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Learner Reviews & Feedback for Fundamentals of Digital Design for VLSI Chip Design by L&T EduTech

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61 ratings

About the Course

This comprehensive learning module delves into Boolean algebra and its applications in digital circuit design, covering fundamental concepts like Boolean variables, logic gates, and their relationship with digital logic circuits. Participants explore Boolean expressions, simplification techniques, and consensus theorems, including the advanced Quine McCluskey method. The module also addresses combinational circuits, detailing the design and functionality of adders, subtractors, parity circuits, and multipliers. Encoding complexities are navigated with insights into encoders, decoders, multiplexers, and demultiplexers. Binary shifting operations, emphasizing logical and arithmetic shifting with multiplexers for efficient design, are covered. Moving forward, the module provides an in-depth exploration of sequential circuits, including latch and flip-flop circuits like SR latch, JK flip-flop, and more. Hazards in digital circuits, along with registers, bidirectional shift registers, and various counters, are thoroughly explained. The exploration concludes with Mealy and Moore state sequential circuits. Additionally, participants gain a comprehensive understanding of memory systems, programmable logic devices, and VLSI physical design considerations. The module covers SRAM and DRAM, tri-state digital buffers, Read-Only Memory (ROM), and Programmable Logic Devices (PLD) such as PROM, PLA, and PAL. Architecture and implementation of Complex Programmable Logic Devices (CPLD) and Field-Programmable Gate Arrays (FPGA) are discussed, along with the VLSI design cycle and design styles for CPLD, SPLD, and FPGA. By the end of this course, you will be able to:  Understand the distinctions between analog and digital signals and the transformative benefits of digitization.  Comprehend various number systems, Boolean algebra, and its application to logic gates.  Master Boolean expression manipulation, canonical forms, and simplification techniques.  Proficiently handle SOP and POS expressions, recognizing relationships between minterms and maxterms.  Recognize the universality of NAND and NOR gates, implementing functions using De Morgan's Law.  Master Karnaugh map techniques, including advanced methods and handling don't care conditions.  Gain a comprehensive understanding of combinational circuits, covering principles and applications.  Understand binary addition principles and design various adder circuits, including 4-bit ripple carry adders.  Explore advanced adder designs for arithmetic operations.  Proficiently design binary subtractors, analyze overflow/underflow scenarios, and understand signed number representation.  Understand parity generation, detection, and various methods of binary multiplication.  Master the design and application of various multipliers, incorporating the Booth algorithm.  Understand applications of comparators, encoders, and decoders in digital systems.  Proficiently use multiplexers and demultiplexers in digital circuit design, recognizing their role as function generators.  Understand binary shifting operations, designing logical shifters, and principles of arithmetic and barrel shifting.  Grasp foundational principles of sequential circuits, focusing on storage elements and designing an SR latch.  Understand the operation of JK flip-flops, addressing race around conditions, and design master-slave JK flip-flops and Gated SR latches.  Gain proficiency in designing and analyzing various types of counters in sequential circuits.  Understand principles and design techniques for Mealy and Moore state sequential circuits.  Grasp fundamental principles of memory, differentiating internal structures between SRAM and DRAM, and gain practical skills in addressing memory, controlling tri-state digital buffers, and understanding ROM, PLD, and various PLDs....

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1 - 8 of 8 Reviews for Fundamentals of Digital Design for VLSI Chip Design

By Pradip K p

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Dec 2, 2024

cover every topic in detail with very well explanation and examples

By Mr. V M

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Oct 30, 2024

Very informative.

By Saurav L

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Oct 29, 2024

great

By Toubo A V

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Nov 16, 2024

Good

By Yash R M

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Nov 13, 2024

This course gives a good overview of digital electronics and the VLSI design flow. Recommended for beginners. Only request is to correct the answers to assignment questions, lot of question - answers are wrong.

By Aburva D

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Jul 29, 2024

Very good course on digital design but few quizes/grade assessments have incorrect answers

By ADI G H

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Nov 20, 2024

Some wrong answers

By Ozoh J N

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Nov 18, 2024

The course is packed with lots of things that could be improved. More than half of the questions in the videos were wrong answers, and there were issues with some of the test questions. One picks the correct answer, and you get it wrong, only to later check the given answer and find out that it is the same answer you picked but marked wrong. I don't understand how that works. This particular course needs to be removed entirely and worked on before putting here again. It also took a lot of work to understand the instructor. You should subsequently include the country taking the course.