# How many different partitions with exactly n parts can be made of a set with k-elements?

How many different partitions with exactly two parts can be made of the set {1,2,3,4}? There are 4 elements in this list that need to be partitioned into 2 parts. I wrote these out and got a total of 7 different possibilities:

1. {{1},{2,3,4}}
2. {{2},{1,3,4}}
3. {{3},{1,2,4}}
4. {{4},{1,2,3}}
5. {{1,2},{3,4}}
6. {{1,3},{2,4}}
7. {{1,4},{2,3}}

Now I must answer the same question for the set {1,2,3,...,100}. There are 100 elements in this list that need to be partitioned into 2 parts. I know the largest size a part of the partition can be is 50 (that's 100/2) and the smallest is 1 (so one part has 1 number and the other part has 99). How can I determine how many different possibilities there are for partitions of two parts without writing out extraneous lists of every possible combination? Can the answer be simplified into a factorial (such as 12!)?
Is there a general formula one can use to find how many different partitions with exactly n parts can be made of a set with k-elements?

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2) There are 2n subsets of a set of n elements (because each of n elements may either be or be not contained in the specific subset). This gives us 2n-1 different partitions of a n-element set into the two subsets. One of these partitions is the trivial one (with the one part being an empty subset and other part being the entire original set), and from your example it seems you don't want to count the trivial partition. So the answer is 2n-1-1 (which gives 23-1=7 for n=4).

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There is no latex on this site –  BlueRaja - Danny Pflughoeft Feb 16 '12 at 22:31
@BlueRaja-DannyPflughoeft Yes, i'm aware of it :) What i wasn't aware of is that one can use html tags like `<sup/>` when writing answers. –  penartur Feb 17 '12 at 9:41

The general answer for n parts and k elements would be the Stirling number of the second kind S(k,n) : http://en.m.wikipedia.org/wiki/Stirling_numbers_of_the_second_kind

Please beware that the usual convention is with n the total number of elements, thus S(n,k)

Computing the general formula is quite ugly, but doable for k=2 (with the common notation) :

Thus S(n,2) = 1/2 ( (+1) * 1 * 0n +(-1) * 2 * 1n + (+1) * 1 * 2n ) = (0-2+2n)/2 = 2n-1-1

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