n^2 + 1$ unit equilateral triangles cannot cover an equilateral triangle of side $> n$ if all triangles have parallel sides

• Main Authors: Baek, Jineon, Lee, Seewoo
• Format: Journal Article
• Language: English
• Published: 15.06.2023
• Subjects: Mathematics - Combinatorics; Mathematics - Metric Geometry
• DOI: 10.48550/arxiv.2306.09533

Conway and Soifer showed that an equilateral triangle $T$ of side $n + \varepsilon$ with sufficiently small $\varepsilon > 0$ can be covered by $n^2 + 2$ unit equilateral triangles. They conjectured that it is impossible to cover $T$ with $n^2 + 1$ unit equilateral triangles no matter how small $\varepsilon$ is. We show that if we require all sides of the unit equilateral triangles to be parallel to the sides of $T$ (e.g. $\bigtriangleup$ and $\bigtriangledown$), then it is impossible to cover $T$ of side $n + \varepsilon$ with $n^2 + 1$ unit equilateral triangles for any $\varepsilon > 0$. As the coverings of $T$ by Conway and Soifer only involve triangles with sides parallel to $T$, our result determines the exact minimum number $n^2+2$ of unit equilateral triangles with all sides parallel to $T$ that cover $T$. We also determine the largest value $\varepsilon = 1/(n + 1)$ (resp. $\varepsilon = 1 / n$) of $\varepsilon$ such that the equilateral triangle $T$ of side $n + \varepsilon$ can be covered by $n^2+2$ (resp. $n^2 + 3$) unit equilateral triangles with sides parallel to $T$, where the first case is achieved by the construction of Conway and Soifer.