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5 - 1 Chapter 6 Analysis of Sequential Systems
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5 - 2 Chapter 6 Analysis of Sequential Systems 6.0 Introduction Clocked System Clock A signal that alternates between 0 and 1 at a regular rate Two versions of clock Type A : 0 half and 1 half Type B : 1 is shorter part of the cycle P. 277
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5 - 3 Chapter 6 Analysis of Sequential Systems 6.0 Introduction Synchronous System Change occurs on the transition of the clock signal Conceptual view of a synchronous sequential system n inputs(x’s), clock, k outputs(z’s), m binary storage devices(q’s) P. 278
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5 - 4 Chapter 6 Analysis of Sequential Systems 6.1 State Tables and Diagrams CE6 A system with one input x and one output z such that z = 1 iff x has been 1 for at least three consecutive clock times. State The last three inputs store in memory Timing Trace A Set of values for the input and the output at consecutive clock times x011011100101111100 z?00000010000001110000 P. 279
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5 - 5 Chapter 6 Analysis of Sequential Systems 6.1 State Tables and Diagrams CE6 Moore Model The output depends only on the state of the system. The output occurs after the desired input pattern has occurred. Named after E. F. Moore. The output for the first input is shown as unknown. After 3 consecutive inputs are 1, the system output is 1. x011011100101111100 z?00000010000001110000 P. 278
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5 - 6 Chapter 6 Analysis of Sequential Systems 6.1 State Tables and Diagrams Two Tools for Describing Sequential Systems State Table It shows the output and the next state for each input combination and each state. Next state is to be stored in memory after the next clock. State Diagram(State Graph) A graphical representation of the behavior of the system. State Table State Diagram Present state Next state x=0 x=1 Present output A AB 0 B AC 0 C AD 0 D AD 1 P. 280
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5 - 7 Chapter 6 Analysis of Sequential Systems 6.1 State Tables and Diagrams Two Tools for Describing Sequential Systems Representation q : present state q* : next state ( Q, q+, q+ ) It will be stored in memory after this clock transition Output depends on the present state, but not the present input. State Diagram corresponds to its state table. Trace with State x0110111001011111100 q?ABCABCDAABABCDDDDAA? z?000000100000011110000 P. 281
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5 - 8 Chapter 6 Analysis of Sequential Systems 6.1 State Tables and Diagrams Mealy Model The Output depends not only the present state of the machine, but also on the present input. The state table has as many output columns as the next state portion. The state diagram is different from the Moore model. State TableState Diagram Trace with State q q* x=0 x=1 z x=0 x=1 AAB 0 0 BAC 0 0 CAC 0 1 x0110111001011111100 q?ABCABCCAABABCCCCCAA z?00000010000001111000 P. 281 - 282
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5 - 9 Chapter 6 Analysis of Sequential Systems 6.2 Latches Latch Binary storage device composed of two or more gates with feedback. Simple example Simplest two NOR gates latch The output of each gate is connected to the input of the other gate. Equations for this system P = ( S + Q )’ Q = ( R + P )’ P. 282
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5 - 10 Chapter 6 Analysis of Sequential Systems 6.2 Latches Latch Simple example Equations for this system S = 0, R = 0 P = Q’, Q = P’ Store 0 (Q = 0 and P = 1) or store 1 (Q = 1 and P = 0) S is used to indicate ‘set’, store a 1 in the latch S = 1, R = 0 P = (1 + Q)’ = 1’ = 0 Q = (0 + 0)’ = 0’ = 1 R is used to indicate ‘reset’, store a 0 in the latch S = 0, R = 1 Q = (1 + P)’ = 1’ = 0 P = (0 + 0)’ = 0’ = 1
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5 - 11 Chapter 6 Analysis of Sequential Systems 6.2 Latches Latch Simple example Equations for this system S = 1, R = 1 : not operated P = (1 + Q)’ = 1’ = 0 Q = (1 + P)’ = 1’ = 0
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5 - 12 Chapter 6 Analysis of Sequential Systems 6.2 Latches Gated Latch Gate signal is inactive ( = 0 ) SG, RG are both 0. Latch remains unchanged. Gate signal is active ( = 1 ) Latch stores 0 or 1. P. 283
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5 - 13 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops Flip Flop Clocked binary storage device Flip Flop stores a 0 or a 1. Trailing-edge Triggered Change FF state when the clock goes from 1 to 0. Leading-edge Triggered Change FF state when the clock goes from 0 to 1. Various Types of Flip Flops D Flip Flop JK Flip Flop SR Flip Flop T Flip Flop
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5 - 14 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop The output is just the input delayed until the next active clock transition. Block Diagram D q q’ D q Clock Trailing-edge Triggered Leading-edge Triggered P. 284
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5 - 15 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop Two forms of a truth table State Diagram Dqq* 000 010 101 111 D 00 11 P. 284
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5 - 16 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop Timing Diagram Trailing-edge triggered D FF Result in (b) will be same as (a) (a) (b) P. 285
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5 - 17 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop Timing Diagram Leading-edge triggered D FF P. 286
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5 - 18 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop Two Flip Flops P. 286 - 287
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5 - 19 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop Preset and Reset P. 287
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5 - 20 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops D Flip Flop Preset and Reset P. 288
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5 - 21 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops SR(Set-Reset) Flip Flop Behavioral Tables SR Flip Flop State Diagram P. 288
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5 - 22 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops SR(Set-Reset) Flip Flop Behavioral Map q* = S + R’q Timing Diagram q* P. 289
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5 - 23 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops T(Toggle) Flip Flop T = 1, TFF changes state (Toggled). T = 0, TFF state remains same. Behavioral Table State Diagram Tqq* 000 011 101 110 T 0q 1q` P. 289
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5 - 24 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops T(Toggle) Flip Flop Behavioral Equation q* = T q Timing Diagram P. 290
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5 - 25 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops JK Flip Flop Combination of SR and T J = K = 1, FF changes state. Behavioral Table State Diagram P. 290
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5 - 26 Chapter 6 Analysis of Sequential Systems 6.3 Flip Flops JK Flip Flop Behavioral Equation q* = Jq’ + K’q Timing Diagram P. 291
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5 - 27 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems D Flip Flop Moore Model(1) Circuit Equation D 1 = q 1 q 2 ’ + xq 1 ’ D 2 = xq 1 z = q 2 ’ P. 292
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5 - 28 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems D Flip Flop Moore Model(2) State Table Partial State Table Complete State Table Moore State Diagram P. 293
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5 - 29 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Moore Model(1) Circuit Equation J A = x K A = xB’ J B = K b = x + A’ z = A + B P. 293
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5 - 30 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Moore Model(2) State Table First two entries A* entered Complete State Table P. 294
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5 - 31 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Moore Model(3) State Table using Equation q* = Jq’ + K’q A* = J A A’ + K A ’A = xA’ + (xB’)A = xA’ + x’A + AB B* = J B B’ + K B ’B = (x + A’)B’ + (x + A’)’B = xB’ + A’B’ + x’AB State table can be constructed with D flip flops. These equations give exactly the same results as before. Trace Table P. 295
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5 - 32 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Moore Model(4) Timing Diagram P. 296
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5 - 33 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Moore Model(5) State Diagram P. 296
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5 - 34 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Mealy Model(1) Circuit Equations D 1 = xq 1 + xq 2 D 2 = xq 1 ’q 2 ’ z = xq 1 q 1 * = xq 1 + xq 2 q 2 * = xq 1 ’q 2 ’ P. 297
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5 - 35 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Mealy Model(2) State Table State Diagram P. 297 - 298
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5 - 36 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Mealy Model(3) Mealy Modeling Timing P. 298
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5 - 37 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems JK Flip Flop Mealy Model(4) Timing Diagram P. 299
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5 - 38 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems Circuit Moore model Output z does not depend on the input x z = q 1 q 2 Example 6.1a(1) P. 299
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5 - 39 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems Equations J 1 = xq 2, K 1 = x’ D 2 = x(q 1 +q 2 ’) When x = 0, J 1 = 0, K 1 = 1, and D 2 = 0, thus system state is 00 When x = 1 J 1 = q 2, K 1 = 0, D 2 = q 1 + q 2 ’ q 1 * = xq 1 ’q 2 + xq 1 = x(q 1 + q 2 ) State Table Example 6.1a(2) P. 300
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5 - 40 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems Timing Diagram Example 6.1a(3) P. 300
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5 - 41 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems z = x’q 1 q 2 This machine is a Mealy model. State Diagram Example 6.1b P. 299, 301
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5 - 42 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems Assume initial state is 0000 J 1 = K 1 = xq 4 T 2 = q 1 ’ S 3 = q 2 ’, R 3 = q 2 D 4 = q 3 Example 6.2 P. 301
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5 - 43 Chapter 6 Analysis of Sequential Systems 6.4 Analysis of Sequential Systems q 1 : changes state only when xq 4 = 1 q 2 : changes state only when q 1 = 0 q 3 * = q 2 ’ q 4 * = q 3 Example 6.2 (cont.) x111011 q1q1 000110000 q2q2 0101110101 q3q3 01010001010 q4q4 001010001010 P. 302
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