Presentation is loading. Please wait.

Presentation is loading. Please wait.

Overview Part 1 - Storage Elements and Sequential Circuit Analysis

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Overview Part 1 - Storage Elements and Sequential Circuit Analysis"— Presentation transcript:

1

2 Overview Part 1 - Storage Elements and Sequential Circuit Analysis
Part 2- Sequential Circuit Design Specification Formulation State Assignment Flip-Flop Input and Output Equation Determination Verification

3 The Design Procedure Specification
Formulation - Obtain a state diagram or state table State Assignment - Assign binary codes to the states Flip-Flop Input Equation Determination - Select flip-flop types and derive flip-flop equations from next state entries in the table Output Equation Determination - Derive output equations from output entries in the table Optimization - Optimize the equations Technology Mapping - Find circuit from equations and map to flip-flops and gate technology Verification - Verify correctness of final design

4 State Assignment – Example 1
Present State Next State x=0 x=1 Output x=0 x=1 A B 1 How may assignments of codes with a minimum number of bits? Two – A = 0, B = 1 or A = 1, B = 0 Does it make a difference? Only in variable inversion, so small, if any.

5 State Assignment – Example 2
Present State Next State x=0 x=1 Output x=0 x=1 A A B B A C C D C D How may assignments of codes with a minimum number of bits? 4  3  2  1 = 24 Does code assignment make a difference in cost?

6 State Assignment – Example 2 (continued)
Counting Order Assignment: A = 0 0, B = 0 1, C = 1 0, D = 1 1 The resulting coded state table: Present State Next State x = 0 x = 1 Output 0 0 0 1 1 0 1 1 1

7 State Assignment – Example 2 (continued)
Gray Code Assignment: A = 0 0, B = 0 1, C = 1 1, D = 1 0 The resulting coded state table: Present State Next State x = 0 x = 1 Output 0 0 0 1 1 1 1 0 1

8 Find Flip-Flop Input and Output Equations: Example 2 – Counting Order Assignment
Assume D flip-flops Interchange the bottom two rows of the state table, to obtain K-maps for D1, D2, and Z: D1 D2 Z Y2 Y1 X 1 Y2 Y1 X 1 Y2 Y1 X 1

9 Optimization: Example 2: Counting Order Assignment
Performing two-level optimization: D1 = Y1Y2 + XY1Y2 D2 = XY1Y2 + XY1Y2 + XY1Y2 Z = XY1Y Gate Input Cost = 22 D1 D2 Z Y2 Y1 X 1 Y2 Y1 X 1 Y2 Y1 X 1

10 Find Flip-Flop Input and Output Equations: Example 2 – Gray Code Assignment
Assume D flip-flops Obtain K-maps for D1, D2, and Z: D1 D2 Z Y2 Y1 X 1 Y2 Y1 X 1 Y2 Y1 X 1

11 Optimization: Example 2: Assignment 2
Performing two-level optimization: D1 = Y1Y2 + XY Gate Input Cost = 9 D2 = X Select this state assignment to Z = XY1Y2 complete design in slide D1 D2 Z Y2 Y1 X 1 Y2 Y1 X 1 Y2 Y1 X 1

12 One Flip-flop per State (One-Hot) Assignment
Example codes for four states: (Y3, Y2, Y1, Y0) = 0001, 0010, 0100, and 1000. In equations, need to include only the variable that is 1 for the state, e. g., state with code 0001, is represented in equations by Y0 instead of Y3 Y2 Y1 Y0 because all codes with 0 or two or more 1s have don’t care next state values. Provides simplified analysis and design Combinational logic may be simpler, but flip-flop cost higher – may or may not be lower cost

13 State Assignment – Example 2 (continued)
One-Hot Assignment : A = 0001, B = 0010, C = 0100, D = 1000 The resulting coded state table: Present State Next State x = 0 x = 1 Output 0001 0010 0100 1000 1

14 Optimization: Example 2: One Hot Assignment
Equations read from 1 next state variable entries in table: D0 = X(Y0+ Y1 + Y3) or X Y2 D1 = X(Y0+ Y3) D2 = X(Y1+ Y2) or X(Y0+ Y3 ) D3 = X Y2 Z = XY3 Gate Input Cost = 15 Combinational cost intermediate plus cost of two more flip-flops needed.

15 Map Technology Library: Initial Circuit:
D Flip-flops with Reset (not inverted) NAND gates with up to 4 inputs and inverters Initial Circuit: Clock D C R Y2 Z Y1 X Reset

16 Mapped Circuit - Final Result
Clock D C R Y2 Z Y1 X Reset

17 Sequential Design: Example
Design a sequential modulo 3 accumulator for 2-bit operands Definitions: Modulo n adder - an adder that gives the result of the addition as the remainder of the sum divided by n Example: modulo 3 = remainder of 4/3 = 1 Accumulator - a circuit that “accumulates” the sum of its input operands over time - it adds each input operand to the stored sum, which is initially 0. Stored sum: (Y1,Y0), Input: (X1,X0), Output: (Z1,Z0)

18 Example (continued) Complete the state table 00 01 11 10 Z1Z0 A (00) X
State Assignment: (Y1,Y0) = (Z1,Z0) Codes are in gray code order to ease use of K-maps in the next step X1X0 Y1Y0 00 01 11 10 Z1Z0 Y1(t+1), Y0(t+1) A (00) X B (01) - (11) C (10) Add entry 01 in (00),(01) Add entry 10 in (00)(10) Add entry 01 in (01)(00) Add entry 10 in (01)(01) Add entry 00 in (01)(10) Add entry 10 in (10)(00) Add entry 00 in (10)(01) Add entry 01 in (10)(10)

19 Example (continued) Complete the state diagram: 00 A/00 Reset 01 C/10
Add arc labeled 10 from state A to state C Add arc labeled 00 from state B to state B Add arc labeled 01 from state B to state C Add arc labeled 10 from state B to state A Add arc labeled 00 from state C to state C Add arc labeled 01 from state C to state A Add arc labeled 10 from state C to state B B/01

20 Example (continued) Y0 Y1 D1 D0 X1 X X0
Find optimized flip-flop input equations for D flip-flops D1 = D0 = D1 Y0 Y1 X1 X0 X D0 Entries in locations 0 through 15 for D1 = 0,0,1,X; 0,1,0,X;1,0,0,X; X,X,X,X Entries in locations 0 through 15 for D0 = 0,1,0,X; 1,0,0,X;0,0,1,X; X,X,X,X Prime implicants (all essential) are given in the equations below: D1 = Y1X1’X0’ + Y0X0 + Y1’Y0’X1 D0 = Y0X1’X0’ + Y1X1 + Y1’Y0’X0

21 Circuit - Final Result with AND, OR, NOT
X1 D C R Y1 Z1 X0 Y0 D Z0 C R Reset Clock

22 Other Flip-Flop Types J-K and T flip-flops
Behavior Implementation Basic descriptors for understanding and using different flip-flop types Characteristic tables Characteristic equations Excitation tables For actual use, see Reading Supplement - Design and Analysis Using J-K and T Flip-Flops

23 J-K Flip-flop Behavior
Same as S-R flip-flop with J analogous to S and K analogous to R Except that J = K = 1 is allowed, and For J = K = 1, the flip-flop changes to the opposite state As a master-slave, has same “1s catching” behavior as S-R flip-flop If the master changes to the wrong state, that state will be passed to the slave E.g., if master falsely set by J = 1, K = 1 cannot reset it during the current clock cycle

24 J-K Flip-flop (continued)
Implementation To avoid 1s catching behavior, one solution used is to use an edge-triggered D as the core of the flip-flop Symbol J C K D C K J

25 T Flip-flop Behavior Same as a J-K flip-flop with J = K = T
Has a single input T For T = 0, no change to state For T = 1, changes to opposite state Same as a J-K flip-flop with J = K = T As a master-slave, has same “1s catching” behavior as J-K flip-flop Cannot be initialized to a known state using the T input Reset (asynchronous or synchronous) essential

26 T Flip-flop (continued)
Implementation To avoid 1s catching behavior, one solution used is to use an edge-triggered D as the core of the flip-flop Symbol T C C D T

27 Basic Flip-Flop Descriptors
Used in analysis Characteristic table - defines the next state of the flip-flop in terms of flip-flop inputs and current state Characteristic equation - defines the next state of the flip-flop as a Boolean function of the flip-flop inputs and the current state Used in design Excitation table - defines the flip-flop input variable values as function of the current state and next state

28 D Flip-Flop Descriptors
Characteristic Table Characteristic Equation Q(t+1) = D Excitation Table D 1 Operation Reset Set Q(t 1) + Q(t +1) 1 D Operation Reset Set

29 T Flip-Flop Descriptors
Characteristic Table Characteristic Equation Q(t+1) = T Å Q Excitation Table T Q(t + 1) Operation Q ( t ) No change 1 Q ( t ) Complement + Q(t 1) T Operation Q ( t ) No change Q ( t ) 1 Complement

30 S-R Flip-Flop Descriptors
Characteristic Table Characteristic Equation Q(t+1) = S + R Q, S.R = 0 Excitation Table S R Q(t + 1) Operation Q ( t ) No change 1 Reset 1 1 Set 1 1 ? Undefined Operation No change Set Reset S X 1 Q(t+ 1) Q(t) R

31 J-K Flip-Flop Descriptors
Characteristic Table Characteristic Equation Q(t+1) = J Q + K Q Excitation Table 1 No change Set Reset Complement Operation J K Q(t + 1) Q ( t ) Q(t) Q(t + 1) J K Operation X No change 1 1 X Set 1 X 1 Reset 1 1 X No Change

32 Flip-flop Behavior Example
Use the characteristic tables to find the output waveforms for the flip-flops shown: Clock D,T D C QD T C QT

33 Flip-Flop Behavior Example (continued)
Use the characteristic tables to find the output waveforms for the flip-flops shown: Clock S,J R,K S C R QSR ? J C K QJK

Download ppt "Overview Part 1 - Storage Elements and Sequential Circuit Analysis"

Similar presentations

EE 5900 Advanced Algorithms for Robust VLSI CAD, Spring 2009 Sequential Circuits.

EE 5900 Advanced Algorithms for Robust VLSI CAD, Spring 2009 Sequential Circuits.
COE 202: Digital Logic Design Sequential Circuits Part 1 Dr. Ahmad Almulhem Email: ahmadsm AT kfupm Phone: 860-7554 Office: 22-324 Ahmad Almulhem, KFUPM.

COE 202: Digital Logic Design Sequential Circuits Part 1 Dr. Ahmad Almulhem ahmadsm AT kfupm Phone: Office: Ahmad Almulhem, KFUPM.
A. Abhari CPS2131 Sequential Circuits Most digital systems like digital watches, digital phones, digital computers, digital traffic light controllers and.

A. Abhari CPS2131 Sequential Circuits Most digital systems like digital watches, digital phones, digital computers, digital traffic light controllers and.
1 Fundamentals of Computer Science Sequential Circuits.

1 Fundamentals of Computer Science Sequential Circuits.
Computer Architecture CS 215

Computer Architecture CS 215
Princess Sumaya University

Princess Sumaya University
Sequential Circuits1 DIGITAL LOGIC DESIGN by Dr. Fenghui Yao Tennessee State University Department of Computer Science Nashville, TN.

Sequential Circuits1 DIGITAL LOGIC DESIGN by Dr. Fenghui Yao Tennessee State University Department of Computer Science Nashville, TN.
Multiplexors Sequential Circuits and Finite State Machines Prof. Sin-Min Lee Department of Computer Science.

Multiplexors Sequential Circuits and Finite State Machines Prof. Sin-Min Lee Department of Computer Science.
Overview Part 1 - Storage Elements and Analysis

Overview Part 1 - Storage Elements and Analysis
CPEN 315 - Digital System Design Chapter 5 Sequential Circuits Storage Elements and Sequential Circuit Analysis C. Gerousis © Logic and Computer Design.

CPEN Digital System Design Chapter 5 Sequential Circuits Storage Elements and Sequential Circuit Analysis C. Gerousis © Logic and Computer Design.
Charles Kime & Thomas Kaminski © 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Chapter 5 – Sequential Circuits Logic and Computer.

Charles Kime & Thomas Kaminski © 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Chapter 5 – Sequential Circuits Logic and Computer.
Circuits require memory to store intermediate data

Circuits require memory to store intermediate data
Charles Kime & Thomas Kaminski © 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Chapter 5 – Sequential Circuits Part 1 – Storage.

Charles Kime & Thomas Kaminski © 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Chapter 5 – Sequential Circuits Part 1 – Storage.
Sequential Circuit Analysis & Design Dr. Aiman H. El-Maleh Computer Engineering Department King Fahd University of Petroleum & Minerals Dr. Aiman H. El-Maleh.

Sequential Circuit Analysis & Design Dr. Aiman H. El-Maleh Computer Engineering Department King Fahd University of Petroleum & Minerals Dr. Aiman H. El-Maleh.
1. 2 Logic Circuits Sequential Circuits Combinational Circuits Consists of logic gates whose outputs are determined from the current combination of inputs.

1. 2 Logic Circuits Sequential Circuits Combinational Circuits Consists of logic gates whose outputs are determined from the current combination of inputs.
Sequential circuit Digital electronics is classified into combinational logic and sequential logic. In combinational circuit outpus depends only on present.

Sequential circuit Digital electronics is classified into combinational logic and sequential logic. In combinational circuit outpus depends only on present.
Sequential Circuit Design

Sequential Circuit Design
Sequential Circuit Design

Sequential Circuit Design
Overview Sequential Circuit Design Specification Formulation

Overview Sequential Circuit Design Specification Formulation
Charles Kime & Thomas Kaminski © 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Chapter 3 – Combinational Logic Design Part 1 –

Charles Kime & Thomas Kaminski © 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Chapter 3 – Combinational Logic Design Part 1 –

Similar presentations

Ads by Google