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System Design Using Verilog
Last updated 8/2022
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 16.09 GB | Duration: 28h 48m

FPGA Based Design


What you'll learn
Verilog coding for digital circuits

Requirements
No

Description
After completion of this course learners will be able to:(1) Understand the concepts design metrics which are to be optimized by a design engineer(2) Understand the concepts of IC design technology(3) Understand the implementation of logic using Fixed Function IC Technology, Full Custom ASIC Technology, and Semi-Custom ASIC Technology(4) Understand the advantages and disadvantages of implementation of logic using Fixed Function IC Technology, Full Custom ASIC Technology, and Semi-Custom ASIC Technology(5) Understand the concept of implementation of logic in PLDs(6) Understand the concept of implementation of logic in FPGA(7) Understand the IC design flow(8) Understand the role of HDL in system design(9) Understand the concepts of various Verilog language constructs(10) Understand various operators and their uses in Verilog coding(11) Understand how to use Xilinx software for writing a Verilog code(12) Understand how to use Xilinx software for simulating a Verilog code(13) Understand how to use Xilinx software for implementing a Verilog code(14) Implement combinational logic by using behavioral modeling style(15) Implement combinational logic by using dataflow modeling style(16) Implement combinational logic by using structural modeling style(17) Implement sequential logic by using behavioral modeling style(18) Implement sequential logic by using dataflow modeling style(19) Implement sequential logic by using structural modeling style(20) Implement logic by using mos transistors
Overview
Section 1: IC Design Technology
Lecture 1 Design Metrics
Lecture 2 Fixed Function IC Technology
Lecture 3 Full Custom ASIC Technology
Lecture 4 Semi-Custom ASIC Technology
Lecture 5 HDL Role in System Design
Lecture 6 PLD Technology (PLA)
Lecture 7 PLD Technology (PAL)
Lecture 8 FPGA (Architecture)
Lecture 9 FPGA (Logic Implementation Examples)
Section 2: Introduction to Verilog and Xilinx Software
Lecture 10 Introduction to Verilog
Lecture 11 Level of Abstraction
Lecture 12 Introduction to Xilinx Software
Lecture 13 Data Types (Net Types)
Lecture 14 Data Types (Register Types)
Lecture 15 Operator (Bitwise operators)
Lecture 16 Operator (Logical & Reduction)
Lecture 17 Operator (Arithmetic, Relational & Shift)
Lecture 18 Operator (Concatenation, Conditional & Replication)
Section 3: Introduction to different level of modeling
Lecture 19 Introduction to Structure Level Modeling
Lecture 20 Introduction to Behavioural Level Modeling
Lecture 21 Introduction to Dataflow Level Modeling
Section 4: Testbench
Lecture 22 Test Bench-(Part I)
Lecture 23 Test Bench -(Part II)
Lecture 24 Test Bench-(Part III)
Section 5: Structure Modeling
Lecture 25 Structure Modeling (2 to 1 Multiplexer)
Lecture 26 Structure Modeling (2 to 4 Decoder)
Lecture 27 Structure Modeling (3-Bit Adder) Part - I
Lecture 28 Structure Modeling (3-Bit Adder) Part - II
Section 6: Behavioural Modeling
Lecture 29 Procedural Statements
Lecture 30 Sequential Statements (if-else) Part-I
Lecture 31 Sequential Statements (if-else) Part-II
Lecture 32 Sequential Statements (if-else) Part-III
Lecture 33 2 to 4 Decoder using if-else Statement
Lecture 34 Comparator using "if-else" Statement
Lecture 35 Software demonstration of Comparator
Lecture 36 2 to 1 Multiplexer using "case" Statement
Lecture 37 4 to 1 Multiplexer using "case" Statement
Lecture 38 2 to 4 Decoder using "case" Statement
Lecture 39 1 Bit Comparator using "case" Statement
Lecture 40 BCD to 7 Segment Decoder using "case" Statement
Lecture 41 Sequential Statements - (loop)
Section 7: Behaviourl Model - Sequential Circuits
Lecture 42 Verilog code of D Flip Flop
Lecture 43 Verilog code of JK Flip Flop
Lecture 44 Verilog code of T Flip Flop
Lecture 45 Verilog code of 3 Bit Counter
Lecture 46 Parallel In Parallel Out Register
Lecture 47 Serial In Parallel Out Register
Lecture 48 Serial In Serial Out Register
Section 8: Multiple Always Block
Lecture 49 Multiple always block - (Example)
Lecture 50 Multiple always block - (D Flip Flop)
Lecture 51 Multiple always block - (2 to 4 Decoder)
Section 9: Blocking and Non-blocking Statements
Lecture 52 Blocking Statement
Lecture 53 Non-Blocking Statement
Section 10: Few Examples of Combinational Circuits
Lecture 54 Verilog Model of Full Subtractor
Lecture 55 Binary to Gray Converter
Lecture 56 Gray to Binary Converter
Lecture 57 Verilog Code of 1 to 2 Demultiplexer
Lecture 58 Priority Encoder
Section 11: Switch Level Modeling
Lecture 59 "cmos" Switch (Part I)
Lecture 60 "cmos" Switch (Part II)
Lecture 61 "cmos" Switch (Part III)
Lecture 62 "cmos" Switch (Part IV)
Students who are interested to write and simulate verilog codes written for combinational and sequential circuits




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