JM38510/34201BEA National Semiconductor, JM38510/34201BEA Datasheet - Page 2

JM38510/34201BEA

Manufacturer Part Number

JM38510/34201BEA

Description

Manufacturer

National Semiconductor

Datasheet

1.JM3851034201BEA.pdf (10 pages)

Specifications of JM38510/34201BEA

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Functional Description

The ’F283 adds two 4-bit binary words (A plus B) plus the

incoming Carry (C

of the various inputs and outputs is indicated by the sub-

script numbers representing powers of two

Interchanging inputs of equal weight does not affect the op-

eration Thus C

5 6 and 7 for DIPS and 7 8 and 9 for chip carrier packages

Due to the symmetry of the binary add function the ’F283

can be used either with all inputs and outputs active HIGH

(positive logic) or with all inputs and outputs active LOW

(negative logic) See Figure 1 Note that if C

must be tied LOW for active HIGH logic or tied HIGH for

active LOW logic

Due to pin limitations the intermediate carries of the ’F283

are not brought out for use as inputs or outputs However

Pin Names

–S

–A

–B

–S

) and outgoing carry (C

Active HIGH 0

Logic Levels

Active HIGH

Active LOW

) The binary sum appears on the Sum

Where (

A Operand Inputs

B Operand Inputs

Carry Input

Sum Outputs

Carry Output

Description

can be arbitrarily assigned to pins

)

) outputs The binary weight

FIGURE 1 Active HIGH versus Active LOW Interpretation

plus

16C

Active LOW 1

HIGH LOW

)

is not used it

50 33 3

)

1 0 2 0

1 0 1 0

U L

54F 74F

20 A

Output I

Input I

1 mA 20 mA

Figure 5 shows one method of implementing a 5-input ma-

other means can be used to effectively insert a carry into or

bring a carry out from an intermediate stage Figure 2

shows how to make a 3-bit adder Tying the operand inputs

of the fourth adder (A

on and equal to the carry from the third adder Using some-

what the same principle Figure 3 shows a way of dividing

the ’F283 into a 2-bit and a 1-bit adder The third stage

adder (A

carry (C

bringing out the carry from the second stage on S

that as long as A

LOW they do not influence S

are the same the carry into the third stage does not influ-

ence the carry out of the third stage Figure 4 shows a meth-

od of implementing a 5-input encoder where the inputs are

equally weighted The outputs S

ry number equal to the number of inputs I

jority gate When three or more of the inputs I

the output M

1 2 mA

0 6 mA

) signal into the fourth stage (via A

is true

) is used merely as a means of getting a

and B

) LOW makes S

are the same whether HIGH or

Similarly when A

and S

–I

dependent only

present a bina-

that are true

and B

–I

are true

and B

) and

Note

JM38510/34201BEA National Semiconductor, JM38510/34201BEA Datasheet - Page 2

JM38510/34201BEA

Specifications of JM38510/34201BEA

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