Digital Electronics: Master The Digital Logic Design Concept

Digital Electronics: Master The Digital Logic Design Concept, available at $44.99, with 257 lectures, 7 quizzes, and has 13 subscribers.

You will learn about Number System in Digital Electronics Boolean Algebra in Digital Electronics Logic Gates in Digital Electronics Combinational Circuits in Digital Electronics Karnaugh Map in Digital Electronics Logic Families in Digital Electronics Sequential Circuits in Digital Electronics Semiconductor Memory in Digital Electronics Analog to Digital Converter in Digital Electronics Digital to Analog Converter in Digital Electronics Can be able to solve most of Digital Electronics Problems in Digital Electronics This course is ideal for individuals who are Electronics and Telecommunication Engineering or Electrical Engineering or Computer Science Students or Diploma/Science Students or IT Professionals or Enthusiastic Learner It is particularly useful for Electronics and Telecommunication Engineering or Electrical Engineering or Computer Science Students or Diploma/Science Students or IT Professionals or Enthusiastic Learner.

Enroll now: Digital Electronics: Master The Digital Logic Design Concept

Summary

Title: Digital Electronics: Master The Digital Logic Design Concept

Price: $44.99

Number of Lectures: 257

Number of Quizzes: 7

Number of Published Lectures: 257

Number of Published Quizzes: 7

Number of Curriculum Items: 264

Number of Published Curriculum Objects: 264

Original Price: ₹2,999

Quality Status: approved

Status: Live

What You Will Learn

Number System in Digital Electronics
Boolean Algebra in Digital Electronics
Logic Gates in Digital Electronics
Combinational Circuits in Digital Electronics
Karnaugh Map in Digital Electronics
Logic Families in Digital Electronics
Sequential Circuits in Digital Electronics
Semiconductor Memory in Digital Electronics
Analog to Digital Converter in Digital Electronics
Digital to Analog Converter in Digital Electronics
Can be able to solve most of Digital Electronics Problems in Digital Electronics

Who Should Attend

Electronics and Telecommunication Engineering
Electrical Engineering
Computer Science Students
Diploma/Science Students
IT Professionals
Enthusiastic Learner

Target Audiences

Electronics and Telecommunication Engineering
Electrical Engineering
Computer Science Students
Diploma/Science Students
IT Professionals
Enthusiastic Learner

This Digital Electronicscourse 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 Digital Electronicsis a unique course in the online marketplace.

Prof. Hitesh Dholakiya is an Electronics and Communication Design Engineerwith over 15 years of experience in the core Electronics/Electrical domain as well as in the Antenna/RF/Communication field. With a passion for teaching and a wealth of industry knowledge, Prof. Hitesh Dholakiya is dedicated to helping students achieve their academic and professional goals in the Electronicsdomain.

This course on Digital Electronicsapplies to many branches of Degree/Diploma Engineering such as Electrical, EC, Computer, IT, and Instrumentation. After completing this Digital Electronicscourse students will be able to understand from basic to advance level concepts of Digital Electronicswhich will be a stepping stone for starting many lucrative career fields.

This Digital Electronicscourse is also helpful in many competitive examinations and not only that it will also be helpful in interviews.

This course on Digital Electronicscovers the following chapters.

1. Number Representations in Digital Electronics

2. Boolean Algebra in Digital Electronics

3. Logic Gates in Digital Electronics

4. Combinatorial circuits of Digital Electronics

5. Karnaugh Map in Digital Electronics

6. Logic Families of Digital Electronics

7. Sequential Circuits of Digital Electronics

8. Memory, ADC, and DAC in Digital Electronics

9. Practical Session of Digital Electronics Circuits on Multisim

Topic wise Detailed Syllabus of Digital Electronics is as follows:

1. Number Representations in Digital Electronics:

Binary, hex, octal, decimal, BCD, integer, and floating-point- numbers, code coversion etc.

2. Boolean Algebra in Digital Electronics:

Laws of Boolean Algebra, SOP, POS, Dual and Self Dual of Boolean equation, Minterms, Maxterms, Quine McCluskey Technique, etc.

3. Logic Gates in Digital Electronics:

AND, OR, NOT, XOR, XNOR, NAND, NOR Gates and Circuit implementation using universal gates.

4. Combinatorial circuits of Digital Electronics:

Minimization of functions using Boolean identities and many other circuits like Multiplexer, Demultiplexer, Adder, Subtractor, Decoder, Encoder, Carry look ahead adder, Even Parity Generator and Odd Parity Generator, Priority Encoder, etc.

5. Karnaugh Map in Digital Electronics:

IK-map basics, Implicants, Prime Implicants and Essential Prime, 3,4,5 and 6 variable K Map, Quine McCluskey Minimization Technique

6. Logic Families of Digital Electronics:

DTL, RTL, TTL, CMOS, Boolean Function Implementations, Stick Diagram of Boolean Function, CMOS Transmission Gate, etc.

7. Sequential Circuits of Digital Electronics:

Clock and Triggering by clock in Sequential circuit, Latch, Flip Flops, Master Slave Flip Flop, Counters, Shift Registers, State Machines, Mealy State Machine and Moore State Machine

8. Memory, ADC, and DAC in Digital Electronics:

ROM, RAM, PLA, PAL, Digital to Analog Converter and Analog to Digital Converter

9. Practical Session of Digital Electronics Circuits on Multisim:

Practicals on Logic gates, Adder, Code conversion, Comparator, Flip flop, Counter, Register, etc.

Enroll now and take the first step toward mastering Digital Electronicscore concepts! Join Our Community of students who have transformed their careers with our expert-led course on Digital Electronics!

See you in the Digital Electronics: Master Digital Logic Design Conceptcourse! You’re going to love it!

All the best…

Course Curriculum

Chapter 1: Digital Electronics Course Introduction

Lecture 1: Introduction

Lecture 2: Course Trailer

Lecture 3: How to access the course materials

Chapter 2: Number System in Digital Electronics

Lecture 1: Representation of Number Systems and Basics of Number System

Lecture 2: Addition operation in Different Number systems

Lecture 3: Subtraction operation in Different Number Systems

Lecture 4: Octal and Binary Multiplication, Number System Multiplication

Lecture 5: Decimal to Binary Conversion, Decimal to Binary Conversion Process

Lecture 6: Decimal to Octal Conversion, Decimal to Octal Conversion Process

Lecture 7: Decimal to Hexadecimal Conversion, Decimal to Hexadecimal Conversion Process

Lecture 8: Octal, Binary and Hexadecimal to Decimal conversion and Visa Versa

Lecture 9: Hexadecimal to Binary to Octal conversion and Visa versa

Lecture 10: X Number System to Y Number System conversion, Number System Conversion

Lecture 11: 1's & 2's Compliment, 7's & 8's Compliment, 9's & 10's Compliment 15's,16's

Lecture 12: Simple Signed Representation, Example and Block Diagram of Simple Signed Rep

Lecture 13: 1's compliment signed Representation and 2's compliment signed Repr.

Lecture 14: 2's compliment signed Representation

Lecture 15: 1's compliment signed Representation

Lecture 16: Shortcut Method to find 2's compliment, 2's Compliment

Lecture 17: Binary Subtraction using 1's compliment

Lecture 18: Binary Subtraction using 2's compliment

Lecture 19: Classification of Codes (Definition, Weighted, Non Weighted

Lecture 20: BCD code, Binary Coded Decimal Code, Binary and BCD Comparison

Lecture 21: BCD Addition, BCD Addition Rules, BCD Addition Examples

Lecture 22: BCD to Binary conversion, BCD to Binary conversion Process

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

Lecture 24: 2421 BCD code and 2_421 BCD code, Self Complimentary Property of 2421 BCD

Lecture 25: Excess 3 Code, Excess 3 Code Properties, Decimal to Excess 3 Code Conversion

Lecture 26: Excess 3 Addition, Excess 3 Addition Process, Excess 3 Addition Examples

Lecture 27: Identification of Base or Radix of given number, Radix Identification

Lecture 28: ASCII code, American Standard Code for Information Interchange

Lecture 29: Gray Code (Basics & Properties), Gray Code as self reflection code, Gray Cod

Lecture 30: Binary to Gray code conversion, Binary to Gray code conversion process

Lecture 31: Gray to Binary Code conversion, Gray to Binary Code conversion process

Lecture 32: Identification of self complimenting code, Digital Electronics

Lecture 33: Total bits required to represent a number

Lecture 34: Minimal Decimal Equivalent, Minimal Decimal Equivalent Examples

Lecture 35: Hamming Code Basics, Number of Parity bits in Hamming code

Lecture 36: Hamming Code generation, Position of Parity bits

Lecture 37: Hamming Code error detection and Hamming Code error correction

Lecture 38: IEEE 754 floating point single precision 32 bit format

Lecture 39: IEEE 754 floating point double precision 64 bit format

Chapter 3: Boolean Algebra in Digital Electronics

Lecture 1: De Morgen's Theorem and Proof of De Morgen's Theorem

Lecture 2: Boolean Algebra Rules (Distributive, Commutative, Associative, De Morgen's)

Lecture 3: Consensus Theorem and Proof of Consensus Theorem

Lecture 4: Boolean Algebra Examples part 1, Boolean Algebra, Boolean Algebra Rules

Lecture 5: Boolean Algebra Examples Part 2, Boolean Algebra, Boolean Algebra Rules

Lecture 6: Boolean Algebra examples part 3, Boolean Algebra, Boolean Algebra Rules

Lecture 7: Dual and Self Dual of Boolean equation, Boolean Algebra

Lecture 8: SOP – Sum Of Product, POS – Product Of Sum and Canonical Form

Lecture 9: Minterms and Maxterms in Boolean function Representation

Lecture 10: SOP to SSOP conversion, Sum Of Product to Standard Sum Of Product Conversion

Lecture 11: POS to SPOS conversion, Product Of Sum to Standard Product Of Sum Conversion

Lecture 12: SSOP to SPOS conversion and SPOS to SSOP conversion

Lecture 13: Examples on SOP and POS, Boolean Algebra in Digital Electronicss

Lecture 14: Quine Mccluskey Minimization Technique for Boolean expression, Karnaugh Map

Chapter 4: Logic Gates in Digital Electronics

Lecture 1: Logic GATE's Introduction, Basic Logic GATE's, Universal Logic GATE

Lecture 2: NOT gate, NOT gate Applications, NOT gate as ring oscillator, NOT gate

Lecture 3: AND gate, Properties of AND gate and Examples of AND gate, Logic Gate's

Lecture 4: OR gate, Properties of OR gate and Examples of OR gate, Logic Gate's

Lecture 5: NAND as universal GATE, Logic GATEs in Digital Electronics

Lecture 6: XOR gate and XNOR gate, Properties of XOR and XNOR gate in Logic GATE'S

Lecture 7: Examples on XOR and XNOR gate part 1, Logic GATEs in Digital Electronics

Lecture 8: Examples on XOR and XNOR gate Part 2, Logic GATEs in Digital Electronics

Lecture 9: NOR as universal GATE, Logic GATEs in Digital Electronics

Lecture 10: NAND gate and NOR Gate in Logic Gate's

Lecture 11: Minimum Two input NAND for multiple input AND & Minimum Two input NAND

Lecture 12: Minimum two input NAND gates for Boolean expression

Lecture 13: Minimum two input NAND gates for Boolean equation

Lecture 14: Boolean expression to NAND gate implementation

Lecture 15: AOI to NAND gate implementation, Logic GATEs in Digital Electronics

Lecture 16: Boolean expression to NOR gate implementation

Lecture 17: AOI to NOR implementation, Logic GATEs in Digital Electronics

Lecture 18: Stuck at 1 and Stuck at 0 fault in Logic circuit

Chapter 5: Combinational Circuits of Digital Electronics

Lecture 1: Combinational circuit and Sequential circuit Comparison

Lecture 2: Combinational circuit designing examples

Lecture 3: Combinational circuit examples, Combinational circuit

Lecture 4: Half Adder (Working, Truth Table, Designing & Circuit)

Lecture 5: Full Adder (Working, Truth Table, Designing & Circuit)

Lecture 6: Full Adder using Half Adder (Designing and Circuit)

Lecture 7: Half Adder using NAND gates, Half Adder

Lecture 8: 4 bits parallel Adder (Working and Circuit)

Lecture 9: BCD Adder by Parallel Adder (Truth Table, Working, Designing and Circuit)

Lecture 10: 1's Compliment Subtraction using Parallel Adder

Lecture 11: 2's Compliment Subtraction using Parallel Adder

Lecture 12: Half Subtractor (Working, Truth Table and Circuit)

Lecture 13: Half Adder using Half Subtractor

Lecture 14: Half Subtractor using Half Adder

Lecture 15: Full Adder using Half Subtractor, Combinational circuit

Lecture 16: Full Subtractor (Working, Truth Table and Circuit)

Lecture 17: Full Subtractor using Full Adder

Lecture 18: Full Adder using Full Subtractor

Instructors

Hitesh Dholakiya
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