Difference between revisions of "Sets:Cardinality"
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If <math>A</math> and <math>B</math> are two sets and there exist injective functions <math>f:A\to B</math> and <math>g:B\to A</math>, then there exists a bijection between <math>A</math> and <math>B</math>. | If <math>A</math> and <math>B</math> are two sets and there exist injective functions <math>f:A\to B</math> and <math>g:B\to A</math>, then there exists a bijection between <math>A</math> and <math>B</math>. |
Revision as of 15:52, 2 October 2021
Infinite Sets and Cardinality
The Size of a Finite Set
When deciding how large finite sets are, we generally count the number of elements in the set, and say two sets are the same size if they have the same number of elements. This approach doesn't work too well if the sets are infinite, however, because we can't count the number of elements in an infinite set.
However, there is another way to define when two sets have the same size that works equally well for finite and infinite sets. We say that two sets and have the same size if we can define a function which satisfies the following properties:
- is defined for every .
- , such that . We say that f is onto or surjective.
- , . We say that f is one-to-one or injective.
Functions which satisfy these properties are called bijections.
Examples
The sets and both have three elements. We can define a bijection between them like this: .
The set of all positive integers, is the same size as the set of nonnegative integers, . Let , and more generally .
Exercise
Prove that the above function is a bijection.
Often it is difficult to construct an explicit bijection between two sets of the same cardinality, so the following theorem can come in handy:
Cantor-Schroeder-Bernstein Theorem
If and are two sets and there exist injective functions and , then there exists a bijection between and .