Binary Coded Decimal.pptx
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Binary Coded Decimal
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1 Binary Coded Decimal COMPUTER ARITHMETIC
2 Binary Coded Decimal Introduction: Although binary data is the most efficient storage scheme; every bit pattern represents a unique, valid value. However, some applications may not be desirable to work with binary data. For instance, the internal components of digital clocks keep track of the time in binary. The binary value must be converted to decimal before it can be displayed.
3 Binary Coded Decimal Because a digital clock is preferable to store the value as a series of decimal digits, where each digit is separately represented as its binary equivalent, the most common format used to represent decimal data is called binary coded decimal , or BCD .
4 The BCD format Algorithms for addition Algorithms for subtraction Algorithms for multiplication Algorithms for division Explanation of Binary Coded Decimal (BCD):
5 1) BCD Numeric Format Every four bits represent one decimal digit. Use decimal values from to 9
6 4-bit values above 9 are not used in BCD. 1) BCD Numeric Format The unused 4-bit values are: BCD Decimal 1010 10 1011 11 1100 12 1101 13 1110 14 1111 15
7 1) BCD Numeric Format Multi-digit decimal numbers are stored as multiple groups of 4 bits per digit.
8 1) BCD Numeric Format BCD is a signed notation positive or negative. For example, +27 as 0(sign) 0010 0111. -27 as 1(sign) 0010 0111. BCD does not store negative numbers in two’s complement.
9 1) BCD Numeric Format Values represented b 3 b 2 b 1 b Sign and magnitude 1’s complement 2’s complement 0111 +7 +7 +7 0110 +6 +6 +6 0101 +5 +5 +5 0100 +4 +4 +4 0011 +3 +3 +3 0010 +2 +2 +2 0001 +1 +1 +1 0000 +0 +0 +0 1000 -0 -7 -8 1001 -1 -6 -7 1010 -2 -5 -6 1011 -3 -4 -5 1100 -4 -3 -4 1101 -5 -2 -3 1110 -6 -1 -2 1111 -7 -0 -1
10 2) Algorithms for Addition 1100 is not used in BCD.
11 2) Algorithms for Addition Two errors will occurs in a standard binary adder. The result is not a valid BCD digit. A valid BCD digit, but not the correct result. Solution: You need to add 6 to the result generated by a binary adder.
12 2) Algorithms for Addition A simple example of addition in BCD. 0101 + 1001 1110 + 0110 1 0100 5 + 9 Incorrect BCD digit Add 6 Correct answer 1 4
13 2) Algorithms for Addition A BCD adder 1001 0101 0001 = 1 0100 = 4 If the result, S 3 S 2 S 1 S , is not a valid BCD digit, the multiplexer causes 6 to be added to the result.
14 A simple example of subtraction 3) Algorithms for Subtraction 0111 + 1101 0100 (+7) (- 3) (+4) 0011 is 3, the one’s complement is 1100 . Each of the computations adds 1 to the one’s complement to produce the two’s complement of the number. 1100 + 1 = 1101 The two’s complement of 3 is 1101
15 3) Algorithms for Subtraction The second change has to do with complements. The nine’s complement in BCD , generated by subtracting the value to be complemented from another value that has all 9 S as its digits. Adding one to this value produces the ten’s complement, the negative of the original value. e.g, the nine’s complement of 631 is 999 – 631 = 368. 368 + 1 = 369 is the ten’s complement
16 The ten’s complement plays the subtraction and negation for BCD numbers. 3) Algorithms for Subtraction Hareware generates the nine’s complement of a single BCD digit.
17 Conclusion for addition and subtraction Using a BCD adder and Nine’s complement generation hardware to compute the addition and the subtraction for signed-magnitude binary numbers The algorithm for adding and subtracting as below: PM’ 1 : U S X S , CU X + Y PM 1 : CU X + Y’ + 1, OVERFLOW 0 PM’ 2 : OVERFLOW C
18 The algorithm for adding and subtracting CZ’PM 2 : U S X S CZPM 2 : U S C’PM 2 : U S X’ S, U U’ + 1 2 : FINISH 1
19 Example of addition of BCD numbers U S U = X S X + Y S Y X S X = +33 = 0 0011 0011 Y S Y = +25 = 0 0010 0101 PM’ 1 : U S 0, CU 0 0101 1000 PM’2: OVERFLOW 0 Result: U S U = 0 0101 1000 = +58
20 Example of subtraction of BCD numbers U S U = X S X + Y S Y X S X = +27 = 0 0010 0111 Y S Y = -13 = 1 0001 0011 PM1: CU 1 0001 0100, OVERFLOW 0 CZ’PM2: U S Result: U S U = 0 0001 0100 = +14
21 4) Algorithms for Multiplication 1101 Multiplicand M X 1011 Multiplier Q 1101 1101 0000 1101____ 10001111 Product P
22 4) Algorithms for Multiplication Multiplicand Multiplier Product
23 4) Algorithms for Multiplication Required to use the BCD adder and nine’s complement circuitry. In BCD, each digit of the multiplicand may have any value from 0 to 9; each iteration of the loop may have to perform up to nine additions. We must incorporate an inner loop in the algorithm for these multiple additions. In addition, use decimal shifts right operation (dshr), which shift one BCD digit, or four bits at a time.
24 The BCD multiplication algorithm 1 : U S X S +Y S, V S X S +Y S , U 0, i n, C d Z Y0 ’ 2 : C S U C d U + X, Y d0 Y d0 – 1, GOTO 2 Z Y0 2 : i i - 1 3 : dshr (C d UV), dshr (Y) Z’ 3 : GOTO 2 ZT 3 : U S 0, V S Z 3 : FINISH 1 4) Algorithms for Multiplication
25 4) Algorithms for Multiplication
26 Division can be implemented using either a restoring or a non-restoring algorithm . An inner loop to perform multiple subtractions must be incorporated into the algorithm. 5) Algorithms for Division 10 11 ) 1000 11_ 10
27 5) Algorithms for Division A logic circuit arrangement implements the restoring-division technique
28 A restoring-division example Initially 0 0 0 0 0 1 0 0 0 0 0 0 1 1 Shift 0 0 0 0 1 0 0 0 Subtract 1 1 1 0 1 Set q 1 1 1 1 0 Restore 1 1 0 0 0 0 1 0 0 0 Shift 0 0 0 1 0 0 0 0 Subtract 1 1 1 0 1 Set q 1 1 1 1 1 Restore 1 1 0 0 0 1 0 0 0 0 Shift 0 0 1 0 0 0 0 0 Subtract 1 1 1 0 1 Set q 0 0 1 0 0 0 0 1 Shift 0 0 0 1 0 0 0 1 Subtract 1 1 1 0 1 Set q 1 1 1 1 1 Restore 1 1 0 0 0 1 0 0 0 1 remainder Quotient First cycle Second cycle Third cycle Fourth cycle
29 5) Algorithms for Division The restoring-division algorithm: S1: DO n times Shift A and Q left one binary position. Subtract M from A, placing the answer back in A. If the sign of A is 1, set q to 0 and add M back to A (restore A) ; otherwise, set q to 1.
30 5) Algorithms for Division The non-restoring division algorithm: S1: Do n times If the sign of A is 0, shift A and Q left one binary position and subtract M from A; otherwise, shift A and Q left and add M to A. S2: If the sign of A is 1, add M to A.
31 References: Computer Systems Organization & Architecture, Addison Wesley Longman, Inc., 2001 Introduction to Computer Organization 4 th Edition. V.Carl hamacher. 1998 http:// www.sfxavier.ac.uk/computing/bcd/bcd1.htm http:// www.awl.com/carpinelli Thank you
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