A '''rational number''' is a number which can be represented as the quotient 
(a fraction) of two integers.

[[[AMG]: I'm guessing that the name derives from the fact that a rational number is a ''ratio'' between two integers.  Even if this isn't true, it's a great mnemonic.  I wish somebody had bothered to say this in high school when I first learned the term, because as it was I was left with the impression that rational numbers were somehow better than irrational numbers.  Negative pedagogy!]]

There are an infinite number of such rationals: take the arrangement:

   ...     ...     ...     ...     ...
   5/1     5/2     5/3     5/4    (5/5)   ...
   4/1    (4/2)    4/3    (4/4)    4/5    ...
   3/1     3/2    (3/3)    3/4     3/5    ...
   2/1    (2/2)    2/3    (2/4)    2/5    ...
   1/1     1/2     1/3     1/4     1/5    ...
   0/1    (0/2)   (0/3)   (0/4)   (0/5)   ...
  -1/1    -1/2    -1/3    -1/4    -1/5    ...
  -2/1   (-2/2)   -2/3   (-2/4)   -2/5    ...
  -3/1    -3/2   (-3/3)   -3/4    -3/5    ...
  -4/1   (-4/2)   -4/3   (-4/4)   -4/5    ...
  -5/1    -5/2    -5/3    -5/4   (-5/5)   ...
   ...     ...     ...     ...     ...


etc., and you have clearly written down all the rational numbers that 
are possible.  Quotients in parenthesis are equal to a quotient with 
smaller denominator, i.e., in a column further left.

You can also place these fractions in correspondence with the natural 
numbers, following for example a curve such as the one below.

   3/1  --  3/2  --------  3/4
    |                       |
   2/1  ----------  2/3     |
                     |      |
   1/1  --  1/2     1/3    1/4
    |        |       |      |
   0/1       |       |      |
             |       |      |
  -1/1  -- -1/2    -1/3   -1/4
    |                |      |
  -2/1  ---------  -2/3     |
                            |
  -3/1  -- -3/2  -------  -3/4
    |

Rational number No. 0 is 0/1=0, rational number No. 1 is 1/1=1, 
rational number No. 2 is 1/2, rational number No. 3 is -1/2, 
rational number No. 4 is -1/1=-1, and so on.
From this follows that the number of fractions is the same as the 
number of natural numbers (for every natural number there is a fraction).  

In the same way (actually a bit simpler, since one doesn't have to skip 
the repeated numbers) one can construct a 1-1 correspondence between 
natural numbers and pairs of integers. This is the basis of the proof that 
infinity * infinity is still only infinity. (pow(2,infinity) is however 
strictly larger than infinity.)

----
A '''rational function''' is a function that can be represented as 
the quotient of two polynomials.
----
See also [Playing with rationals]

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