Free Download Logic Design Using Verilog - New Approach!
Published 11/2023
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.20 GB | Duration: 5h 1m
Advance Digital Design using verilog.
What you'll learn
Understand the principles of digital design and how to apply them to the design of digital circuits and systems.
Be able to use Verilog to design and simulate a variety of digital circuits, including combinational logic circuits, sequential logic circuits, and state machin
Understand logic design concepts and apply it using verilog.
Have the skills and knowledge necessary to design and implement complex digital systems for a variety of applications.
Requirements
A basic understanding of digital design and familiarity with Boolean algebra and logic gates is recommended.
Description
Embark on a journey into the intricacies of digital design with a focus on advanced techniques using Verilog. This course delves into the realm of vectorized components, including adders, multiplexers, comparators, and D flip-flops, providing a comprehensive understanding of their applications and implementations.Key Topics:Vectorized Adders: Explore advanced methods of designing adders using vectors, enabling efficient and optimized digital circuitry.Vectorized Multiplexers: Learn to create versatile and space-efficient circuits using vectored multiplexers, optimizing resource utilization in digital systems.Vectorized Comparators: Understand the nuances of designing vectored comparators for precise digital signal processing and decision-making.Vectorized D Flip-Flops (DFF): Delve into the world of sequential logic by mastering the design and application of vectored D flip-flops, crucial for building memory elements in digital systems.Circuit Design Approach: Adopt a unique methodology by first conceptualizing and sketching digital circuits on paper. Translate these designs into efficient Verilog code to validate and simulate their behavior.Course Highlights:Hands-On Design Exercises: Engage in practical design exercises that involve drawing digital circuits on paper before implementing them in Verilog, reinforcing a strong connection between theory and application.Real-world Applications: Explore real-world applications of vectorized components, emphasizing their role in cutting-edge digital systems, from signal processing to data storage.Project-Based Learning: Undertake a comprehensive final project that integrates the principles learned throughout the course. This project encourages creativity and problem-solving skills, applying vectorized design techniques to address complex digital challenges.Prerequisites:Basic understanding of digital design fundamentals and Boolean algebra.Familiarity with Verilog programming language basics.Who Should Enroll:Electrical and Computer Engineering students seeking an in-depth understanding of advanced digital design.Professionals in the field of digital system design aiming to enhance their skillset with cutting-edge techniques.Outcome:Upon completion of this course, participants will possess the skills to design complex digital circuits using advanced vectorized components, gaining a competitive edge in the ever-evolving field of digital system design. The ability to seamlessly transition from paper sketches to Verilog code ensures a practical and comprehensive understanding of the design process. Enroll now to elevate your expertise in advanced digital design with Verilog.
Overview
Section 1: Introduction
Lecture 1 Introduction
Section 2: Adder
Lecture 2 HA and FA
Lecture 3 Ripple carry adder
Section 3: Mux
Lecture 4 Mux
Lecture 5 Gates with mux
Section 4: Vectored mux
Lecture 6 Design Vectored Mux
Lecture 7 4:2 Priority encoder
Lecture 8 8:3 priority encoder (Solution)
Section 5: Comparator
Lecture 9 1-bit comparator
Lecture 10 Vectored Comparator
Section 6: Min-Max logic design
Lecture 11 Min-Max
Lecture 12 Min-Mid-Max
Lecture 13 Min-Midh-Midl-Min (Solution)
Section 7: Vectored Adder
Lecture 14 Design Vectored Adder
Lecture 15 Next Seconds
Section 8: Vectored DFF
Lecture 16 Design Vectored DFF
Lecture 17 3-bit 0 to 7 counter
Lecture 18 Mod 5 counter
Section 9: Design Project
Lecture 19 HMS Counter
Lecture 20 Mod 4 Mod 5 counter using FSM
Section 10: Verilog
Lecture 21 Introduction to Verilog
Section 11: Tools Installation
Lecture 22 Downloading Modelsim
Lecture 23 Installing Modelsim
Lecture 24 Running code in edaplayground
Section 12: Combinational Logic in Verilog
Lecture 25 Basic Gates using Verilog.
Lecture 26 HA and FA using basic gates[Verilog]
Lecture 27 Modelling Styles
Lecture 28 Vectored Mux using Verilog
Lecture 29 4:2 priority encoder using Verilog
Lecture 30 8:3 Priority encoder using verilog (Solution)
Lecture 31 Vectored comparator using verilog (Using waveforms)
Lecture 32 Min-Max using verilog
Lecture 33 Min-Mid-Max (Solution)
Lecture 34 Vectored Adder (with small checker logic)
Lecture 35 Next seconds using verilog
Section 13: Sequential Logic in Verilog
Lecture 36 Vectored DFF using Verilog
Lecture 37 3-bit 0 to 7 counter using verilog.
Lecture 38 Mod 5 counter using verilog.
Section 14: HMS Project in verilog
Lecture 39 HMS counter part 1
Lecture 40 HMS counter part 2
Section 15: Verification
Lecture 41 Part 2 and Part 3
Section 16: To delete
Lecture 42 Logic Gates
Lecture 43 Mux
Lecture 44 Adders
This course on logic design using Verilog is likely to be most suitable for students who have a basic foundation in digital design and are looking to learn how to design and implement digital circuits using the Verilog hardware description language. It may also be suitable for students who are interested in a career in hardware design or who want to expand their skills and knowledge in digital design.
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