Digital System

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Transcript Digital System 

Digital System
數位系統
Chapter 4
Combinational Logic
Ping-Liang Lai (賴秉樑)
Digital System Ch4-1
Outline of Chapter 4
 4.1 Introduction
 4.2 Combination Circuits
 4.3 Analysis Procedure
 4.4 Design Procedure
 4.5 Binary Adder-Subtractor
 4.6 Decimal Adder
 4.7 Binary Multiplier
 4.8 Magnitude Comparator
 4.9 Decoders
 4.10 Encoders
 4.11 Multiplexers
 4.12 HDL Models of Combination Circuits
Digital System Ch4-2
4.1 Introduction (p.138)
 Logic circuits for digital systems may be combinational or
sequential.
 A combinational circuit consists of logic gates whose outputs at
any time are determined from only the present combination of
inputs.
Digital System Ch4-3
4.2 Combinational Circuits (p.138)
 Logic circuits for digital system

Sequential circuits
Contain memory elements.
» The outputs are a function of the current inputs and the state of the memory
elements.
» The outputs also depend on past inputs.
»
Digital System Ch4-4
Combinational Circuits (p.139)
 A combinational circuits

n
2 possible combinations of input values
Combinational
Logic Circuit
…..
…..
n input
variables
m output
variables
Figure 4.1 Block diagram of combinational circuit

Specific functions
Adders, subtractors, comparators, decoders, encoders, and multiplexers.
» MSI circuits or standard cells.
»
Digital System Ch4-5
4-3 Analysis Procedure (p.139)
 A combinational circuit

Make sure that it is combinational not sequential
»



No feedback path.
Derive its Boolean functions (truth table)
Design verification
A verbal explanation of its function
Digital System Ch4-6
A Straight-forward Procedure (p.140)
F2
T1
T2
T3
F1
= AB+AC+BC
= A+B+C
= ABC
= F2'T1
= T3+T2
Figure 4.2 Logic Diagram for Analysis Example
Digital System Ch4-7
 F1 = T3+T2 = F2'T1+ABC = (AB + AC + BC)'(A + B + C) + ABC
= (A' + B')(A' + C')(B' + C')(A + B + C) + ABC = (A' + B'C')
(AB' + AC' + BC' + B'C) + ABC = A'BC' + A'B'C + AB'C' +
ABC
 A full-adder


F1: the sum
F2: the carry
Digital System Ch4-8
The Full-adder
 The truth table
Digital System Ch4-9
4-4 Design Procedure (p.142)
 The design procedure of combinational circuits






State the problem (system spec.)
Determine the inputs and outputs
The input and output variables are assigned symbols
Derive the truth table
Derive the simplified Boolean functions
Draw the logic diagram and verify the correctness
Digital System Ch4-10
Design Procedure
 Functional description


Boolean function
HDL (Hardware description language)
Verilog HDL
» VHDL
»

Schematic entry
 Logic minimization





Number of gates
Number of inputs to a gate
Propagation delay
Number of interconnection
Limitations of the driving capabilities
Digital System Ch4-11
Code Conversion Example (p.143)
 BCD to excess-3 code

The truth table
Digital System Ch4-12
The Maps (p.144)
Figure 4.3 Maps for BCE to Excess-3 Code Converter
Digital System Ch4-13
(p.145)
 The simplified functions




z = D'
y = CD +C'D'
x = B'C + B'D+BC'D'
w = A+BC+BD
 Another implementation




z = D'
y = CD +C'D' = CD + (C+D)'
x = B'C + B'D+BC'D' = B'(C+D) +B(C+D)'
w = A+BC+BD
Digital System Ch4-14
BCD to Excess-3
 The logic diagram
z = D'
y = CD +C'D' = CD +
(C+D)'
x = B'C + B'D+BC'D' =
B'(C+D) +B(C+D)‘
w = A+BC+BD
Fig. 4-4 Logic Diagram for BCD to Excess-3 Code Converter
Digital System Ch4-15
4-5 Binary Adder-Subtractor (p.146)
 Half adder




0 + 0 = 0 ; 0 + 1 = 1 ; 1 + 0 = 1 ; 1 + 1 = 10
Two input variables: x, y
Two output variables: C (carry), S (sum)
Truth table
Digital System Ch4-16
Half Adder


S = x'y+xy'
C = xy
 The flexibility for implementation





S = xy
S = (x+y)(x'+y')
S' = xy+x'y'
S = (C+x'y')'
C = xy = (x'+y')'
Digital System Ch4-17
Figure 4.5 Implementation of Half-Adder
Digital System Ch4-18
Full-Adder (p.147)
 Full-Adder


The arithmetic sum of three input
bits.
Three input bits
x, y: two significant bits.
» z: the carry bit from the previous
lower significant bit.
»

Two output bits: C, S
Digital System Ch4-19
Full-Adder
C
S
Fig. 4-6 Map for Full Adder
Fig. 4-7 Implementation of Full Adder in Sum of Products
Digital System Ch4-20
Full-Adder




S = x'y'z+x'yz'+ xy'z'+xyz
C = xy+xz+yz
S = z(xy) = z'(xy'+x'y)+z(xy'+x'y)'= z'xy'+z'x'y+z((x'+y)(x+y')) =
xy'z'+x'yz'+xyz+x'y'z
C = z(xy'+x'y)+xy = xy'z+x'yz+ xy
Fig. 4-8 Implementation of Full Adder with Two Half Adders and an OR Gate
Digital System Ch4-21
Binary Adder (p.149)
Figure 4.9 Full-bit adder
Digital System Ch4-22
 Carry propagation




When the correct outputs are available
The critical path counts (the worst case)
(A1, B1, C1) → C2 → C3 → C4 → (C5, S4)
When 4-bits full-adder → 8 gate levels (n-bits: 2n gate levels)
Figure 4.10 Full Adder with P and G Shown
Digital System Ch4-23
Parallel Adders
 Reduce the carry propagation delay
 Employ faster gates
 Look-ahead carry (more complex mechanism, yet faster)
 Carry propagate: Pi = AiBi
 Carry generate: Gi = AiBi
 Sum: Si = PiCi
 Carry: Ci+1 = Gi+PiCi
 C0 = Input carry
 C1 = G0+P0C0
 C2 = G1+P1C1 = G1+P1(G0+P0C0) = G1+P1G0+P1P0C0
 C3 = G2+P2C2 = G2+P2G1+P2P1G0+ P2P1P0C0
Digital System Ch4-24
Carry Look-ahead Adder (1/2)
 Logic diagram
Fig. 4.11 Logic Diagram of Carry Look-ahead Generator
Digital System Ch4-25
Carry Look-ahead Adder (2/2)
 4-bit carry-look ahead
adder

Propagation delay of C3, C2
and C1 are equal.
Fig. 4.12 4-Bit Adder with Carry Digital
Look-ahead
System Ch4-26
Binary Subtractor
 A-B = A+(2’s complement of B)
 4-bit Adder-subtractor

M=0, A+B; M=1, A+(B’+1)
Fig. 4.13 4-Bit Adder Subtractor
Digital System Ch4-27
 Overflow




The storage is limited
Add two positive numbers and obtain a negative number
Add two negative numbers and obtain a positive number
V = 0, no overflow; V = 1, overflow
 Example:
Digital System Ch4-28
4-6 Decimal Adder
 Add two BCD's


9 inputs: two BCD's and one carry-in
5 outputs: one BCD and one carry-out
 Design approaches


A truth table with 29 entries
Use binary full Adders
The maximum sum ← 9 + 9 + 1 = 19
» Binary to BCD
»
Digital System Ch4-29
BCD Adder (1/3)
 BCD Adder: The truth table
Digital System Ch4-30
BCD Adder (2/3)
 Modifications are needed if the sum > 9

If C = 1, then sum > 9
K = 1, or
» Z8Z4 = 1 (11××), or
» Z8Z2 = 1 (1×1×).
»

Modification: (10)d or + 6
C = K +Z8Z4 + Z8Z2
Digital System Ch4-31
BCD Adder (3/3)
 Block diagram
Fig. 4-14 Block Diagram of a BCD AdderDigital System Ch4-32
Binary Multiplier (1/2)
 Partial products

AND operations
Fig. 4.15 Two-bit by two-bit binary multiplier
Digital System Ch4-33
Binary Multiplier (2/2)
 4-bit by 3-bit binary multiplier
Fig. 4.16 Four-bit by three-bit binary
multiplier
Digital System Ch4-34
4-8 Magnitude Comparator
 The comparison of two numbers

Outputs: A>B, A=B, A<B
 Design Approaches

The truth table of 2n-bit comparator
2n
»

2 entries - too cumbersome for large n
Use inherent regularity of the problem
Reduce design efforts
» Reduce human errors
»
Digital System Ch4-35
 Algorithm → logic


A = A3A2A1A0 ; B = B3B2B1B0
A=B if A3=B3, A2=B2, A1=B1 and A1=B1
Equality: xi= AiBi+Ai'Bi'
» (A=B) = x3x2x1x0=1
»


(A>B) = A3B3'+x3A2B2'+x3x2A1B1'+x3x2x1 A0B0'
(A<B) = A3'B3+x3A2'B2+x3x2A1'B1+x3x2x1 A0'B0
 Implementation

xi = (AiBi'+Ai'Bi)'
Digital System Ch4-36
Fig. 4.17 Four-bit magnitude comparator.
Digital System Ch4-37
4-9 Decoder
 A n-to-m decoder



n
A binary code of n bits = 2 distinct information
n
N input variables; up to 2 output lines
Only one output can be active (high) at any time
Digital System Ch4-38
 An implementation
Fig. 4.18 Three-to-eight-line decoder
Digital System Ch4-39
 Combinational logic implementation


Each output = a minterm.
Use a decoder and an external OR gate to implement any Boolean function
of n input variables.
Digital System Ch4-40
 Demultiplexers


A decoder with an enable input.
n
Receive information on a single line and transmits it on one of 2 possible
output lines.
Fig. 4.19 Two-to-four-line decoder with enable input
Digital System Ch4-41
 Decoder/demultiplexers
第三版內容,參考用!
Digital System Ch4-42
 Expansion

Two 3-to-8 decoder: a 4-to-16 decoder
Fig. 4.20 4  16 decoder constructed with two 3  8 decoders Digital System Ch4-43
Combination Logic Implementation
 Each
output = a minterm
 Use a decoder and an external OR gate to implement any Boolean function
of n input variables
 A full-adder
S(x, y, z) = S(1,2,4,7)
» C(x, y, z) = S(3,5,6,7)
»
Fig. 4.21 Implementation of a full adder with a decoder
Digital System Ch4-44

Two possible approaches using decoder
OR(minterms of F): k inputs (k minterms)
n
» NOR(minterms of F'): 2  k inputs
»

In general, it is not a practical implementation
Digital System Ch4-45
4-10 Encoders
 The inverse function of a decoder
z  D1  D3  D5  D7
y  D2  D3  D6  D7
x  D4  D5  D6  D7
The encoder can be implemented
with three OR gates.
Digital System Ch4-46
 An implementation

Limitations
第三版內容,參考用!
Illegal input: e.g. D3=D6=1
» The output = 111 (¹3 and ¹6)
»
Digital System Ch4-47
Priority Encoder






Resolve the ambiguity of illegal inputs
Only one of the input is encoded
D3 has the highest priority
D0 has the lowest priority
X: don't-care conditions
V: valid output indicator
Digital System Ch4-48
 The maps for simplifying outputs x and y
Fig. 4.22 Maps for a priority encoder
Digital System Ch4-49
 Implementation of priority
Fig. 4.23 Four-input priority encoder
x  D2  D3
y  D3  D1D2
V  D0  D1  D2  D3
Digital System Ch4-50
4-11 Multiplexers



Select binary information from one of many input lines and direct it to a
single output line
n
2 input lines, n selection lines and one output line
e.g.: 2-to-1-line multiplexer
Fig. 4.24 Two-to-one-line multiplexer
Digital System Ch4-51

4-to-1 line multiplexer
Fig. 4.25 Four-to-one-line multiplexer
Digital System Ch4-52
 Note: 2n-to-1 multiplexer





n
n-to- 2 decoder
n
Add the 2 input lines to each AND gate
OR (all AND gates)
n selection lines
An enable input (an option)
Digital System Ch4-53
Fig. 4.26 Quadruple two-to-one-line multiplexer
Digital System Ch4-54
Boolean Function Implementation



MUX: a decoder + an OR gate
n
2 -to-1 MUX can implement any Boolean function of n input variable
A better solution: implement any Boolean function of n+1 input variable
n of these variables: the selection lines
» The remaining variable: the inputs
»
Digital System Ch4-55
 An example: F(A, B, C) = S(1, 2, 6, 7)
Fig. 4.27 Implementing a Boolean function with a multiplexer
Digital System Ch4-56
 Procedure:






Assign an ordering sequence of the input variable
The rightmost variable (D) will be used for the input lines
Assign the remaining n-1 variables to the selection lines w.r.t. their
corresponding sequence
Construct the truth table
Consider a pair of consecutive minterms starting from m0
Determine the input lines
Digital System Ch4-57
 Example: F(A, B, C, D) = S(1, 3, 4, 11, 12, 13, 14, 15)
Fig. 4.28 Implementing a four-input function with a multiplexer
Digital System Ch4-58
Three-state Gates


A multiplexer can be constructed with three-state gates
Output state: 0, 1, and high-impedance (open ckts)
Fig. 4.29 Graphic symbol for a three-state buffer
Digital System Ch4-59
Example: Four-to-one-line multiplexer
Fig. 4.30 Multiplexer with three-state gates
Digital System Ch4-60
4-12 HDL Models of Combinational Circuits
 Modeling Styles



Gate-level modeling using instantiations of predefined and user-defined
primitive gates.
Dataflow modeling using continuous assignment statements with the
keyword assign.
Behavioral modeling using procedural assignment statements with the
keyword always.
Digital System Ch4-61
Gate-level Modeling
 The four-valued logic truth tables for the and, or, xor, and not
primitives
Digital System Ch4-62
Gate-level Modeling
 Example:
output [0: 3] D;
wire [7: 0] SUM;
 The first statement declares an output vector D with four bits, 0
through 3.
 The second declares a wire vector SUM with eight bits numbered
7 through 0.
Digital System Ch4-63
HDL Example 4-1
 Two-to-one-line decoder
Digital System Ch4-64
HDL Example 4-2
 Four-bit adder: bottom-up hierarchical description
Digital System Ch4-65
HDL Example 4-2 (continued)
Digital System Ch4-66
Three-State Gates
 Statement: gate name (output, input, control);
Fig. 4.31 Three-state gates
Digital System Ch4-67
Three-State Gates
 Examples of gate instantiation
Digital System Ch4-68
Fig. 4.32 Two-to-one-line multiplexer with three-state buffers
Dataflow Modeling
 Verilog HDL operators
Example:
assign Y = (A & S) | (B & ~S)
Digital System Ch4-70
HDL Example 4.3
 Dataflow description of a 2-to-4-line decoder
Digital System Ch4-71
HDL Example 4-4
 Dataflow description of 4-bit adder
Digital System Ch4-72
HDL Example 4-5
 Dataflow description of 4-bit magnitude comparator
Digital System Ch4-73
HDL Example 4-6
 Dataflow description of a 2-to-1-line multiplexer
 Conditional operator (?:)
Condition ? True-expression : false-expression
Example: continuous assignment
assign OUT = select ? A : B
Digital System Ch4-74
 if statement:

if (select) OUT = A;
 HDL Example 4-7

Behavioral description of a 2-to-1-line multiplexer
Digital System Ch4-75
HDL Example 4-8
 Behavioral description of a 4-to-1-line multiplexer
Digital System Ch4-76
Writing a Simple Test Bench
 Initial block
Three-bit truth table
Digital System Ch4-77
Writing a Simple Test Bench
 Interaction between stimulus and design modules
Digital System Ch4-78
Writing a Simple Test Bench
 Stimulus module
 System tasks for display
Digital System Ch4-79
 Syntax for $dispaly, $write, and $monitor:
 Example:
 Example:
Digital System Ch4-80
HDL Example 4-9
 Stimulus module
Digital System Ch4-81
HDL Example 4-9 (Continued)
Digital System Ch4-82
HDL Example 4-10
 Gate-level description of a full adder
Digital System Ch4-83
HDL Example 4-10 (Continued)
Digital System Ch4-84