Presentation is loading. Please wait.

Presentation is loading. Please wait.

Introduction to Sequential Logic Design Flip-flops FSM Analysis.

Published byAdrian Phillips Modified over 8 years ago

Similar presentations

Presentation on theme: "Introduction to Sequential Logic Design Flip-flops FSM Analysis."— Presentation transcript:

1 Introduction to Sequential Logic Design Flip-flops FSM Analysis

2 Prev… Latches S-R S-bar-R-bar S-R with enable signal D

3 D latch D C Q Q

4 D-latch operation When C is asserted, Q follows the D input, the latch is “open” and the path (D-->Q) is “transparent”. When C is negated, the latch “closes” and Q retains its last value.

5 D-latch timing parameters Propagation delay (from C or D) Setup time (D before C edge) Hold time (D after C edge)

6 S-R vs D latches S-R Useful in control applications, “set” and “reset” S=R=1 problem Metastability problem when S, R are negated simultaneously, or a pulse applied to S, R is too short. D Store bits of information No S=R=1 problem Metability still possible.

7 FF vs. Latch Latches and flip-flops(FFs) are the basic building blocks of sequential circuits. latch: bistable memory device with level sensitive triggering (no clock), watches all of its inputs continuously and changes its outputs, independent of a clocking signal. flip-flop: bistable memory device with edge-triggering (with clock), samples its inputs, and changes its output only at times determined by a clocking signal.

8 Edge triggered D Fli-Flop A D FF combines a pair of D latches. Master/slave D FF Positive-edge-triggered D FF Negative-edge-triggered D FF Edge-Triggered D FF with Enable Scan FF

9 Positive-Edge-triggered D flip-flop Dynamic-input indicator

10 Edge-triggered D flip-flop behavior

11 D flip-flop timing parameters Propagation delay (from CLK) Setup time (D before CLK) Hold time (D after CLK)

12 D FF with asynchronous inputs Force the D FF to a particular state independent of the CLK and D inputs. PR (Preset) and CLR (Clear)

13 Negative-edge triggered D FF Simply inverts the clock input. Active low.

14 Edge-triggered D FF with Enable

15 Scan flip-flops -- for testing TE = 0 ==> normal operation TE = 1 ==> test operation All of the flip-flops are hooked together in a daisy chain from external test input TI. Load up (“scan in”) a test pattern, do one normal operation, shift out (“scan out”) result on TO. Scan FF

16 J-K flip-flops Not used much anymore

17 T (toggle)flip-flops A T FF changes state on every tick of the clock. (be toggled on every tick) Q has precisely half the frequency of the T. Important for counters, frequency dividers Positive-edge-triggered T FF

18 T (toggle)flip-flops with enable

19 Clocked Synchronous State-Machine State machine: generic name for sequential circuits;(Finite State Machine:FSM) Clocked: the storage elements(FFs) use a clock input; Synchronous: all of the FFs in a circuit use the same clock signal. Such a FSM changes states only when a triggering edge(rising or falling) on the clock signal.

20 State Machine Structure State memory: n FFs to store current states. All FFs are connected to a common clock signal. Next-state logic: determine the next state when state changes occur; Output logic: determines the output as a function of current state and input Mealy machine vs. Moore machine

21 Mealy Machine Next state= F (current state, input) Output= G(current state, input)

22 Moore Machine Next state= F (current state, input) Output= G(current state)

23 Characteristic Equations A Characteristic equation specifies the FF’s (or latch’s) next state as a function of its current state and inputs.

24 Analysis of FSM with D FFs Next state= F (current state, input) Output= G(current state, input) Step 1: Determine the next-state and output functions F, G Step 2: Use F, G to construct a state/output table that completely specifies the next state and output of the circuit for every possible combination of current state and input. Step 3: (optional) Draw a state diagram which is a graphical form of the state/output table.

25 Example: clocked synchronous FSM using positive-edge triggered D FFs

26 Transition, state, state/output tables Excitation equations Transition Equations (next-state equations) Output equations

27 State Diagram

28 Summary: how to analyze a clocked symchronous state machine? 1) Determine the excitation equations for the FF control inputs; 2) Substitute the excitation equatiions into the FF characteristic equations to obtain transition equations; 3) Use the transition equations to construct a transition table; 4) Determine the output equations; 5) Add output values to the transition table for each state (Moore) or state/input combination (Mealy) to create a transition/output table; 6) Name the states and substitute state names for state-variable combinations in the transition/output table to obtain state/output table; 7) Draw a sate diagram corresponding to the state/output table.

Download ppt "Introduction to Sequential Logic Design Flip-flops FSM Analysis."

Similar presentations

Introduction to Sequential Logic Design Latches. 2 Terminology A bistable memory device is the generic term for the elements we are studying. Latches.

Introduction to Sequential Logic Design Latches. 2 Terminology A bistable memory device is the generic term for the elements we are studying. Latches.
Flip-Flops Basic concepts. 1/50A. Yaicharoen2 Flip-Flops A flip-flop is a bi-stable device: a circuit having 2 stable conditions (0 or 1) 3 classes of.

Flip-Flops Basic concepts. 1/50A. Yaicharoen2 Flip-Flops A flip-flop is a bi-stable device: a circuit having 2 stable conditions (0 or 1) 3 classes of.
CHAPTER 3 Sequential Logic/ Circuits.  Concept of Sequential Logic  Latch and Flip-flops (FFs)  Shift Registers and Application  Counters (Types,

CHAPTER 3 Sequential Logic/ Circuits.  Concept of Sequential Logic  Latch and Flip-flops (FFs)  Shift Registers and Application  Counters (Types,
Classification of Digital Circuits  Combinational. Output depends only on current input values.  Sequential. Output depends on current input values and.

Classification of Digital Circuits  Combinational. Output depends only on current input values.  Sequential. Output depends on current input values and.
1 Kuliah Rangkaian Digital Kuliah 8: Rangkaian Logika Sekuensial Teknik Komputer Universitas Gunadarma.

1 Kuliah Rangkaian Digital Kuliah 8: Rangkaian Logika Sekuensial Teknik Komputer Universitas Gunadarma.
Sequential Logic Latches and Flip-Flops. Sequential Logic Circuits The output of sequential logic circuits depends on the past history of the state of.

Sequential Logic Latches and Flip-Flops. Sequential Logic Circuits The output of sequential logic circuits depends on the past history of the state of.
Fall 2004EE 3563 Digital Systems Design EE 3563 Sequential Logic Design Principles  A sequential logic circuit is one whose outputs depend not only on.

Fall 2004EE 3563 Digital Systems Design EE 3563 Sequential Logic Design Principles  A sequential logic circuit is one whose outputs depend not only on.
Introduction to Sequential Logic Design Bistable elements Latches.

Introduction to Sequential Logic Design Bistable elements Latches.
1 Sequential Systems A combinational system is a system whose outputs depend only upon its current inputs. A sequential system is a system whose outputs.

1 Sequential Systems A combinational system is a system whose outputs depend only upon its current inputs. A sequential system is a system whose outputs.
ReturnNext  Latch : a sequential device that watches all of its inputs continuously and changes its outputs at any time, independent of a clocking signal.

ReturnNext  Latch : a sequential device that watches all of its inputs continuously and changes its outputs at any time, independent of a clocking signal.
1 Sequential Circuits –Digital circuits that use memory elements as part of their operation –Characterized by feedback path –Outputs depend not only on.

1 Sequential Circuits –Digital circuits that use memory elements as part of their operation –Characterized by feedback path –Outputs depend not only on.
1 EE121 John Wakerly Lecture #8 Sequential Circuits Flip-flops Sequential PALs.

1 EE121 John Wakerly Lecture #8 Sequential Circuits Flip-flops Sequential PALs.
Circuits require memory to store intermediate data

Circuits require memory to store intermediate data
EET 1131 Unit 10 Flip-Flops and Registers

EET 1131 Unit 10 Flip-Flops and Registers
EKT 124 / 3 DIGITAL ELEKTRONIC 1

EKT 124 / 3 DIGITAL ELEKTRONIC 1
INTRODUCTION TO SEQUENCIAL CIRCUIT

INTRODUCTION TO SEQUENCIAL CIRCUIT
Digital Logic Design Lecture 23. Announcements Homework 8 due Thursday, 11/20 Exam 3 coming up on Tuesday, 11/25.

Digital Logic Design Lecture 23. Announcements Homework 8 due Thursday, 11/20 Exam 3 coming up on Tuesday, 11/25.
1 EE365 Sequential-circuit analysis. 2 Clocked synchronous seq. circuits A.k.a. “state machines” Use edge-triggered flip-flops All flip-flops are triggered.

1 EE365 Sequential-circuit analysis. 2 Clocked synchronous seq. circuits A.k.a. “state machines” Use edge-triggered flip-flops All flip-flops are triggered.
Sequential Logic Flip-Flops and Related Devices Dr. Rebhi S. Baraka Logic Design (CSCI 2301) Department of Computer Science Faculty.

Sequential Logic Flip-Flops and Related Devices Dr. Rebhi S. Baraka Logic Design (CSCI 2301) Department of Computer Science Faculty.
1 Sequential logic networks I. Motivation & Examples  Output depends on current input and past history of inputs.  “State” embodies all the information.

1 Sequential logic networks I. Motivation & Examples  Output depends on current input and past history of inputs.  “State” embodies all the information.

Similar presentations

Ads by Google