\section{Minkowski's Theorem} \theorem{Blichfeldt's theorem} Let $X$ be a finite connected region. If the volume of $X$ is greater than $1$, $X$ must contain two distinct points that differ by an element of $\mathbb{Z}^n$. In other words, there exist distinct $x, y \in X$ so that $x - y \in \mathbb{Z}^n$. \problem{} Draw a region in $\mathbb{R}^2$ with volume greater than 1 that contains no lattice points. Find two points in that region which differ by an integer vector. \hint{Area is two-dimensional volume.} \vfill \problem{Proof in $\mathbb{Z}^2$} The following picture gives the idea for the proof of Blichfeldt's theorem. Explain the picture and complete the proof. \begin{center} \includegraphics[angle=90,width=0.5\linewidth]{proof.png} \end{center} \begin{solution} The fundamental region of $\mathbb{Z}^2$ tiles the plane. Translate these tiles by lattice vectors to stack them on the fundamental region. Then since the union of the intersections of X with these tiles has area greater 1 and they are stacked on a region of area 1, there must be an overlap by a generalization of the pigeonhole principle (if there were no overlap then the sum of the areas would be less than or equal to 1). Take points $x, y$ in the overlap. Then $x - y$ is a lattice point corresponding to the difference in translates, which were lattice points. Hence, $x - y \in \mathbb{Z}^2$. \end{solution} \vfill \pagebreak %\problem{} %Does your proof of Blichfeldt's theorem in $\mathbb{Z}^2$ extend to a proof of Blichfeldt's theorem in $\mathbb{Z}^n$? %\vfill \problem{} Let $X$ be a region $X$ of volume $k$. How many integral points must $X$ contain after a translation? \vfill \definition{} A region $X$ is \textit{convex} if the line segment connecting any two points in $X$ lies entirely in $X$. \problem{} \begin{itemize} \item Draw a convex region in the plane. \item Draw a region that is not convex. \end{itemize} \vfill \pagebreak \definition{} We say a region is \textit{symmetric with respect to the origin} if for all points $x$ in the region, $-x$ is also in $X$. \problem{} \begin{itemize} \item Draw a symmetric region. \item Draw an asymmetric region. \end{itemize} \vfill \theorem{Minkowski's Theorem} Every convex set in $\mathbb{R}^n$ that is symmetric with respect to the origin and which has a volume greater than $2^n$ contains an integral point that isn't zero. \problem{} Draw a few sets that satisfy \ref{mink} in $\mathbb{R}^2$. Which is the simplest region that has the properties listed above? \vfill \problem{} Let $K$ be a region in $\mathbb{R}^2$ satisfying \ref{mink}. Scale this region by $\frac{1}{2}$, called $K' = \frac{1}{2}K$. \begin{itemize} \item How does the volume of $K'$ compare to $K$? \item Show that the sum of any two points in $K'$ lies in $K$ \item Apply Blichfeldt's theorem to $K'$ to prove Minkowski's theorem in $\mathbb{R}^2$. \end{itemize} \vfill \problem{} Let $K$ be a region in $\mathbb{R}^n$ satisfying \ref{mink}. Scale this region by $\frac{1}{2}$, called $K' = \frac{1}{2}K$. \begin{itemize} \item How does the volume of $K'$ compare to $K$? \item Show that the sum of any two points in $K'$ lies in $K$ \item Apply Blichfeldt's theorem to $K'$ to prove Minkowski's theorem. \end{itemize} \begin{solution} \begin{itemize} \item The volume of $K'$ is $\frac{1}{2^n}$ the volume of $K$. \item Take $x, y \in K'$. It follows that $2x, 2y \in K$. Since $K$ is convex, we have that the midpoint of the line segment between $2x$ and $2y$ is in $K$, and so $\frac{2x + 2y}{2} = x + y \in K$. \item Since the volume of $K$ is greater than $2^n$, we have the volume of $K'$ is greater than one. Applying Blichfeldt's theorem, we can find two distinct points $x, y \in K'$ such that $x - y \in \mathbb{Z}^n$. Since $K'$ is symmetric with respect to the origin, we have that $-y \in K'$. Therefore, $x + (-y) \in K$ by the previous part. $x \neq y, x - y \neq 0$, so we have found a nontrivial integer point in $K$. \end{itemize} \end{solution} \vfill \pagebreak