Presentation is loading. Please wait.

Presentation is loading. Please wait.

Digital Electronics.

Published byMelvin Luke Fleming Modified over 8 years ago

Similar presentations

Presentation on theme: "Digital Electronics."— Presentation transcript:

1 Digital Electronics

2 Chapter 4 Combinational Logic

3 Terminology Combinational:Output is completely determined from the input(s) and does not depend on time Sequential : Output depends on the input(s), previous history, and time Analysis : A circuit is given and one must determine the Truth Table Design: One must build a circuit whose output(s) are given as a Truth Table

4 Analysis Problem Set up the Truth Table

5 Analysis: Truth Table x y F

6 Design or Synthesis x y z F 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 1 1 0 0 0

7 K-Map of Design Problem
y'z' y'z yz yz' x' x 1 1 1 1 F = x y + x z + y z

8 Final Circuit Design F = x y + x z + y z

9 Binary Adder Half Adder Truth Table x y C S 0 0 0 0 0 1 0 1 1 0 0 1

10 Implementation of Half Adder

11 Full Adder x y z C S

12 Implementation of Full Adder

13 Magnitude Comparator

14 Comparator Theory x is generated from XNOR and equals 1 if the two bits are equal A = B if all the x’s are equal A > B if the corresponding bit is greater as long as the previous bits are equal A < B if the corresponding bit is smaller as long as the previous bits are equal

15 3-to-8 Line Decoder

16 Decoder Truth Table Which output will be high when x =1, y = 1 and z = 0 ?

17 Decoder Truth Table Only line 6 will be high. The other 7 lines will be low.

18 Implement the Full Adder with a 3x8 Decoder
Decoder Application Implement the Full Adder with a 3x8 Decoder

19 Full Adder using 3x8 Decoder

20 Important Note! The actual 74LS138 decoder chip has inverted outputs … welcome to the REAL WORLD!!!

21 Multiplexer A multiplexer is a combinational circuit that selects binary information from one of many input lines and directs it to a single output line.

22 Multiplexer

23 Multiplexer Application Implement the function F(x,y,z) = Σ(1,2,6,7)

24 F(x,y,z) = Σ(1,2,6,7) with a multiplexer

25 VHDL // A 2x4 Decoder with enable E module my_decoder (A,B,E,D);
input A,B,E; output [0:3] D; assign D[0] = ~(~A & ~B & ~E), D[1] = ~(~A & B & ~E), D[2] = ~(A & ~B & ~E), D[3] = ~(A & B & ~E); endmodule

26 Gate implementation of my_decoder

27 More VHDL ... //A 4-bit comparator module comp(A,B,ALTB,AGTB,AEQB);
input [3:0] A,B; output ALTB,AGTB,AEQB; assign ALTB = (A < B), AGTB = (A > B), AEQB = (A == B); endmodule

28 That’s All Folks!

Download ppt "Digital Electronics."

Similar presentations

Digital Circuits. Review – Getting the truth table The first step in designing a digital circuit usually is to get the truth table. That is, for every.

Digital Circuits. Review – Getting the truth table The first step in designing a digital circuit usually is to get the truth table. That is, for every.
ECE 2110: Introduction to Digital Systems Chapter 6 Combinational Logic Design Practices Encoders.

ECE 2110: Introduction to Digital Systems Chapter 6 Combinational Logic Design Practices Encoders.
Give qualifications of instructors: DAP

Give qualifications of instructors: DAP
//HDL Example 4-10 // //Gate-level description of circuit of Fig. 4-2 module analysis (A,B,C,F1,F2); input.

//HDL Example 4-10 // //Gate-level description of circuit of Fig. 4-2 module analysis (A,B,C,F1,F2); input.
Logic Circuits Design presented by Amr Al-Awamry

Logic Circuits Design presented by Amr Al-Awamry
Princess Sumaya University

Princess Sumaya University
Verilog Modules for Common Digital Functions

Verilog Modules for Common Digital Functions
Combinational Circuits

Combinational Circuits
Functions and Functional Blocks

Functions and Functional Blocks
ECE 3110: Introduction to Digital Systems Chapter 6 Combinational Logic Design Practices XOR, Parity Circuits, Comparators.

ECE 3110: Introduction to Digital Systems Chapter 6 Combinational Logic Design Practices XOR, Parity Circuits, Comparators.
التصميم المنطقي Second Course

التصميم المنطقي Second Course
1 Tutorial: ITI1100 Dewan Tanvir Ahmed SITE, UofO.

1 Tutorial: ITI1100 Dewan Tanvir Ahmed SITE, UofO.
CS 151 Digital Systems Design Lecture 15 Magnitude Comparators and Multiplexers.

CS 151 Digital Systems Design Lecture 15 Magnitude Comparators and Multiplexers.
08/07/041 CSE-221 Digital Logic Design (DLD) Lecture-8:

08/07/041 CSE-221 Digital Logic Design (DLD) Lecture-8:
Chapter 3 Continued Logic Gates Logic Chips Combinational Logic Timing Sequential Logic Flip Flops Registers Memory State Machines.

Chapter 3 Continued Logic Gates Logic Chips Combinational Logic Timing Sequential Logic Flip Flops Registers Memory State Machines.
DIGITAL SYSTEMS TCE1111 1 OTHER COMBINATIONAL LOGIC CIRCUITS WEEK 7 AND WEEK 8 (LECTURE 1 OF 3) COMPARATORS CODE CONVERTERS.

DIGITAL SYSTEMS TCE OTHER COMBINATIONAL LOGIC CIRCUITS WEEK 7 AND WEEK 8 (LECTURE 1 OF 3) COMPARATORS CODE CONVERTERS.
Combinational Logic1 DIGITAL LOGIC DESIGN by Dr. Fenghui Yao Tennessee State University Department of Computer Science Nashville, TN.

Combinational Logic1 DIGITAL LOGIC DESIGN by Dr. Fenghui Yao Tennessee State University Department of Computer Science Nashville, TN.
TDC 311 Digital Logic. Truth Tables  AND  OR  NOT  NAND  NOR  XOR  XNOR.

TDC 311 Digital Logic. Truth Tables  AND  OR  NOT  NAND  NOR  XOR  XNOR.
Part 2: DESIGN CIRCUIT. LOGIC CIRCUIT DESIGN x y z F 0 0 0 0 1 1 0 1 0 0 0 1 1 0 1 0 0 1 1 0 1 1 1 1 0 1 1 1 F = x + y’z x y z F Truth Table Boolean Function.

Part 2: DESIGN CIRCUIT. LOGIC CIRCUIT DESIGN x y z F F = x + y’z x y z F Truth Table Boolean Function.
Logic Gates Combinational Circuits

Logic Gates Combinational Circuits

Similar presentations

Ads by Google