The Erdős unit distance problem for small point sets

Boris Alexeev; Dustin G. Mixon; Hans Parshall

The Erdős unit distance problem for small point sets

Boris Alexeev, Dustin G. Mixon, Hans Parshall

Abstract

We improve the best known upper bound on the number of edges in a unit-distance graph on $n$ vertices for each $n\in\{16,\ldots,30\}$. When $n\leq 21$, our bounds match the best known lower bounds, and we fully enumerate the densest unit-distance graphs in these cases. On the combinatorial side, our principle technique is to more efficiently generate $\mathcal{F}$-free graphs for a set of forbidden subgraphs $\mathcal{F}$. On the algebraic side, we are able to determine programmatically whether many graphs are unit-distance, using a custom embedder that is more efficient in practice than tools such as cylindrical algebraic decomposition.

The Erdős unit distance problem for small point sets

Abstract

We improve the best known upper bound on the number of edges in a unit-distance graph on

vertices for each

. When

, our bounds match the best known lower bounds, and we fully enumerate the densest unit-distance graphs in these cases. On the combinatorial side, our principle technique is to more efficiently generate

-free graphs for a set of forbidden subgraphs

. On the algebraic side, we are able to determine programmatically whether many graphs are unit-distance, using a custom embedder that is more efficient in practice than tools such as cylindrical algebraic decomposition.

The Erdős unit distance problem for small point sets

Abstract

The Erdős unit distance problem for small point sets

Abstract

Paper Structure