Recording 3 questions recently posted at MathOverflow:
1. On Geometry of Numbers:
https://mathoverflow.net/questions/381542/on-circles-and-ellipses-drawn-on-an-infinite-planar-square-lattice
Thanks to Profs. Noam Elkies and Alexei Ustinov for sharing their insights.
Just recording the main questions: Consider a square lattice on the plane formed by points with integer coordinates:
- Given any positive integer n, can we always find a sufficiently large circle drawn on the plane that passes through at least n lattice points? Can such circles be found if the center is not to be a lattice point? What if we require the circle to pass through exactly n lattice points?
- Above qn has a natural restatement if instead of circles, we look at ellipses (either all with a given eccentricity e or with e that can be freely chosen). The ellipses need not be axis parallel.
- And what can one say if the lattice of points has as unit cell not a square but a general parallelogram? And what happens in 3D and higher dimensions?
2. On Zonogons:
https://mathoverflow.net/questions/381781/partitions-of-convex-planar-regions-into-zonogons
A discussion is on...
Here are the main questions:
A zonogon is a centrally symmetric convex polygon.
- Are there convex non-zonogons that can be partitioned into a finite number of (convex) zonogons?
- Same as 1 with the pieces allowed to be nonconvex but centrally symmetric polygons.
3. On Congruent Partitions:
https://mathoverflow.net/questions/381091/on-congruent-partitions-of-planar-regions
Given any integer n, any rectangular region or any sector of a disc (including the full disk as a boundary case) can be cut into n mutually congruent pieces - by equally spaced parallel lines and lines radiating from a point at equal angular spacing respectively.
Intuitively, this property generalizes to some deformations of the rectangle which continue to allow partition into n congruent pieces by mutually parallel and equally spaced polylines or curves for any n and for some deformations of a sector which can be congruent partitioned by mutually congruent curves radiating from a single point. .
Question: Are there any other classes of planar regions which can be cut into n mutually congruent regions for any n? The answer seems negative, but is t
here a proof?
Note: Analogously, in 3D, one readily has parallelopipeds and suitable slices of regions with axial symmetry (sphere, torus, cone...) which can obviously be cut into n mutually congruent 3D regions for any n.
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