Guenther Shepherd

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Author: Guenther Shepherd

Tessellating Art and the Einstein Problem
While researching the recently solved “Einstein Problem,” I stumbled upon talented individuals who were using this new discovery to build mathematical art. These people equipped me with the tools and inspiration to create some works of my own. In creating this art, I found a new connection to M.C. Escher, a master of tessellation art.

The Einstein Problem

The einstein problem asks if there exists a shape that tiles (covers without gaps or overlaps) a plane aperiodically (without a repeating motif). Just recently a small research team discovered that tile, solving the einstein problem. They discovered not just one tile but an entire family of tiles. They named this family of tiles ‘Specters’.

(Left) A Specter with stylized polyline edges. (center) The underlying edge arraignment of all Specters. (Right) A specter with stylized curved edges.

I was disappointed to learn that the einstein problem has no relation to Albert Einstein. In this case we’re referring to the literal German translation, meaning “one stone”.

A tessellation of Specters. The animation fades between differently stylized edges.

Getting Hands On

The initial discovery was made by David Smith, a retired print technician and self-identified “shape enthusiast.” In his pragmatic methodology he used both software and cardboard cutouts to experiment with tessellation. In turn, I wanted to do some hands-on experimentation too.

I went online to find a tile file for 3D printing, and found more than I expected. People have been decorating the tiles so that when they’re tessellated a design takes form. I downloaded a few of these designs, 3D printed them and then made these mosaics.

Various mosaics made with 3D printed tiles.¹

Notice the gaps in the center of each star in the last image? This is a great example of something unique to aperiodic monotiles; Its only possible to create a repeating motif by leaving gaps between tiles. The only way to close the gaps is to let the tiles flow into aperiodic tessellation. Laying the tiles down this way has an unusual feeling to it, there’s no regular pattern to guide tile placement, and yet, each additional tile has a place it fits perfectly. Every tile has the same simple decoration, but when they’re together a complex design emerges.

Tools

Inspired to create tile decorations of my own, I set out to find the necessary software tools. After some searching, I found exactly what I was looking for on the forum for Rhino 3D. This thread contains an excellent assortment of both scripts and art. I modified an existing tessellation script to work on my tile decorations. I used Rhino 3D to draw my decorations on a source tile and then used Grasshopper to tessellate them.
(First) A single decorated tile that’s used to tessellate the plane. (Second) A glimpse of the grasshopper script used.

After generating the tessellation, I transferred the curves into Adobe Illustrator for coloring.

Art

When tiles come together, something new emerges. This artwork is inspired by structures with emergent characteristics e.g. a network of roads, a multicellular organism, an organic molecule.

Drag the bar on each image to reveal or hide the individual tiles.

Alleys

Mush

Roads

Fungus

Atoms

Cells

Repetition Emerges

Despite being aperiodic, repeating shapes start to emerge as we zoom out.

Large Fungus

Notice the triangle-like pattern? This isn’t a trick of the eye; the repetition is real.

When Specters are tessellated, they can be lumped into small groups. These small groups tile just like hexagons.

Animated fade between tessellated Specters² and tessellated hexagons.

A tessellation of Specters will always have an equivalent tessellation of hexagons, but the two won’t ever perfectly fit inside each other. This is the reason for the emerging repetition, and also the reason the repetition isn’t perfect.

In the end, this art built by tessellating Specters was equivalent to art made by tessellating hexagons.

Returning To Escher

A sculpture inspired by tessellating art of M.C. Escher.³

While making art with Specter is new, making art using hexagons is not. I’m reminded of the tessellating artwork of the late M.C Escher. I encourage the unfamiliar to peruse his playful tessellations.

His unique prospective has long been an inspiration to me. It is a strange feeling to have inadvertently circled back.

Citations
1. 3D printed file authorship by order of appearance. @bengineering on Thingaverse, @ateldsign on Printables, @ateldsign on Printables, @CarlosLuna on Printables. ↩︎
2. This diagram comes from the paper “A chiral aperiodic monotile” by David Smith, Joseph Samuel Myers, Craig S. Kaplan, and Chaim Goodman-Straussis. It’s released under the CC BY license (International 4.0). My modifications to the diagram are shared alike. ↩︎
3. Photograph by Bouwe Brouwer. It’s released under the Creative Commons Attribution-Share Alike 3.0 Unported license. ↩︎
January 3, 2025
3D Printing Merch For Sailors
This last spring I set out to develop a piece of merchandise for the Renton Sailing Center (RSC). To make things fun, I self-imposed a constraint to use my 3D printer. The final product found its way into classes, races, and outreach, connecting with sailors new and old.

The product is just a branded whistle on a lanyard. While simple in appearance, this product took a few wrong turns in development before ending up where it needed to be.

The final product.

What To Make

I settled on whistles since they’re both useful to sailors and cheap to make. As an added bonus, there’s already countless open-source whistle designs to build off of. After a bit of research, I found a model that would be perfect for adding my own graphics onto: The Flat Pocket Whistle by Jonas Daehnert.

The First Prototype And Feedback

I made a little vector graphics sailboat and embossed it alongside the RSC initials.

First attempt in various sizes.

Then I collected feedback from members about the design. Responses were mixed:
- Members felt no connection to graphics and colors used.
- Sailors struggled to find storage for a loose whistle on their sailing outfit.
- Leadership was unsure how to dispense the merchandise.
The New Design

Back to the drawing board! First to get fixed was the graphics and colors. I was sad to see my little sailboat drawing go, but a much better graphic was clear to me now. I vectorized the Renton Sailing Center’s Burgee and updated the colors to match.

Final graphics.

Using an established symbol increased people’s connection with the whistle.

I addressed the issue of storage by adding a cheap lanyard to each whistle. While I was disappointed that my product was no longer 100% 3D printed, this change was necessary to unlock the full utility of the whistle. I was surprised by how readily people accepted the whistle on a lanyard compared to the confusion that came without one.

Whistle on lanyard.

I also came up with a plan to disperse the whistles. The RCS doesn’t maintain its own merch shop, so there was no way to sell the whistles to members. Instead, I invited the RSC’s Activities Coordinators (called Dock Masters) to give away the whistles at their discretion. Whistles could be given out to anyone who participates in club activates like volunteering or taking a class.

Conclusion

Over this last summer about 100 of these whistles went out to the community. They went to kids at outreach events, students who completed classes, members who volunteered their time, and a myriad of others.

This simple design is both useful and put smiles on faces.

Me rocking the RSC whistle.
December 19, 2024
Hello world!

Welcome to my personal website. I’m putting this together as a way to share my thoughts with the world. I’ll be making digestible write ups about my projects, processes, and products. Navigate to any of my blog posts, get reading, and see the world through my eyes.

June 21, 2024