proof of Ramsey’s theorem

\omega\rightarrow(\omega)^{n}_{k}

is proven by induction on $n$ .

If $n=1$ then this just states that any partition of an infinite set into a finite number of subsets must include an infinite set; that is, the union of a finite number of finite sets is finite. This is simple enough to prove: since there are a finite number of sets, there is a largest set of size $x$ . Let the number of sets be $y$ . Then the size of the union is no more than $x y$ .

\omega\rightarrow(\omega)^{n}_{k}

then we can show that

\omega\rightarrow(\omega)^{n+1}_{k}

Let $f$ be some coloring of $[S]^{n+1}$ by $k$ where $S$ is an infinite subset of $\omega$ . Observe that, given an $x<\omega$ , we can define $f^{x}\colon[S\setminus\{x\}]^{n}\rightarrow k$ by $f^{x}(X)=f(\{x\}\cup X)$ . Since $S$ is infinite, by the induction hypothesis this will have an infinite homogeneous set.

Then we define a sequence of integers $\langle n_{i}\rangle_{i\in\omega}$ and a sequence of infinite subsets of $\omega$ , $\langle S_{i}\rangle_{i\in\omega}$ by induction. Let $n_{0}=0$ and let $S_{0}=\omega$ . Given $n_{i}$ and $S_{i}$ for $i\leq j$ we can define $S_{j}$ as an infinite homogeneous set for $f^{n_{i}}\colon[S_{j-1}]^{n}\rightarrow k$ and $n_{j}$ as the least element of $S_{j}$ .

Obviously $N=\bigcup\{n_{i}\}$ is infinite, and it is also homogeneous, since each $n_{i}$ is contained in $S_{j}$ for each $j\leq i$ .

Title	proof of Ramsey’s theorem
Canonical name	ProofOfRamseysTheorem
Date of creation	2013-03-22 12:55:52
Last modified on	2013-03-22 12:55:52
Owner	mathcam (2727)
Last modified by	mathcam (2727)
Numerical id	8
Author	mathcam (2727)
Entry type	Proof
Classification	msc 05D10