Proof Hypercube 1

Theorem 1

Theorem: Let ${\displaystyle v\in \mathbb {S} }$.

${\displaystyle N(v)\subseteq \mathbb {S} \Rightarrow vol(P_{v})=1/2^{n}}$

Proof: Let ${\displaystyle e_{i}=0\ldots 1\ldots 0}$ where 1 appears at ith position.

${\displaystyle N(v)=\{v\oplus e_{i}\}_{i=1}^{n}}$

There will be some technicalities in the proof. One way to get rid of them is to consider ${\displaystyle v=0^{n}}$.

Consider a hyperplane ${\displaystyle H_{i}}$ halving the middle point between v and ${\displaystyle v\oplus e_{i}}$ The hyperplane is defined by ${\displaystyle (x-(v+v\oplus e_{i})/2))\cdot e_{i}=0}$. Working out the calculation,

${\displaystyle x_{i}-1/2=0}$

So, P_v is defined by the intersection of halfspaces ${\displaystyle x_{i}\leq 1/2}$ for ${\displaystyle i=1,\ldots ,n}$. It is obvious that the volume of this intersection is ${\displaystyle 1/2^{n}}$ (If you don't believe, you can do Reimann integration of this set :P ).

Since the volume can't be any smaller, we conclude that, in this case, ${\displaystyle Vol(P_{v})=1/2^{n}}$. A more rigorous proof can also be achieved by considering other halfspaces and argue that it contains at least one of ${\displaystyle h_{i}}$.

Theorem 2