COE 405 Logic Design with Behavioral Models of Combinational & Sequential Logic
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Transcript of Chapter 4 Combinational Logic. 4.1 Introduction Logic circuits for digital systems may be...
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Chapter 4
Combinational Logic
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4.1 Introduction
Logic circuits for digital systems may becombinational or sequential.
A combinational circuit consists of logic gateswhose outputsat anytime are determined
from only the present combinationof inputs.
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4.2 Combinational Circuits
Logic circuits for digital system Sequential circuits
contain memory elements
the outputs are a function of the current inputs and thestate of the memory elements
the outputs also depend on past inputs
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A combinational circuits 2possible combinations of input valuesn
Combination
al circuitsCombinatixnalxoxic Circuit
n inputm outputvariablesvariables
4
Specific functions
Adders, subtractors, comparators, decoders, encoders,andmultiplexers
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4-3 Analysis Procedure
A combinational circuit
make sure that it is combinational not sequential
No feedback path
derive its Boolean functions (truth table)
designverification
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A straight-forward procedure
=AB+AC+BCF2
T1
=A+B+C
6
1TT
2
3
1
=ABC =F2'T1
=T3+T2F
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F 13221
) =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
=T +T =F 'T +ABC
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The truth table
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4-4 Design Procedure
The design procedure ofcombinational circuits
State the problem (system spec.)
determine the inputs and outputs
the inputand output variables are assigned symbols
derivethe truth table
x erive the simplified Bool xan functionx
draw the logic diagram and verify the correctness
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derive the simplifi edb oolean functions
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code conversion example
BCD to excess-3 code Thetruth table
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The maps
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The simplified functions z = D'
y = CD +C'D‘
x = B'C + B‘D+BC'D'
w = A+BC+BD
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
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Another implementation
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The logic diagram
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4-5Binary Adder-Subtractor
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
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S = x'y+xy'
C = xy
the flexibility for implementation
S=xÅy
S = (x+y)(x'+y')
S = (C+x'y')'
C = xy = (x'+y')x
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S‘= xy+x'y'
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17Functional Block: Full-Adder
A full adder is similar to a half adder, but includes a carry-in bit from lower stages. Like the half-adder, it computes a sum bit, S and a carry bit, C.
For a carry-in (Z) of 0, it is the same as the half-adder:
For a carry- in(Z) of 1:
Z 0 0 0 0X 0 0 1 1 +Y +0 +1 +0 +1
C S 0 0 0 1 0 1 1 0
Z 1 1 1 1X 0 0 1 1 +Y +0 +1 +0 +1
C S 0 1 1 0 1 0 1 1
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Full-Adder
the arithmetic sum of three inputbits
three input bits
x, y: two significant bits
z: the carrybit from the previous lower significant bit
Two outputbits: C, S
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S = x'y'z+x'yz'+ xy'z'+xyz
C = xy + xz + yz
S = zÅ (xÅy)
= z'(xy'+x‘y)+z(xy'+x'y)'
= z‘xy'+z'x'y+z(xy+x‘y')
= xy'z'+x'yz'+xyz+x'y'z
C = z(xy'+x'y)+xy
= xy'z+x'yz+ xy
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Binary adder
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Binary subtractor
A-B = A+(2’s complement of B)4-bit Adder-subtractor
M=0, A+B; M=1, A+B’+1
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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
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Example:
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4-6 Decimal Adder
Add twoBCD's
9 inputs: two BCD's and one carry-in5 outputs: one BCD and one carry-out
Design approaches
A truth table with 2^9 entriesthe sum <= 9 + 9 + 1 = 19
binary to BCD
useuinary full Adders
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BCD Adder: The truth Table25
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Modifications are needed if the sum > 9C = 1
K = 1
Z
Z84Z =1
=18 2Z
moxification: - (10) dor +6 modification: -(10)dor +6
C = K +Z Z + Z Z8 4 8 2
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Block diagram27
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Binary Multiplier
Partial products
–AND operations
fig. 4.15Two-bit by two-bit binary multiplier.
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4-bit by 3-bit binary multiplier
Digital Circuits
Fig. 4.16Four-bit by three-bit binary
multiplier.
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4-9 Decoder
A n-to-m decodera binary code of n bits = 2 distinct information
n
n input variables; up to 2 output linesonly one output can be active )high( at any time
n
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An implementation
Digital Circuits 38
Fig. 4.18Three-to-eight-line decoder.
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Combinational logic implementation
each output = a mintermuse a decoder and an external OR gate toimplement any Boolean function of n input
variables
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Demultiplexers
a decoder with an enable input
receive information in a single line and transmitsit in one of 2 possible output lines
n
Fig. 4.19Two-to-four-line decoder with enable input
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Decoder Examples
D0 = m0 = A2’A1’A0’
D1= m1 = A2’A1’A0
…etc
3-to-8-Line Decoder: example: Binary-to-octal conversion.
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Expansion two 3-to-8 decoder: a 4-to-16 deocder
a 5-to-32 decoder?
Fig. 4.204 16 decoder
constructed with two3 x 8 decoders
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Decoder Expansion - Example 2 Construct a 5-to-32-line decoder using four 3-8-line
decoders with enable inputs and a 2-to-4-line decoder.
D0 – D7
D8 – D15
D16 – D23
D24 – D31
A3
A4
A0
A1
A2
2-4-line Decoder
3-8-line Decoder
3-8-line Decoder
3-8-line Decoder
3-8-line Decoder
E
E
E
E
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Combination Logic Implementation
each output = a mintermuse a decoder and an external OR gate toimplement any Boolean function of n inputvariables
A full-adder
S)x,y,z(=S)1,2,4,7(C)x,y,z(= S (3,5,6,7)C)x,y,z(= S (3,5,6,7)
Fig. 4.21Implementation of a full adder with 1 decoder
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two possible approaches using decoder
OR(minterms of F): k inputs
NOR(minterms of F'): 2 - k inputs
In general, it is not a practical implementation
n
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4-10 Encoders
The inverse function of decodera decoder
1357
2367
4567
z D D D D
y D D D D
x D D D D
=
=
=
+ + +
+ + +
+ + +
The encoder can be implementedwith three OR gates.
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An implementation
limitations
illegal input: e.g. D 36
The output = 111 (¹3 and ¹6)=D x1
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Priority Encoder
resolve the ambiguity of illegal inputsonly one of theinput is encoded
DD
3
0
X: don't-care conditionsV: valid output indicator
has the highest priorityhas the lowest priority
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■ The maps for simplifying outputs x and y
fig. 4.22Maps for a priority encoder
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■ Implementation of priority
Fig. 4.23Four-input priority encoder
23
0123
x =y=
D D
D D D
V D D D D
+¢+
= + + +
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3 1 2
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4-11 Multiplexers
select binary information from one of many inputlines and direct it to a single output line
2 input lines, n selection lines and one output line
e.g.: 2-to-1-line multiplexer
n
Fig. 4.24Two-to-one-line multiplexer
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4-to-1-line multiplexer
Fig. 4.25Four-to-one-line multiplexer
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Note
n-to- 2 decodern
add the 2 input lines to each AND gateOR(all AND gates)
an enable input (an option)
n
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Fig. 4.26Quadruple two-to-one-line multiplexer
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Boolean function implementation
MUX: a decoders an OR gate
2 -to-1 MUX can implement any Boolean functionof n input variable
n
n of these variables: the selection lines
the remaining variable: the inputs
a better solution: implement any Boolean function
of n+1 input variable
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an example: F(A,B,C) = S(1,2,6,7)
Fig. 4.27Implementing a Boolean function with a multiplexer
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procedure:
assign an ordering sequence of the input variablethe rightmost variable (D) will be used for the inputlinesassign the remaining n-1 variables to the selection
0
determine the input lines
lines w.r.t. their corresponding sequ
consider a pair of consecutive minterms startingfrom m
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Lines with construct the truth table
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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
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Three-state gates
A multiplexer can be constructed with three-stategatesOutput state: 0, 1, and high-impedance (open ckts)
Fig. 4.29Graphic symbol for a three-state buffer
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Example: Four-to-one-line multiplexer
Fig. 4.30Multiplexer with three-state gates
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