In mathematics and computing, the method of complements is a technique used to subtract one number from another using only addition of positive numbers. This method was commonly used in mechanical calculators and is still used in modern computers. To subtract a number y (the subtrahend) from another number x (the minuend), the radix complement of y is added to x and the initial '1' of the result is discarded. Discarding the initial '1' is especially convenient on calculators or computers that use a fixed number of digits: there is nowhere for it to go so it is simply lost during the calculation.
Contents |
The radix complement of an n digit number y in radix b is, by definition, . Adding this to x results in the value or . Assuming y ≤ x, the result will always be greater or equal to and dropping the initial '1' is the same as subtracting , making the result or just , the desired result.
The radix complement is most easily obtained by adding 1 to the diminished radix complement, which is . Since is the digit repeated n times (because , see also binomial numbers), the diminished radix complement of a number is found by complementing each digit with respect to (that is, subtracting each digit in y from ). Adding 1 to obtain the radix complement can be done separately, but is most often combined with the addition of x and the complement of y.
In the decimal numbering system, the radix complement is called the ten's complement and the diminished radix complement the nines' complement. In binary, the radix complement is called the two's complement and the diminished radix complement the ones' complement. The naming of complements in other bases is similar. Some people, notably Donald Knuth, recommend using the placement of the apostrophe to distinguish between the radix complement and the diminished radix complement. In this usage, the four's complement refers to the radix complement of a number in base four while fours' complement is the diminished radix complement of a number in base 5. However, the distinction is not important when the radix is apparent (nearly always), and the subtle difference in apostrophe placement is not common practice. Most writers use one's and nine's complement, and many style manuals leave out the apostrophe, recommending ones and nines complement.
To subtract a decimal number y from another number x using the method of complements, the ten's complement of y (nines' complement plus 1) is added to x. Typically, the nines' complement of y is first obtained by determining the complement of each digit. The complement of a decimal digit in the nines' complement system is the number that must be added to it to produce 9. The complement of 3 is 6, the complement of 7 is 2, and so on. Given a subtraction problem:
873 (x, the minuend) - 218 (y, the subtrahend)
The nines' complement of y (218) is 781. In this case, because y is three digits long, this is the same as subtracting y from 999.
Next, the sum of x, the nines' complement of y, and 1 is taken:
873 (x) + 781 (nines' complement of y) ===== 1654 -1000 (y + nines' complement of y) + 1 or (y + tens' complement of y) ===== 654
The first "1" digit is then dropped, in an effort to keep the same digits as the original, giving 654. This is not yet correct. We have essentially added 999 to the equation in the first step. Then we remove 1000 when we drop the first 1 in the answer (above) this will make the answer we get one less than the correct answer. To fix this, we must add 1 to the answer.
654 +1 ==== 655
Adding a 1 gives 655, the correct answer.
If the subtrahend has fewer digits than the minuend, leading zeros must be added which will become leading nines when the complement is taken. For example:
48032 (x) - 391 (y)
becomes the sum:
48032 (x) + 99608 (nines' complement of y) ======= 147640
Dropping the "1" yields 47640, and adding the dropped "1" to 47640 gives the answer: 47641.
The method of complements is especially useful in binary (radix 2) since the ones' complement is very easily obtained by inverting each bit (changing '0' to '1' and vice versa). And adding 1 to get the two's complement can be done by simulating a carry into the least significant bit. For example:
01100100 (x, equals decimal 100) - 00010110 (y, equals decimal 22)
becomes the sum:
01100100 (x) + 11101001 (ones' complement of y) + 1 (to get the two's complement) ========== 101001110
Dropping the initial "1" gives the answer: 01001110 (equals decimal 78)
The method of complements normally assumes that the operands are positive and that y ≤ x, logical constraints given that adding and subtracting arbitrary integers is normally done by comparing signs, adding the two or subtracting the smaller from the larger, and giving the result the correct sign.
Let's see what happens if x < y. In that case, there will not be a "1" digit to cross out after the addition since will be less than . For example (in decimal):
185 (x) - 329 (y)
Complementing y and adding gives:
185 (x) + 670 (nines' complement of y) + 1 ===== 856
This is obviously the wrong answer; the expected answer is -144. But it isn't as far off as it seems; 856 happens to be the ten's complement of 144. This issue can be addressed in three ways:
The method of complements was used in many mechanical calculators as an alternative to running the gears backwards. For example:
Use of the method of complements is ubiquitous in digital computers, regardless of the representation used for signed numbers. However, the circuitry required depends on the representation:
The method of complements was used to correct errors when accounting books were written by hand. To remove an entry from a column of numbers, the accountant could add a new entry with the ten's complement of the number to subtract. A bar was added over the digits of this entry to denote its special status. It was then possible to add the whole column of figures.
Complementing the sum is handy for cashiers making change for a purchase from currency in a single denomination of 1 raised to an integer power of the currency's base. For decimal currencies that would be 10, 100, 1,000, etc., e.g. a $10.00 bill.
In grade schools, students are sometimes taught the method of complements as a shortcut useful in mental arithmetic.[1] Subtraction is done by adding the ten's complement of the subtrahend, which is the nines' complement plus 1. The method is generally only applied when it is clear that the difference will be positive. The same technique works for subtracting on an adding machine.