Trying to do some revision but not sure on this one:

Prove that the set of all languages over a finite alphabet is uncountable.

I have a feeling it will require using the Cantor Diagonalization method - but I'm not sure how you would use it for this problem.

  • is this homework? – NG. Jan 11 '11 at 0:15
  • this can be proven by the absurd... can't remember exactly how, though – Santiago Alessandri Jan 11 '11 at 0:17
  • No, its not homework – Robben_Ford_Fan_boy Jan 11 '11 at 0:22
  • Is it necessary that n>1? I don't think that 1 alphabet language is uncountable. – User Not Found Dec 1 '16 at 10:08
up vote 6 down vote accepted

I've found in my computation theory class notes this proof, I hope it's useful for you

|N| < |languages(N)|

Supose that |N| >= |languages(N)|. Therefore, each of the elements of languages(N) can be related to one of the elements of N. So they can be put into order:

languages(N) = {S_1 , S_2, S_3, ...}

We define a set D like:

D = {n in N / n not in S_n}

D is valid and D is a subset of N, therefore D belongs languages(N). So, there must exist a k for which D = S_k

1) If k belongs to D then by definition of D, k doesn't belong to S_k. And k doesn't belong to D Because D = S_k(We find a contradiction)

2) If k doesn't belong to D then: k belongs to S_k(by definition of D) and k belongs to D because D = S_k(Contradiction again)

A sequence like the one assumed can't exist. Therefore an injective function that assigns an elemnt of N for each element of languages(N) is not possible. Concluding that |languages(N)| !<= |N|, so |languages(N)| > |N|

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