• Sep 15, 2019

  Linkage

  • Lee Bollinger, president of Columbia University: “No, I won’t start spying on my foreign-born students” ($\mathbb{M}$).
• Aug 31, 2019

  Linkage

  • Should graduate students be expected to bring refreshments to their doctoral defenses? ($\mathbb{M}$). It can be an imposition, it distracts from preparing from the defense, students on graduate fellowships may not easily afford it, and to some extent it looks like bribery of the examining committee. On the other hand, it’s traditional and it’s hard to break traditions, and a non-hungry committee is a non-hangry committee.
• Aug 29, 2019

  Grid majors

  I’ve written here about grid minors before, more than once. These are grid graphs that you can get from a given graph $G$ as a minor (that is, by removing edges or vertices from $G$ and contracting others of its edges). So, in the other direction, a “grid major” of $G$ must be a grid graph that has $G$ as a minor. These are the subject of my new preprint, “Homotopy height, grid-major height and graph-drawing height” (arXiv:1908.05706, with Therese Biedl, Erin Chambers, Arnaud De Mesmay, and Tim Ophelders, to appear at Graph Drawing).

• Aug 27, 2019

  Congratulations, Dr. Besa!

  Juan Besa’s successful dissertation defense was last Thursday, but I’ve been holding off posting about it here because one of his committee members took ill and couldn’t sign off on it until today.

• Aug 22, 2019

  Serpentine belts

  Many car engines use a serpentine belt, passing across multiple pulleys and tensioner wheels, to transmit mechanical power and timing information from the car’s crankshaft to its alternator, engine fan, water pump, air conditioning, steering pump, and other systems. Another (usually separate) belt, the timing belt, similarly connects the crankshaft to the camshaft, which controls and drives the timing of the engine’s valves. The Volvo bus engine below shows both of these belts:

• Aug 17, 2019

  Footprints in the snow

  Given an abstract optimization problem with multiple solutions, how much partial information about a solution do you have to know in order to uniquely identify that solution? That has been the topic of some of my earlier research, on how many creases of an origami folding pattern you have to force to be mountain or valley folds in order to cause the remaining folds to go the way you want. And it’s the topic of my new preprint “Tracking paths in planar graphs” (arXiv:1908.05445, with Mike Goodrich, James Liu, and Pedro Matias).

• Aug 15, 2019

  Linkage

  • Tricolor pyramids ($\mathbb{M}$). In this logic puzzle by @jsiehler, you have to 3-color hexagonal tiles avoiding 2-colored upright triangles. What interests me is not that, but the following: it’s the time-space diagram of a 3-state cellular automaton (with time flowing upward and each cell taking the color that makes the triangle below it work). But turned $120^\circ$ it’s still the time-space diagram of the same automaton! I haven’t seen this sort of CA symmetry before.
• Aug 10, 2019

  Report from CCCG

  After WADS, I stayed in Edmonton for CCCG. The two conferences have not always been in the same places, but this year they were co-located, and the plan is to continue that pattern in odd years (when WADS is held). As far as I know there are no plans to move CCCG to Scandinavia for SWAT in the even years.

• Aug 9, 2019

  University of Alberta Botanic Gardens

  The WADS excursion was to the University of Alberta Botanic Gardens. Here are a few photos I took there:

• Aug 7, 2019

  Report from WADS

  I’m in Edmonton, Canada for WADS, which just finished, and CCCG, which is just about to begin.

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