|
|
|
|
|
|
by jimsimmons
1164 days ago
|
|
|
Thanks. A suspicion lingered as soon as I wrote that comment. I guess I was going off of some YouTube video. Now I see rationals are countable. But what explains the power set being larger though? It seems intuitive but I don’t want to trust it for obv reasons. Is diagonalisation impossible? |
|
|
We can show that S has a strictly smaller cardinality than 2^S by showing that no function from S to 2^S can hit every value in 2^S. That is, there's going to be some element of 2^S that no element of S gets mapped to.
Suppose, as one does, to the contrary: that there is a function, call it F, that hits every element of 2^S. We'll construct a particularly pathological element of 2^S, call it B, the set {s in S | s not in F(s)} of values of S that are not members of the subset F picks out for them. (Remember that 2^S is the set of subsets of S, so it is meaningful to ask whether any s is a member of F(s).) If this smells like Russell's paradox, good -- follow your nose!
Now, since B is a subset of 2^S, and F is presumed to hit every subset, there's going to be some element b such that F(b) = B. We ask the critical question: is b in B? If it is, then b is not in F(b) -- but F(b) is B, contradicting our assumption. If it isn't, then b is in F(b) -- but F(b) is B, contradicting our assumption.
Since we end up at a contradiction no matter which way we resolve "is b in B", and we know this question must be answered one way or the other, we must admit that our supposed function F must not have the property we asked for; it must not hit every element of 2^S. So 2^S really is "bigger" than S, in that no matter how we pair every element of S with an element of 2^S, we run out of elements of the former before we've exhausted the latter.