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Lattice points in the boundary of a Minkowski sum of two convex lattice polygons

Let $P$ and $Q$ be two convex lattice polygons in $\mathbb{R}_+^2$ and let $P+Q$ be their Minkowski sum. Given a set $S \subset \mathbb{R}^2$, we let $L(S) =\#( S \bigcap \mathbb{Z}^2)$. The equality $...
Yromed's user avatar
  • 183
3 votes
1 answer
237 views

Find the number of triangles in plane

Let $S$ be a set of $n$ points in the plane in general position. Each 3 points of S span a triangle. Total number of triangles spanned by S: $$\binom{n}{3}=\frac{n(n-1)(n-2)}{6}=\frac{1}{6} n^3-O(n^2 )...
Xd00fg's user avatar
  • 214
4 votes
1 answer
356 views

Left and right halves of convex curve

Let $S$ be a set of $n$ points in the plane in general position (no 3 on a line), $n$ even. A halving line is a line through $2$ points of $S$ that partitions $S$ into 2 equal parts ($(n-2)/2$ points ...
Xd00fg's user avatar
  • 214
6 votes
1 answer
127 views

Convex planar regions with all area bisectors having equal length

Following A claim on the concurrency of area bisectors of planar convex regions, let me record a couple of simple queries. An area bisector (perimeter bisector) of a planar convex region is a chord ...
Nandakumar R's user avatar
  • 5,979
2 votes
1 answer
84 views

What is the average component size of a coloring?

Supose each cell of a big (or infinite) grid is colored at random by one of $k$ colors. Then the connected monochromatic components (here components are not supposed to contain "wasp waists",...
Wolfgang's user avatar
  • 13.4k
3 votes
1 answer
329 views

Planar subsets with many pairs of points on distance $1$ [duplicate]

Let $X$ be a subset of $\mathbb R^2$ consisting of $n$ distinct points. Let $d_1(X)$ be the number of pairs of points of $X$ on distance $1$ from each other. Define $$d_1(n)=\sup_{X\subset \mathbb R^2|...
aglearner's user avatar
  • 14.3k
5 votes
0 answers
235 views

Arrangement of points, lines, and planes

Is it possible to construct a finite nontrivial arrangement of points, lines, and planes in 3-dimensional Euclidean space with the following properties? every line is incident with four points and ...
Daniel Sebald's user avatar
22 votes
1 answer
886 views

Happy ants never leave compact domain?

I am curious if the following seemingly simple question has an easy answer? Consider an ant population of $N$ ants that lives in $\mathbb R^2$. Each ant can be labeled by some coordinate $x\in \mathbb ...
Pritam Bemis's user avatar
5 votes
1 answer
176 views

Orientations of triples of points in the plane

Given a finite indexing-set $I$ and a collection $P = \{P_i: \ i \in I\}$ of points in the plane no three of which are collinear, let $I_{(3)}$ denote the set of ordered triples of distinct elements ...
James Propp's user avatar
  • 19.7k
10 votes
1 answer
1k views

How can we find n points on a plane so that as many pairs of points as possible have the same distance?

There are $n$ points on the plane, and we need to maximize the number of pairs of points which have the same Euclidean distance.
Cynasty's user avatar
  • 159
4 votes
2 answers
94 views

Finding a not too slim triangulation with prescribed vertices on $\mathbb R^2$

Let us fix a constant $r>1$. Let $d(x,y)$ denote the distance between points $x,y\in \mathbb R^2$. Suppose we have a discreet subset $X\subset \mathbb R^2$ such that 1) For any two points $x,x'\...
aglearner's user avatar
  • 14.3k
10 votes
0 answers
497 views

Which finite sets could be packed into a square?

This question is inspired by an interesting visualization of the finite levels of von Neumann's hierarchy on Adam P. Goucher's blog, Complex Projective 4-Space. The problem starts with a two-...
Morteza Azad's user avatar
21 votes
0 answers
441 views

Straight-line drawing of regular polyhedra

Find the minimum number of straight lines needed to cover a crossing-free straight-line drawing of the icosahedron $(13\dots 15)$ and of the dodecahedron $(9\dots 10)$ (in the plane). For example, ...
Lviv Scottish Book's user avatar
6 votes
1 answer
429 views

Bichromatic pencils

A pencil is a collection of some lines through a point, called the center of the pencil. If the points of the plane are colored, then call a pencil bichromatic if there is a color that is present on ...
domotorp's user avatar
  • 18.8k
4 votes
0 answers
164 views

Tileability and computabilty

Let $n>2$ be an integer. We consider $n$ pairs $(x_1,y_1),\dotsc,(x_n,y_n)$ in $\mathbb{N}^2$, and the polygon defined by drawing a straight line from $(x_k, y_k)$ to $(x_{k+1},y_{k+1})$ and from $(...
Dominic van der Zypen's user avatar
10 votes
1 answer
277 views

Optimization of points on a plane

Suppose we have $n$ points on a plane. Let $D$ be the sum of the squares of all the pairwise distances between the points. Let $A$ be the area of the convex hull. What is the minimum possible value of ...
Halbort's user avatar
  • 1,129
13 votes
1 answer
247 views

Complexity of planar scissor congruence

Two (not necessarily convex) poygons of equal area are scissor-congruent, i.e. both can be cut along a finite number of straight lines or segments into isometric pieces. What can be said about the ...
Roland Bacher's user avatar
12 votes
1 answer
861 views

Connected components $0-1$ matrices

Let $M$ be a $0-1$ matrix. Here a matrix has one component means we can traverse from a matrix entry $(i,j)$ which is $1$ to any other one by moving step of $(i\pm1,j),(i,j\pm1),(i\pm1,j\pm1)$ where ...
Turbo's user avatar
  • 13.9k
13 votes
3 answers
3k views

Koebe–Andreev–Thurston theorem - where can I find a proof?

Koebe–Andreev–Thurston theorem (known also as the circle packing theorem) says that any planar graph can be realized by a set of (interior-) disjoint disks corresponding to vertices, such that two ...
user49822's user avatar
  • 2,178
2 votes
1 answer
305 views

Distribution of area of randomly placed circles

I've searched the web now for ages to try and find a paper on the asymptotic distribution of the area of the union of randomly placed discs on the plane. Ideally, I would be looking for the discs to ...
Pavan Sangha's user avatar
20 votes
1 answer
452 views

Hidden points in polygons

Let $h(n)$ be the largest number of mutually invisible points that can be located in a polygon $P$ of $n$ vertices. Two points $x$ and $y$ are mutually invisible if the segment $xy$ contains a point ...
Joseph O'Rourke's user avatar
14 votes
2 answers
878 views

Sets of evenly distributed points in the Euclidean plane

Is there a set $P \subset \mathbb{R}^2$ of points in the Euclidean plane whose intersection with every convex subset of $\mathbb{R}^2$ of area $1$ is nonempty but finite? If the answer is yes, can $P$...
Stefan Kohl's user avatar
  • 19.6k
18 votes
2 answers
979 views

Arrangements of points in the plane

Let $p_1,\ldots,p_n$ be a collection of distinct points in $\mathbb{R}^2$, no three of which lie on a line. For each $p_i$, let $\omega_i(p_1,\ldots,p_n)$ be the following ordered list (well-defined ...
Solid Snake's user avatar
16 votes
2 answers
1k views

Are Penrose tilings universal? Do aperiodic universal tilings exist?

Consider a tiling of the plane using tiles of at least two types (e.g, a Penrose tiling such as that shown at the bottom of this question, which tiles the plane with two types of tiles). List the tile ...
Louigi Addario-Berry's user avatar
3 votes
1 answer
672 views

Gluing Polygons

Consider all polygons whose vertices are lattice points and edges are parallel to the axes such that no more than two edges meet at a vertex. For two polygons A and B, define A+B be to the set of ...
Anonymous's user avatar
  • 413
24 votes
3 answers
4k views

What upper bounds are known for the diameter of the minimum spanning tree of $n$ uniformly random points in $[0,1]^2$?

Let $P$ be a pointset consisting of $n$ uniformly random elements of $[0,1]^2$. It is known that the diameter (greatest number of edges in any shortest path between two points) of the Delaunay ...
Louigi Addario-Berry's user avatar
2 votes
3 answers
2k views

Placing Axis-parallel rectangles on 2-D plane

Can we place $n$ axis-parallel rectangles on 2D plane (e.g. four sides of each rectangle must be parallel to either x-axis or y-axis) such that for every pair of rectangles, there is a region that is ...
ltdtl's user avatar
  • 21
28 votes
6 answers
2k views

How fast are a ruler and compass?

This may be more of a recreational mathematics question than a research question, but I have wondered about it for a while. I hope it is not inappropriate for MO. Consider the standard assumptions ...
John Watrous's user avatar