The workshop was largely based on Labs 9.1 and 9.6 from my (free) book

*Geometry Labs*. I quite enjoyed leading those sessions, as I learned a lot both about the topic at hand, and about how to best present it. The approach in

*Geometry Labs*was based on separating a very basic introduction from further enrichment questions. The reason is that the basics are helpful as a contrast to Euclidean distance on the coordinate plane, and help students better understand the latter, while the further explorations were unlikely to be pursued in very many classes.

However in a session for teachers, or for a math club or an 11th or 12th grade elective, there is no reason for that separation. Moreover, in preparing those sessions, I got interested in other questions, including taxicab parabolas. The result is that I created a stand-alone worksheet on Taxicab Geometry that incorporates much of the material from

*Geometry Labs,*somewhat reorganized and edited, and to which I added some interesting extensions. Download it here, and learn a lot about taxicab geometry! (If you use activities from

*Geometry Labs,*be sure to periodically check the

*Geometry Labs*home page for any new connections, corrections, extensions and revisions.)

This bizarre figure is the answer to one of the problems on the worksheet. Can you figure out what was being asked?

Here's a hint:

What prompted this post is that last Saturday, I attended the San Francisco Math Teachers Circle's last meeting of the school year. The session was led by Dr. Cornelia Van Cott, a math prof at USF. After an exploration of taxicab circles and ellipses, we got to think about what circles would look like in other metrics. This was both entertaining and thought-provoking. Each metric had a fun name: the elevator metric, the post office metric, the teleportation metric. Unfortunately, the resulting circles were not as satisfying as the elegant circles of Euclidean or taxicab geometry. Cornelia explained that to be as mathematically productive as taxicab distance, a metric needs to be a norm, i.e. satisfy additional constraints. She wrote about this in an award-winning article for the February 2016 issue of

*Math Horizons*(MAA's journal for undergraduates.) The title of the article is "A Pi Day of the Century Every Year", because different norms lead to different values for π, and thus, you could get a value like 3.1418, which would be perfect for next year.

What blew me away was Dr. Van Cott's explanation of how you can reverse the whole thing. Instead of defining the norm, and seeing what a unit circle would look like, you can go the other way: define your unit circle, and build the norm from it. So taxicab geometry would be derived from a square with vertices at (1, 0), (0, 1), (-1, 0) and (0, -1) (or in fact any square centered at the origin!) Other geometries could be derived by starting from any convex figure that is symmetric around the origin, e.g. a 2n-gon or an ellipse. Apparently, such geometries are called Minkowski geometries. Read the article!

If this sort of exploration is interesting to you, you should join or start a Math Teachers Circle in your area!

--Henri

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