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Countable and Countably Infinite Sets

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1 Countable and Countably Infinite Sets
Theorem: |N-{0}| = |N| Proof: Define a function f from |N-{0}| to N as f(i) = i-1. f is a function f is one-to-one f is onto f is therefore a bijection and, by definition of cardinality, |N-{0}| = |N|.  Corollary: N-{0} is countable. Corollary: N-{0} is countably infinite.

2 Theorem: Let A be the set of all even integers >=2, and let B be the set of all positive integers (i.e., >=1). Then |A| = |B|. Proof: Let f(i) = i/2. Then it can be easily verified that f is a bijection from A to B. 

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