Excess-3

"XS-3" redirects here. For the experimental aircraft, see Douglas XS-3 Stiletto.

"Shifted binary" redirects here. For the general concept, see Offset binary. For binary shifts, see Bit shifting.

Excess-3, 3-excess^[1][2][3] or 10-excess-3 binary code (often abbreviated as XS-3,^[4] 3XS^[1] or X3^[5][6]), shifted binary^[7] or Stibitz code^[1][2][8][9] (after George Stibitz,^[10] who built a relay-based adding machine in 1937^[11][12]) is a self-complementary binary-coded decimal (BCD) code and numeral system. It is a biased representation. Excess-3 code was used on some older computers as well as in cash registers and hand-held portable electronic calculators of the 1970s, among other uses.

Stibitz code
Digits	4[1]
Tracks	4[1]
Digit values	8  4 −2 −1
Weight(s)	1..3[1]
Continuity	No[1]
Cyclic	No[1]
Minimum distance	1[1]
Maximum distance	4
Redundancy	0.7
Lexicography	1[1]
Complement	9[1]
v t e

Representation

Biased codes are a way to represent values with a balanced number of positive and negative numbers using a pre-specified number N as a biasing value. Biased codes (and Gray codes) are non-weighted codes. In excess-3 code, numbers are represented as decimal digits, and each digit is represented by four bits as the digit value plus 3 (the "excess" amount):

• The smallest binary number represents the smallest value (0 − excess).
• The greatest binary number represents the largest value (2^N+1 − excess − 1).

Excess-3, and Stibitz code

Decimal	Excess-3	Stibitz	BCD 8-4-2-1	Binary	3-of-6 CCITT extension[13][1]	4-of-8 Hamming extension[1]
0	0011	0011	0000	0000	…10	…0011
1	0100	0100	0001	0001	…11	…1011
2	0101	0101	0010	0010	…10	…0101
3	0110	0110	0011	0011	…10	…0110
4	0111	0111	0100	0100	…00	…1000
5	1000	1000	0101	0101	…11	…0111
6	1001	1001	0110	0110	…10	…1001
7	1010	1010	0111	0111	…10	…1010
8	1011	1011	1000	1000	…00	…0100
9	1100	1100	1001	1001	…10	…1100

To encode a number such as 127, one simply encodes each of the decimal digits as above, giving (0100, 0101, 1010).

Excess-3 arithmetic uses different algorithms than normal non-biased BCD or binary positional system numbers. After adding two excess-3 digits, the raw sum is excess-6. For instance, after adding 1 (0100 in excess-3) and 2 (0101 in excess-3), the sum looks like 6 (1001 in excess-3) instead of 3 (0110 in excess-3). To correct this problem, after adding two digits, it is necessary to remove the extra bias by subtracting binary 0011 (decimal 3 in unbiased binary) if the resulting digit is less than decimal 10, or subtracting binary 1101 (decimal 13 in unbiased binary) if an overflow (carry) has occurred. (In 4-bit binary, subtracting binary 1101 is equivalent to adding 0011 and vice versa.)^[14]

Advantage

The primary advantage of excess-3 coding over non-biased coding is that a decimal number can be nines' complemented^[1] (for subtraction) as easily as a binary number can be ones' complemented: just by inverting all bits.^[1] Also, when the sum of two excess-3 digits is greater than 9, the carry bit of a 4-bit adder will be set high. This works because, after adding two digits, an "excess" value of 6 results in the sum. Because a 4-bit integer can only hold values 0 to 15, an excess of 6 means that any sum over 9 will overflow (produce a carry-out).

Another advantage is that the codes 0000 and 1111 are not used for any digit. A fault in a memory or basic transmission line may result in these codes. It is also more difficult to write the zero pattern to magnetic media.^[1][15][11]

Example

BCD 8-4-2-1 to excess-3 converter example in VHDL:

entity bcd8421xs3 is
  port (
    a   : in    std_logic;
    b   : in    std_logic;
    c   : in    std_logic;
    d   : in    std_logic;

    an  : buffer std_logic;
    bn  : buffer std_logic;
    cn  : buffer std_logic;
    dn  : buffer std_logic;

    w   : out   std_logic;
    x   : out   std_logic;
    y   : out   std_logic;
    z   : out   std_logic
  );
end entity bcd8421xs3;

architecture dataflow of bcd8421xs3 is
begin
    an  <=  not a;
    bn  <=  not b;
    cn  <=  not c;
    dn  <=  not d;

    w   <=  (an and b  and d ) or (a  and bn and cn)
         or (an and b  and c  and dn);
    x   <=  (an and bn and d ) or (an and bn and c  and dn)
         or (an and b  and cn and dn) or (a  and bn and cn and d);
    y   <=  (an and cn and dn) or (an and c  and d )
         or (a  and bn and cn and dn);
    z   <=  (an and dn) or (a  and bn and cn and dn);

end architecture dataflow; -- of bcd8421xs3

Extensions

3-of-6 extension
Digits	6[1]
Tracks	6[1]
Weight(s)	3[1]
Continuity	No[1]
Cyclic	No[1]
Minimum distance	2[1]
Maximum distance	6
Lexicography	1[1]
Complement	(9)[1]
v t e

4-of-8 extension
Digits	8[1]
Tracks	8[1]
Weight(s)	4[1]
Continuity	No[1]
Cyclic	No[1]
Minimum distance	4[1]
Maximum distance	8
Lexicography	1[1]
Complement	9[1]
v t e

• 3-of-6 code extension: The excess-3 code is sometimes also used for data transfer, then often expanded to a 6-bit code per CCITT GT 43 No. 1, where 3 out of 6 bits are set.^[13][1]
• 4-of-8 code extension: As an alternative to the IBM transceiver code^[16] (which is a 4-of-8 code with a Hamming distance of 2),^[1] it is also possible to define a 4-of-8 excess-3 code extension achieving a Hamming distance of 4, if only denary digits are to be transferred.^[1]

See also

• Offset binary, excess-N, biased representation
• Excess-128
• Excess-Gray code
• Shifted Gray code
• Gray code
• m-of-n code
• Aiken code