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Bibliographic Details
Main Author: Goertzen, Tom
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.15080
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author Goertzen, Tom
author_facet Goertzen, Tom
contents This work presents a construction method for interlocking assemblies based on planar crystallographic symmetries. Planar crystallographic groups, also known as wallpaper groups, correspond to tessellations of the plane with a tile, called a fundamental domain, such that the action of the group can be used to tessellate the plane with the given tile. The main idea of this method is to extend the action of a wallpaper group so that it acts on three-dimensional space and places two fundamental domains into parallel planes. Next, we interpolate between these domains to obtain a block that serves as a candidate for interlocking assemblies. We show that the resulting blocks can be triangulated, and we can also approximate blocks with smooth surfaces using this approach. Finally, we show that there exists a family of blocks derived from this construction that can be tiled in multiple ways, characterised by generalised Truchet tiles. The assemblies of one block in this family, which we call RhomBlock, correspond to tessellations with lozenges.
format Preprint
id arxiv_https___arxiv_org_abs_2405_15080
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Constructing Interlocking Assemblies with Crystallographic Symmetries
Goertzen, Tom
Computational Geometry
Combinatorics
This work presents a construction method for interlocking assemblies based on planar crystallographic symmetries. Planar crystallographic groups, also known as wallpaper groups, correspond to tessellations of the plane with a tile, called a fundamental domain, such that the action of the group can be used to tessellate the plane with the given tile. The main idea of this method is to extend the action of a wallpaper group so that it acts on three-dimensional space and places two fundamental domains into parallel planes. Next, we interpolate between these domains to obtain a block that serves as a candidate for interlocking assemblies. We show that the resulting blocks can be triangulated, and we can also approximate blocks with smooth surfaces using this approach. Finally, we show that there exists a family of blocks derived from this construction that can be tiled in multiple ways, characterised by generalised Truchet tiles. The assemblies of one block in this family, which we call RhomBlock, correspond to tessellations with lozenges.
title Constructing Interlocking Assemblies with Crystallographic Symmetries
topic Computational Geometry
Combinatorics
url https://arxiv.org/abs/2405.15080