics.All the best..

Overview

Section 1: Course Introduction

Lecture 1 Introduction

Section 2: Number System

Lecture 2 Representation of Number Systems and Basics of Number System

Lecture 3 Addition operation in Different Number systems

Lecture 4 Subtraction operation in Different Number Systems

Lecture 5 Octal and Binary Multiplication, Number System Multiplication

Lecture 6 Decimal to Binary Conversion, Decimal to Binary Conversion Process

Lecture 7 Decimal to Octal Conversion, Decimal to Octal Conversion Process

Lecture 8 Decimal to Hexadecimal Conversion, Decimal to Hexadecimal Conversion Process

Lecture 9 Octal, Binary and Hexadecimal to Decimal conversion and Visa Versa

Lecture 10 Hexadecimal to Binary to Octal conversion and Visa versa

Lecture 11 X Number System to Y Number System conversion, Number System Conversion

Lecture 12 1's & 2's Compliment, 7's & 8's Compliment, 9's & 10's Compliment 15's,16's

Lecture 13 Simple Signed Representation, Example and Block Diagram of Simple Signed Rep

Lecture 14 1's compliment signed Representation and 2's compliment signed Repr.

Lecture 15 2's compliment signed Representation

Lecture 16 1's compliment signed Representation

Lecture 17 Shortcut Method to find 2's compliment, 2's Compliment

Lecture 18 Binary Subtraction using 1's compliment

Lecture 19 Binary Subtraction using 2's compliment

Lecture 20 Classification of Codes (Definition, Weighted, Non Weighted

Lecture 21 BCD code, Binary Coded Decimal Code, Binary and BCD Comparison

Lecture 22 BCD Addition, BCD Addition Rules, BCD Addition Examples

Lecture 23 BCD to Binary conversion, BCD to Binary conversion Process

Lecture 24 Binary to BCD conversion, Process of Binary to BCD conversion, Binary to BCD

Lecture 25 2421 BCD code and 2_421 BCD code, Self Complimentary Property of 2421 BCD

Lecture 26 Excess 3 Code, Excess 3 Code Properties, Decimal to Excess 3 Code Conversion

Lecture 27 Excess 3 Addition, Excess 3 Addition Process, Excess 3 Addition Examples

Lecture 28 Identification of Base or Radix of given number, Radix Identification

Lecture 29 ASCII code, American Standard Code for Information Interchange

Lecture 30 Gray Code (Basics & Properties), Gray Code as self reflection code, Gray Cod

Lecture 31 Binary to Gray code conversion, Binary to Gray code conversion process

Lecture 32 Gray to Binary Code conversion, Gray to Binary Code conversion process

Lecture 33 Identification of self complimenting code, Digital Electronics

Lecture 34 Total bits required to represent a number

Lecture 35 Minimal Decimal Equivalent, Minimal Decimal Equivalent Examples

Lecture 36 Hamming Code Basics, Number of Parity bits in Hamming code

Lecture 37 Hamming Code generation, Position of Parity bits

Lecture 38 Hamming Code error detection and Hamming Code error correction

Lecture 39 IEEE 754 floating point single precision 32 bit format

Lecture 40 IEEE 754 floating point double precision 64 bit format

Section 3: Boolean Algebra

Lecture 41 De Morgen's Theorem and Proof of De Morgen's Theorem

Lecture 42 Boolean Algebra Rules (Distributive, Commutative, Associative, De Morgen's)

Lecture 43 Consensus Theorem and Proof of Consensus Theorem

Lecture 44 Boolean Algebra Examples part 1, Boolean Algebra, Boolean Algebra Rules

Lecture 45 Boolean Algebra Examples Part 2, Boolean Algebra, Boolean Algebra Rules

Lecture 46 Boolean Algebra examples part 3, Boolean Algebra, Boolean Algebra Rules

Lecture 47 Dual and Self Dual of Boolean equation, Boolean Algebra

Lecture 48 SOP - Sum Of Product, POS - Product Of Sum and Canonical Form

Lecture 49 Minterms and Maxterms in Boolean function Representation

Lecture 50 SOP to SSOP conversion, Sum Of Product to Standard Sum Of Product Conversion

Lecture 51 POS to SPOS conversion, Product Of Sum to Standard Product Of Sum Conversion

Lecture 52 SSOP to SPOS conversion and SPOS to SSOP conversion

Lecture 53 Examples on SOP and POS, Boolean Algebra in Digital Electronicss

Lecture 54 Quine Mccluskey Minimization Technique for Boolean expression, Karnaugh Map

Section 4: Logic Gates

Lecture 55 Logic GATE's Introduction, Basic Logic GATE's, Universal Logic GATE

Lecture 56 NOT gate, NOT gate Applications, NOT gate as ring oscillator, NOT gate

Lecture 57 AND gate, Properties of AND gate and Examples of AND gate, Logic Gate's

Lecture 58 OR gate, Properties of OR gate and Examples of OR gate, Logic Gate's

Lecture 59 NAND as universal GATE, Logic GATEs in Digital Electronics

Lecture 60 XOR gate and XNOR gate, Properties of XOR and XNOR gate in Logic GATE'S

Lecture 61 Examples on XOR and XNOR gate part 1, Logic GATEs in Digital Electronics

Lecture 62 Examples on XOR and XNOR gate Part 2, Logic GATEs in Digital Electronics

Lecture 63 NOR as universal GATE, Logic GATEs in Digital Electronics

Lecture 64 NAND gate and NOR Gate in Logic Gate's

Lecture 65 Minimum Two input NAND for multiple input AND & Minimum Two input NAND

Lecture 66 Minimum two input NAND gates for Boolean expression

Lecture 67 Minimum two input NAND gates for Boolean equation

Lecture 68 Boolean expression to NAND gate implementation

Lecture 69 AOI to NAND gate implementation, Logic GATEs in Digital Electronics

Lecture 70 Boolean expression to NOR gate implementation

Lecture 71 AOI to NOR implementation, Logic GATEs in Digital Electronics

Lecture 72 Stuck at 1 and Stuck at 0 fault in Logic circuit

Section 5: Combinational Circuits

Lecture 73 Combinational circuit and Sequential circuit Comparison

Lecture 74 Combinational circuit designing examples

Lecture 75 Combinational circuit examples, Combinational circuit

Lecture 76 Half Adder (Working, Truth Table, Designing & Circuit)

Lecture 77 Full Adder (Working, Truth Table, Designing & Circuit)

Lecture 78 Full Adder using Half Adder (Designing and Circuit)

Lecture 79 Half Adder using NAND gates, Half Adder

Lecture 80 4 bits parallel Adder (Working and Circuit)

Lecture 81 BCD Adder by Parallel Adder (Truth Table, Working, Designing and Circuit)

Lecture 82 1's Compliment Subtraction using Parallel Adder

Lecture 83 2's Compliment Subtraction using Parallel Adder

Lecture 84 Half Subtractor (Working, Truth Table and Circuit)

Lecture 85 Half Adder using Half Subtractor

Lecture 86 Half Subtractor using Half Adder

Lecture 87 Full Adder using Half Subtractor, Combinational circuit

Lecture 88 Full Subtractor (Working, Truth Table and Circuit)

Lecture 89 Full Subtractor using Full Adder

Lecture 90 Full Adder using Full Subtractor

Lecture 91 Full Subtractor using Half Subtractor,

Lecture 92 Parallel Subtractor using Full Subtractor and Half Subtractor

Lecture 93 Bits Multiplier using Half Adder

Lecture 94 Excess 3 Addition by Parallel Adder, Combinational circuit

Lecture 95 2 bits Data comparator, Combinational circuit in Digital Electronics

Lecture 96 Seven Segments Display Decoder, Combinational circuit in Digital Electronics

Lecture 97 Carry Look Ahead Adder, CLA Adder, Combinational circuit in Digital Electron

Lecture 98 Even Parity Generator and Odd Parity Generator

Lecture 99 Decoder Basics and 2 to 4 Decoder

Lecture 100 3 to 8 Decoder working, Truth Table and Circuit Diagram

Lecture 101 Combinational Circuit Output Waveforms with Delay at Gates

Lecture 102 Combinational Circuit Output Waveforms with Delay at Gates

Lecture 103 Priority Encoder Basics, Working, Truth Table and Circuit

Lecture 104 Decimal to BCD Encoder Basics, Working, Truth Table

Lecture 105 Implementation of Full Adder using Decoder

Lecture 106 Binary Code to Gray Code Converter

Lecture 107 Multiplexer MUX Basics, Working, Advantages, Applications and Types

Lecture 108 2 to 1 Multiplexer Working, Truth Table and Circuit

Lecture 109 4 to 1 Multiplexer (Working, Truth Table and Circuit), Combinational circuit

Lecture 110 8 to 1 Multiplexer using Full Subtractor

Lecture 111 MUX Tree, Multiplexer Tree

Lecture 112 Designing of 4 to 1 Multiplexer using 2 to 1 Multiplexer

Lecture 113 Designing of 8 to 1 Multiplexer using 2 to 1 Multiplexer

Lecture 114 8 to 1 MUX using 4 to 1 MUX by two different Methods

Lecture 115 SOP Implementation using Multiplexer

Lecture 116 Full Adder Implementation using 4 to 1 Multiplexer

Lecture 117 Full Adder using 2 to 1 Multiplexer,

Lecture 118 Identification of Boolean Expression from Multiplexer Circuit

Lecture 119 Identification of logic Gate's from Multiplexer circuit

Lecture 120 Examples Based on Multiplexer, Combinational circuit in Digital Electronics

Lecture 121 Examples Based on Multiplexer, Combinational circuit ,

Lecture 122 Coincidence Logic and Problems based on Coincidence Logic

Lecture 123 Demultiplexer and 1 to 2 Demultiplexer

Lecture 124 1 to 4 Demultiplexer Working

Lecture 125 1 to 8 Demultiplexer Working

Lecture 126 Implementation of Full Subtractor using 1 to 8 Demultiplexer

Lecture 127 Demultiplexer as Decoder _ Combinational circuit

Lecture 128 Implementation of Boolean Expression using Demultiplexer

Section 6: Karnaugh Map

Lecture 129 Karnaugh Map basics & Key points of Karnaugh Map

Lecture 130 K Map rules for grouping cells, K map rules for formation of Boolean fun.

Lecture 131 Implicants, Prime Implicants and Essential Prime Implicants

Lecture 132 K Map Examples, Karnaugh Map Examples, K Map

Lecture 133 K Map Examples

Lecture 134 K Map with Don't care examples

Lecture 135 K Map with Don't care examples

Lecture 136 K Map for POS expression

Lecture 137 5 variable K Map, 5 variable Karnaugh

Lecture 138 6 variable K Map

Lecture 139 K Map Examples

Lecture 140 Quine McCluskey Minimization Technique

Section 7: Logic Families

Lecture 141 Digital Logic Families, Classifications of Digital Logic Families

Lecture 142 Merits, Demerits and Characteristics of Digital IC

Lecture 143 Propagation Delay, Threshold Voltage, Power Dissipation & Figure of Merits

Lecture 144 Fan out, Fan in and Operating Temperature of IC

Lecture 145 Voltage and Current Parameters, Noise Margin

Lecture 146 Resistor Transistor Logic RTL, RTL NOT Gate, RTL NOR Gate

Lecture 147 Diode Transistor Logic DTL, DTL NAND Gate, Components Details of DTL

Lecture 148 Transistor Transistor Logic TTL, TTL NAND Circuit, TTL NAND Gate Working

Lecture 149 TTL NAND Gate with Totem Pole Output, Circuit & Working of TTL NAND Gate

Lecture 150 TTL NOR Gate with Totem Pole Output

Lecture 151 TTL Open Collector NAND Gate

Lecture 152 TTL Tristate Logic

Lecture 153 CMOS logic circuit rules

Lecture 154 CMOS NAND Gate

Lecture 155 CMOS NOR Gate

Lecture 156 Boolean Function implementation using CMOS

Lecture 157 CMOS Multiplexer

Lecture 158 CMOS Half Adder

Lecture 159 Boolean Function Implementation using CMOS

Lecture 160 CMOS SR Latch using NOR Gates

Lecture 161 CMOS SR Latch using NAND Gates

Lecture 162 CMOS D Latch, CMOS D Latch Circuit

Lecture 163 CMOS SR Flip Flop using NOR Gates

Lecture 164 CMOS JK Flip Flop using NOR Gates

Lecture 165 Stick Diagram of CMOS NOR Gate

Lecture 166 Stick Diagram of CMOS NAND Gate

Lecture 167 Stick Diagram of Boolean Function

Lecture 168 CMOS Transmission Gate

Lecture 169 Multiplexer Implementation using Transmission Gates

Lecture 170 D Latch Implementation using Transmission Gate

Lecture 171 Boolean Function Implementation using Transmission Gates

Section 8: Sequential Circuits

Lecture 172 Sequential circuit (Basics, Block Diagram, Classification and Examples)

Lecture 173 Clock and Triggering by clock in Sequential circuit

Lecture 174 Difference between Latch and Flip Flop

Lecture 175 SR Latch by NOR gates

Lecture 176 SR Latch using NAND gates

Lecture 177 Truth Table, Characteristic Table and Excitation Table of Flip Flop

Lecture 178 SR Flip Flop or Set Reset Flip Flop

Lecture 179 D Flip Flop or Data Flip Flop Circuit

Lecture 180 JK Flip Flop Circuit, Working, Truth Table, Characteristics Table

Lecture 181 Race Around Condition in JK Flip Flop

Lecture 182 Master Slave JK Flip Flop (Circuit, Working and Waveforms)

Lecture 183 T Flip Flop or Toggle Flip Flop

Lecture 184 Preset and Clear Input in Flip Flop

Lecture 185 R Flip Flop to D Flip Flop conversion

Lecture 186 SR Flip Flop to JK Flip Flop conversion

Lecture 187 SR Flip Flop to T Flip Flop conversion

Lecture 188 JK Flip Flop to D Flip Flop Conversion

Lecture 189 JK Flip Flop to T Flip Flop conversion

Lecture 190 D Flip Flop to T Flip Flop conversion

Lecture 191 D Flip Flop to JK Flip Flop conversion

Lecture 192 T Flip Flop to D Flip Flop Conversion

Lecture 193 T Flip Flop to JK Flip Flop conversion

Lecture 194 JK Flip Flop to SR Flip Flop

Lecture 195 Examples on Flip Flop

Lecture 196 Examples on Latch

Lecture 197 D Latch (Working, Circuit & Truth Table)

Lecture 198 Counter (Types, Classifications & Applications)

Lecture 199 Asynchronous Up Counter or Ripple Up Counter (Circuit, Working & Waveforms)

Lecture 200 Asynchronous Down Counter or Ripple Down Counter

Lecture 201 Modulo Counter by Asynchronous Counter

Lecture 202 2 bits Synchronous Counter using JK Flip Flop

Lecture 203 BCD Counter or Decade Counter or Modulo 10 Counter

Lecture 204 3 bits Synchronous Counter using T Flip Flop

Lecture 205 3 bits Synchronous Up Down Counter

Lecture 206 Ring Counter, Ring Counter Circuit

Lecture 207 Johnson's Counter - Twisted Ring Counter

Lecture 208 Arbitrary Sequence Counter

Lecture 209 Arbitrary Sequence Counter

Lecture 210 Sequence Generator

Lecture 211 Sequence Generator

Lecture 212 Examples of Counter

Lecture 213 Sequence Detector Example 1

Lecture 214 Sequence Detector Example 2

Lecture 215 Register Basics, Format and Classification

Lecture 216 SISO Shift Register, Serial Input Serial Output Shift Register

Lecture 217 SIPO Shift Register, Serial Input Parallel Output Shift Register

Lecture 218 PIPO Register, Storage Register, Buffer Register

Lecture 219 PISO Shift Register, Parallel Input Serial Output Shift Register

Lecture 220 Bidirectional Shift Register

Lecture 221 Universal Shift Register

Lecture 222 Examples based on Shift Register

Lecture 223 Moore State Machine and Example on Moore State Machine

Lecture 224 Mealy State Machine and Example on Mealy State Machine

Lecture 225 Comparison of Mealy State Machine and Moore State Machine

Section 9: Memory, ADC and DAC

Lecture 226 ROM-Read Only Memory (Basics, Structure, size and Classifications)

Lecture 227 RAM - Random Access Memory (Basics, Structure, size and Classifications)

Lecture 228 PLA - Programmable Logic Array (Basics, Structure, Designing and Programming

Lecture 229 PAL - Programmable Array Logic Basics, Structure, Designing and Programming)

Lecture 230 Binary Weighted Digital to Analog Converter DAC (Basics, Circuit and Working

Lecture 231 Example of Binary Weighted Digital to Analog Converter DAC

Lecture 232 R-2R ladder Digital to Analog Converter DAC (Voltage Switched Network)

Lecture 233 Example on R-2R Ladder Digital to Analog Convertor DAC

Lecture 234 R-2R Ladder Digital to Analog Convertor DAC (Current Switched Network)

Lecture 235 Counter Type ADC, Counter Type Analog to Digital Converter

Lecture 236 Tracking Type ADC, Tracking Type Analog to Digital Converter

Lecture 237 Successive Approximation Type ADC, Successive Approximation Type Analog to Dig.

Lecture 238 Flash ADC, Flash Analog to Digital Converter

Lecture 239 Half Flash ADC, Half Flash Analog to Digital Converter

Lecture 240 Dual Slope ADC, Dual Slope Analog to Digital Converter

Lecture 241 Sigma Delta ADC, Sigma Delta Digital to Analog Converter

Lecture 242 Examples on ADC

Section 10: Practical Session on Multisim

Lecture 243 Basic Logic Gates in Multisim Software

Lecture 244 Half Adder and Full Adder in Multisim

Lecture 245 Binary Code to Gray Code Conversion in Multisim

Lecture 246 One Bit Comparator in Multisim

Lecture 247 Multiplexer and Demultiplexer in Multisim Software

Lecture 248 Flip Flops in Multisim Software

Lecture 249 3 bits synchronous Counter using T Flip Flop in Multisim

Lecture 250 3 Bits Up Down Counter using Multisim Software

Lecture 251 SISO Shift Register using Multisim Software

Lecture 252 Sequence Generator in Multisim Software

Lecture 253 Digital Electronics Important Questions

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