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7 votes
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165 views

Lonely globe trotters

In analogy with the lonely runners conjecture, imagine "globe trotters" each traveling on a longitudinal great circle at different (constant, positive) speeds. Each "trotter" ...
Joseph O'Rourke's user avatar
1 vote
0 answers
115 views

A circle is inscribed in a triangle, with three other circles in the corner regions. The radii are integers. Possible values of the largest radius?

Originally posted at MSE. A circle with integer radius $R$ is inscribed in a triangle. Three other circles with integer radii $a,b,c$ are each tangent to the large circle and two sides of the ...
Dan's user avatar
  • 3,527
1 vote
0 answers
52 views

'Self-similar and perfect' partitions of planar regions

Definition: A partition of a planar figure into finitely many pieces that are all similar to itself and also mutually non-congruent may be called a self-similar perfect partition. A classical example ...
Nandakumar R's user avatar
  • 5,979
1 vote
0 answers
100 views

Perfect 'cuboiding' of cubes and cuboids

We try to add a bit to ref 2 listed below. In this post, by 'cuboid', we mean only rectangular cuboids - hexahedra with all faces rectangles and adjacent faces meeting only at right angles. A special ...
Nandakumar R's user avatar
  • 5,979
4 votes
1 answer
438 views

Perfect squaring of rectangles

A perfect squaring of a rectangle may be defined as a partition of the rectangle into finitely many squares all of which are mutually non-congruent. https://en.wikipedia.org/wiki/Squaring_the_square ...
Nandakumar R's user avatar
  • 5,979
9 votes
0 answers
187 views

Cubing the cube - as 'perfectly' as possible

Ref: https://en.wikipedia.org/wiki/Squaring_the_square A perfect cubing of a cube is a partition of the cube into some finite number of smaller cubes that are pair-wise non-congruent. The above page ...
Nandakumar R's user avatar
  • 5,979
3 votes
1 answer
366 views

Illumination from visible lattice points with inverse square intensity

It is well known that the number of $\mathbb{Z}^2$ lattice points visible from the origin is $6/\pi^2$, about $61$%. See, e.g., What fraction of the integer lattice can be seen from the origin?. I am ...
Joseph O'Rourke's user avatar
4 votes
0 answers
111 views

Advice on results for balls on regular $N$-dimensional grids

I have obtained some results regarding balls on regular $N$-dimensional grids. I would like expert opinion on wether the results are significant or interesting enough for (trying to) publish them in a ...
Luis Mendo's user avatar
3 votes
1 answer
954 views

A geometric proof that there are infinitely many primes?

Let $e_d$ be the $d$-th standard-basis vector in the Hilbert space $H=l_2(\mathbb{N})$. Let $h(n) = J_2(n)$ be the second Jordan totient function, defined by: $$J_2(n) = n^2 \prod_{p|n}(1-1/p^2)$$ ...
mathoverflowUser's user avatar
2 votes
1 answer
588 views

Kissing number lower bound vs. upper bound - precise meanings?

According to en.wikipedia.org, https://en.wikipedia.org/wiki/Kissing_number#Some_known_bounds It says the kissing numbers $K$ have lower bound $K_L$ and upper bound $K_S$: $$ K_L < K < K_U. $$ I ...
zeta's user avatar
  • 447
0 votes
1 answer
199 views

Leech lattice shortest vector vs other 23 cases and E8 cases

In this paper by Viazovska, she said that: "The E8-lattice sphere packing 𝒫E8 is the union of open Euclidean balls with centers at the lattice points and radius $1/\sqrt{2}$." So I think ...
zeta's user avatar
  • 447
7 votes
1 answer
498 views

Is there a bicyclic irregular pentagon in integers?

Is there a bicyclic irregular pentagon in integers, i.e. is there a pentagon, the length of each side is integer and unique such that it has a circumcircle and an inner circle as well? If it does ...
shabo's user avatar
  • 71
1 vote
0 answers
77 views

Lattice packing

Let $\Lambda$ be a lattice in $R^n$ and $R>0$ a real number. Consider the number $N$ of points in $\Lambda$ of norm less than $R$. Let $R$ goes to infinity. What can be said about the asymptotic ...
user95246's user avatar
  • 237
1 vote
0 answers
142 views

A question about Roger Penrose's spin networks and mathematical formalization?

Let $a,b,c$ be "units" in the spin network. Then there are there are the following three requirements to fulfill (according to the relevant Wikipedia entry): $a,b,c \in \mathbb{N}$ Triangle ...
mathoverflowUser's user avatar
2 votes
0 answers
95 views

Is there an exact solution for the number of points within a circle of radius r for an honeycomb lattice?

I want to ask if exists an exact solution for the number of points within a circle of radius r for an honeycomb lattice. I know that it is exist for an square lattice https://mathworld.wolfram.com/...
Mihaela's user avatar
  • 31
0 votes
1 answer
937 views

The exact number of points within a circle of radius r centered on a lattice point in a hexagonal lattice? Review expression Gauss circle problem

In the case of a square lattice, the exact number of points within a circle of radius r centered in the center is (see: http://mathworld.wolfram.com/GausssCircleProblem.html: $$N(r)=1+4Floor(r)+4 \...
Mihaela's user avatar
  • 31
8 votes
1 answer
362 views

Is the set of powerful numbers piecewise syndetic?

Recall that a subset $A \subset \mathbb Z_+$ of positive integers syndetic if there exists a $d>0$ such that every positive integer has distance at most $d$ to an element of $A$. It is called ...
Jens Reinhold's user avatar
1 vote
0 answers
82 views

Intersecting lattices with surfaces in R^d

Let us fix some bounded surface $S\subset \mathbb{R}^d$. Let $x_1,\ldots, x_m$ be some non-zero vectors in $\mathbb{R}^d$. I am interested is the maximum number of points that the lattice $L_m=\{\sum ...
TOM's user avatar
  • 2,288
16 votes
1 answer
533 views

Is there a degenerate simplex in $\mathbb{R}^{8 k-1}$ with odd integer edge lengths?

The Cayley-Menger determinant gives the squared volume of a simplex in $\mathbb{R}^n$ as a function of its $n(n+1)/2$ edge lengths: $$v_n^2 = \frac{(-1)^{n+1}}{(n!)^2 2^n} \begin{vmatrix} 0&d_{01}^...
Greg Egan's user avatar
  • 2,902
5 votes
2 answers
446 views

Lattices containing $A_n$ and $D_n$

How many lattices are there which contain both the $A_n$ and $D_n$ lattices of the same dimension as sublattices? So far, I’ve found examples in 1D, 3D, 8D, and 24D.
Daniel Sebald's user avatar
9 votes
1 answer
204 views

Which unimodular lattices $L\subset \mathbb R^2$ minimize $f_t(L):=\sum_{ v\in L} e^{-t \|v\|_2}$? (for parameters $t>0$)

$\DeclareMathOperator\SL{SL}\DeclareMathOperator\SO{SO}$Consider the lattices in $\SL(2,\mathbb R)(\mathbb Z^2)$ up to rotation. The space of such lattices can be identified with the modular surface $\...
user84899's user avatar
  • 241
8 votes
2 answers
803 views

a Littlewood–Offord-type problem concerning the "cubical lattice"

Fix even $n$ and consider the boolean function $f : \{0, 1\}^n \rightarrow \{0, 1\}$, $f : (x_0, \ldots , x_{n - 1}) \mapsto (x_0 \vee x_1) \wedge (x_2 \vee x_3) \wedge \cdots \wedge (x_{n - 2} \vee ...
BD107's user avatar
  • 63
6 votes
2 answers
544 views

On circles and ellipses drawn on an infinite planar square lattice

Consider a plane with a square lattice formed by all points with both coordinates as integers. As can be easily seen, a simple parabola can be found that passes through infinitely many of the square ...
Nandakumar R's user avatar
  • 5,979
4 votes
0 answers
396 views

Dense sets in $\Bbb{R}^2$ with rational distance

We call a subset $S\subset \Bbb{R}^2$ rationally distanced if all $s_1,s_2 \in S$ have rational Euclidean distance. The Erdos-Ulam conjecture asks if there is a dense subset of $\Bbb{R}^2$ which is ...
Zach Hunter's user avatar
  • 3,499
2 votes
1 answer
600 views

A geometric approach to the odd perfect number problem?

Let $e_d$ be the $d$-th standard-basis vector in the Hilbert space $H=l_2(\mathbb{N})$. Let $h(n) = J_2(n)$ be the second Jordan totient function. Define: $$\phi(n) = \frac{1}{n} \sum_{d|n}\sqrt{h(d)}...
mathoverflowUser's user avatar
7 votes
0 answers
346 views

The space of $p$-adic norms

The 1963 paper by Goldman and Iwahori The space of $p$-adic norms deals with the space of norms on a finite dimensional vector space $E$ over a locally compact complete discrete valuation field $K$. I ...
A413's user avatar
  • 433
3 votes
1 answer
303 views

number of integer points inside a triangle and its area

Let $T$ be a triangle in $\mathbb{R}^2$ defined by $y = \alpha x$, $y = \beta$ and $x = \gamma$ where $\alpha, \beta, \gamma \in \mathbb{R}_{>0}$. I am interested in obtaining an estimate for the ...
Johnny T.'s user avatar
  • 3,625
11 votes
0 answers
307 views

Entropy, magnitude, diversity of finite metric spaces in number theory

I was reading the article by Tom Leinster, (Maximizing diversity in biology and beyond, arXiv link), and find it very interesting. Since I was searching for entropies of finite metric spaces I found ...
user avatar
3 votes
1 answer
818 views

Has anyone studied spaces based on the number of centers circles have on them?

I have been away from math for a while so be gentle if this is not very rigorous or if I am redefining already defined objects. The essential question that started me on this was the following. In the ...
Heraiwa's user avatar
  • 39
24 votes
4 answers
2k views

A reinterpretation of the $abc$ - conjecture in terms of metric spaces?

I hope it is appropriate to ask this question here: One formulation of the abc-conjecture is $$ c < \text{rad}(abc)^2$$ where $\gcd(a,b)=1$ and $c=a+b$. This is equivalent to ($a,b$ being ...
user avatar
10 votes
1 answer
648 views

Does every positive-definite integral lattice admit an angle-preserving homomorphism into $\Bbb Z^n$ for some $n$?

Some initial clarifications By lattice I mean an additive subgroup of $\mathbb R^n$ which is isomorphic to $\mathbb Z^n$ and has full rank (i.e. spans $\Bbb R^n$ when considered as set of vectors). A ...
M. Winter's user avatar
  • 13.6k
2 votes
4 answers
997 views

Why does $\sqrt 5$ occur in manageable situations of these scenarios? [closed]

Banach-Mazur distance between $P_5$ and $P_3$ is $d(P_5,P_3)=1+\frac{\sqrt5}2$ where $P_n$ is regular polygon in $n$ sides https://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7968198&tag=...
VS.'s user avatar
  • 1,826
3 votes
0 answers
310 views

Upper bound on the number of lattice points on the intersection of a hyperplane and a sphere

Let $R>0$, $\overrightarrow{\alpha} \in \mathbb{R}^{d}$. Consider the intersection $T$of $RS^{d-1}$ and the hyperplane $\overrightarrow{\alpha} \cdot \overrightarrow{x} = n$. What is the best known ...
Martin Ortiz's user avatar
6 votes
0 answers
176 views

Approximating a ray with an integer lattice point

Take $X$ uniform on the unit sphere in $\mathbb{R}^n.$ For $r>0$, take $S_r=\{x\in \mathbb{Z}^n: \sum_i x_i^2 \leq r^2\}.$ With $\|\cdot \|$ the 2-norm, what is the distribution (or at least the ...
Christian Chapman's user avatar
17 votes
0 answers
1k views

Almost monochromatic point sets

There are many sort of equivalent theorems about monochromatic configurations in finite colorings, such as Van der Waerden, Hales-Jewett or Gallai's theorem, the latter of which states that in a ...
domotorp's user avatar
  • 19k
3 votes
1 answer
118 views

Question arise from kissing number in 2 dimension

I'm considering an extended problem of kissing number in $\mathbb{R}^2$. Suppose I have a given disc $\mathcal{D}$ of radius 1/2 and infinitely many discs all of radius 1/2 and all these discs and ...
neverevernever's user avatar
1 vote
0 answers
196 views

Squares as sum of squares

For which positive integers n is $n^2$ the sum of precisely n smaller positive squares? Of these n x n squares, which can be actually cut into n smaller squares?
Bernardo Recamán Santos's user avatar
9 votes
0 answers
365 views

How to count integer lattice points close to a subspace of $\mathbb R^n$?

Consider $m$ linearly independent vectors in $n$-dimensional Euclidean space, $v_1,...,v_m \in \mathbb R^n$ where $1\leq m<n$, and let $U := {\rm span}(v_1,...,v_m)$ denote the $m$-dimensional ...
Dierk Bormann's user avatar
5 votes
1 answer
188 views

Example of a non-arithmetic Veech surface (other than regular polygon)?

I am reading this paper of Avila and Delecroix of the billiard flow on polygonal surfaces, but I have to get through some basic definitions first. What is a non-arithmetic Veech surface? A Veech ...
john mangual's user avatar
  • 22.8k
6 votes
1 answer
237 views

Current interest in geometric properties of Hilbert fundamental domains

Harvey Cohn published several articles in the 1960's analyzing geometric properties of fundamental domains for Hilbert modular surfaces. H. Cohn, "On the shape of the fundamental domain of the ...
j0equ1nn's user avatar
  • 2,436
1 vote
1 answer
145 views

More on divisibility

This is a fuzzier follow-up to this question. Again, we construct the graph whose vertices are integers from $1$ to $n,$ and two vertices are connected whenever one of the corresponding integers ...
Igor Rivin's user avatar
  • 96.4k
3 votes
0 answers
145 views

How much can analogy between $\Bbb Z$ and $\Bbb F_q[t]$ work out to give better distance measures in information theory?

Let $x$ be transmitted symbol and $y$ be received symbol and $n$ be noise Given $y=x+n$ where symbols $x,y,n$ are in $\Bbb K$. If $\Bbb K=\Bbb Z$ then we take $|n|$ to be the magnitude of noise while ...
Turbo's user avatar
  • 13.9k
11 votes
4 answers
447 views

Sequential addition of points on a circle, optimizing asymptotic packing radius

Suppose I have to put $N$ points $x_1, x_2, \ldots, x_N$ on the circle $S^1$ of length 1 so as to achieve the largest minimum separation (packing radius). The optimal solution is the equally spaced ...
Yoav Kallus's user avatar
  • 5,971
8 votes
1 answer
280 views

Hyperbolic planes inside hyperbolic 3-space quotients

Let $\mathcal{H}_2 = \{(x,t) \in \mathbf{R}^2: t > 0\}$ be the upper half-plane, and let $\mathcal{H}_3$ be the hyperbolic 3-space $\{(x,t) \in \mathbf{C} \times \mathbf{R}: t > 0\}$. Clearly $\...
David Loeffler's user avatar
5 votes
0 answers
107 views

How well can a rotation separate lattice vectors of equal norm in Z^d?

I'm interested in rotations $R$ that maximally separate integral lattice vectors of equal norm. This question is preliminary, and regards the scaling of those separations as norm goes to infinity. ...
Chaitanya Murthy's user avatar
7 votes
1 answer
642 views

volume over a hypercube, over simplex: twist by Euler numbers

Let $\square_n=\{(x_1,\dots,x_n): 0\leq x_i\leq1,\, \forall i\}$ be an $n$-dimensional unit hypercube, and let $\Delta_n=\{(u_1,\dots,u_n):u_1+\cdots+u_n\leq\frac{\pi}2,\, u_i\geq0,\, \forall i\}$ be $...
T. Amdeberhan's user avatar
6 votes
2 answers
473 views

rate of equidistribution of the horocycle flow for $SL(2, \mathbb{Z})$

I know that for any Fuchsian group $\Gamma$, there is a spectral gap, which leads to $$ \left| \int_0^1 F(x + iy) \, dx - \int_{\Gamma \backslash \mathbb{H}} F \, \frac{dx \, dy}{y^2} \right| < ...
john mangual's user avatar
  • 22.8k
9 votes
2 answers
598 views

Dissecting Ramanujan´s Cuboid: 1729 = 19 x 13 x 7

Consider the cuboid of dimensions 19 x 13 x 7 whose volume is 1729, the Hardy-Ramanujan number. What is the least number of smaller cuboids into which it can be dissected so that the resulting pieces ...
Bernardo Recamán Santos's user avatar
21 votes
1 answer
1k views

Sphere packings : what next after the recent breakthrough of Viazovska (et al.)?

Given the march 2016 breakthrough concerning sphere packings by Viazovska for the case of dimension 8, and by Cohn, Kumar, Miller, Radchenko and Viazovska for the case of dimension 24, it follows that ...
Archie's user avatar
  • 883
1 vote
0 answers
79 views

Completely incongruent box partitions

Let $B$ be a rectangular box with corners in $\mathbb{Z}^d$ and sides parallel to the axes. A completely incongruent partition of $B$ is a partition into $d$-dimensional boxes, each of whose integer ...
Joseph O'Rourke's user avatar