Digital Logic Design: A Complete Guide

Number system, K-map, Boolean Algebra, Sequential Circuit, Basic Logic Family, Computational Circuits

What you'll learn

In a Digital Logic Design course, students will learn a wide range of concepts, techniques, and skills related to designing, analyzing, and implementing digital

Number Systems: Understanding binary, octal, and hexadecimal number systems and their applications in digital electronics.

Boolean Algebra: Mastering the fundamental laws and theorems of Boolean algebra, including Boolean expressions, truth tables, and logic minimization techniques.

Logic Gates: Exploring basic logic gates (AND, OR, NOT) and their properties, truth tables, logic symbols, and practical applications in digital circuits.

Combinational Logic Design: Designing and analyzing combinational logic circuits using various components such as multiplexers, demultiplexers, encoders, decode

Sequential Logic Design: Understanding sequential circuits, flip-flops, latches, registers, counters, and their applications in building memory elements, sequen

Digital Circuit Analysis: Analyzing the behavior of digital circuits using methods such as truth tables, Boolean algebra, Karnaugh maps, and timing diagrams.

Memory and Storage Elements: Exploring various types of memory devices such as RAM, ROM, and programmable logic devices (PLDs), and their role in digital system

Requirements

No, There are no pre requisites.

Description

Welcome to the world of Digital Logic Design, where the binary language of computers comes to life! In this comprehensive course, you'll dive deep into the foundational principles and techniques of designing digital circuits, laying the groundwork for understanding the inner workings of modern electronics.Whether you're a budding electrical engineer, computer scientist, or simply fascinated by the digital world around you, this course is your gateway to unlocking the mysteries of binary logic and digital systems. Through a blend of theoretical concepts and practical hands-on exercises, you'll develop the skills and knowledge necessary to design, analyze, and optimize digital circuits with confidence.Our aim is to provide you with a rich learning experience that not only equips you with theoretical knowledge but also empowers you to apply these concepts in real-world scenarios. Whether you're pursuing a career in electronics, computer engineering, or simply have a passion for understanding how digital systems work, this course will lay a solid foundation for your journey.Get ready to unlock the mysteries of digital logic design and embark on a rewarding learning adventure. Let's dive in and explore the fascinating world of digital circuits together!"Explore more , All the best my dear learners

Overview

Section 1: Basic and Logic family

Lecture 1 Number System Representation

Lecture 2 Boolean Algebra

Lecture 3 Problem Solved 1: Boolean algebra

Lecture 4 Problem solved 2: Boolean algebra

Lecture 5 Sum of Product (SOP) and Product of Sum (POS)

Lecture 6 Problem solved: SOP

Lecture 7 Min Terms and Max Terms

Lecture 8 Introduction and rules of K-Map

Lecture 9 2 and 3 Variable K-Map

Lecture 10 4 variable K-map

Lecture 11 Problem Solved 1: K-Map

Lecture 12 Problem Solved 2: K-Map

Lecture 13 Introduction to Logic family

Lecture 14 Standard TTL

Lecture 15 TTL: Totem Pole Output

Lecture 16 TTL: Open collector Output

Section 2: Computational Circuits

Lecture 17 Half Adder

Lecture 18 Half Subtractor

Lecture 19 Full adder

Lecture 20 Full Subtractor

Lecture 21 Multiplexer

Lecture 22 Demultiplexer

Lecture 23 encoder

Lecture 24 Decoder

Lecture 25 Code Converters

Lecture 26 Code converter: Part 2

Lecture 27 Binary to Grey Code

Lecture 28 Magnitude Comparator

Section 3: Sequential circuits

Lecture 29 Flip flop conversion: SR to JK slip flop

Lecture 30 JK to T flip flop conversion

Lecture 31 3 bit synchronous up counter using T flip flop

Lecture 32 3 bit synchronous down counter using Flip flop

Section 4: Advanced Combinational and Sequential Logic

Lecture 33 Mealy and Moore Introduction

Lecture 34 Mealy Type

Lecture 35 Non-Overlapping Mealy Type

Lecture 36 Sequence detector using moore type

Lecture 37 Sequence detector using flip flop

Lecture 38 Hamming code Introduction

Lecture 39 Generation of hamming code

Lecture 40 Error correction and detection hamming code

Lecture 41 2 bit multiplier

Section 5: PLD's and Memory

Lecture 42 Memory Unit

Lecture 43 Static Random Access Memory (RAM)

Lecture 44 Dynamic RAM

Lecture 45 Difference between Static and Dynamic RAM

Lecture 46 ROM and its types

Lecture 47 PLD and its types

Lecture 48 Problem solved: PAL

Lecture 49 Problem solved PLA

Lecture 50 Problem solved: PROM

Beginner Electronics, CS and IT Aspirants