My paper has algorithms for finding a minimum-weight Hamiltonian cycle (when it exists), in an \(n\)-vertex graph of maximum degree three, in time \(O(2^{n/3})\), and for listing all Hamiltonian cycles in time \(O(2^{3n/8})\). Both have since been improved by others. Maciej Liśkiewicz and Martin R. Schuster gave an algorithm for the minimum-weight cycle with time \(O(1.2553^n)\) in their paper “A new upper bound for the traveling salesman problem in cubic graphs” [J. Discrete Algorithms 2014], and Heidi Gebauer gave an algorithm for listing all cycles in time \(O(1.276^n)\) in her paper “Enumerating all Hamilton cycles and bounding the number of Hamilton cycles in 3-regular graphs” [Elect. J. Combinatorics 2011]. Despite these improvements, I think it’s interesting enough to examine what the issue was with my paper and how to work around it.

The bug is in the case analysis for the algorithm to list all Hamiltonian cycles. The minimum-weight algorithm includes a case where a triangle is contracted into a single vertex. However, for some reason the cycle-listing algorithm omitted that case, and then later tried to assume there were no triangles, but without a valid justification for this assumption. It’s not impossible that the rest of the analysis goes through without using the assumption of no triangles, but working out the details looks messy.

Both algorithms in the paper work with a more general problem in which, together with an input graph, one is given “forced edges” which are required to be included in any Hamiltonian cycle. This allows certain simplifications in which, for instance, paths through degree-two vertices or paths of multiple forced edges can be compressed into single forced edges. It’s important when listing cycles that the input is a simple graph, not a multigraph, because multigraphs can have as many as \(O(2^{n/2})\) Hamiltonian cycles. So, when this sort of compression produces a forced edge that’s parallel to an unforced edge, the unforced edge can be deleted, and when it produces two parallel forced edges, there can be no Hamiltonian cycle and the algorithm backtracks. After these simplifications, one can assume that the graph is simple and 3-regular rather than merely having maximum degree three, and that no two forced edges are adjacent. But it might still have some triangles.

With that as background, it is indeed possible to eliminate the triangles. Here are the missing cases to do so.

• If a triangle includes a forced edge, then the opposite edge entering the triangle should also become forced. (The paper included a case with the opposite implication, but this direction is needed to preserve the forcing information after the contraction of a triangle, below.) So in the image below, if either of the two thick edges is forced, the other one should be too.

• If there exists a triangle that does not share any of its edges with another triangle, contract it. Hamiltonian cycles in the contracted graph correspond one-for-one with Hamiltonian cycles in the uncontracted graph, and (with no shared edges) this contraction will not create any parallel edges.

• If there exist two triangles that share an edge, then there are two paths through their four vertices that might extend to Hamiltonian cycles. If only one of these two paths is consistent with the forced edges within this subgraph, add the rest of its edges to the forced set; their contraction will eliminate the triangles. Otherwise, make two recursive branches, each with one of the two paths added to the forced set. Each branch eliminates four previously-unforced edges, consistent with the analysis of the other cases in this part of the paper.

As far as I know, another problem from the same paper remains open. The paper constructs a family of cubic graphs that have \(2^{n/3}\) Hamiltonian cycles, but the cycle-listing algorithm proves only that the number of cycles is always \(O(2^{3n/8})\), a bigger number. Gebauer’s paper improves the upper bound, but it still does not match the lower bound. Is \(2^{n/3}\) the maximum number of Hamiltonian cycles in an \(n\)-vertex 3-regular graph?

(Discuss on Mastodon)

Now, whenever you subdivide one rectangle into two smaller rectangles in this recursion, connect the centerpoints of the two new rectangles by a line segment. The union of all of these line segments is a fractal, the H-tree.

It comes arbitrarily close to any point of the initial rectangle, so its closure is the whole rectangle and its fractal dimension is two. But the points that belong to the H-tree (normalized with one corner of the rectangle at the origin) all have at least one coordinate that is a dyadic rational multiple of one of the rectangle sides. So as a subset of a countable union of axis-parallel lines, the H-tree has measure zero.

At each finite level of recursive construction (using closed line segments) the union of the segments is a kind of topological tree called a dendroid. Roughly this means that its a connected compact set with a unique arc connecting each two points. The full H-tree is not compact (it is not closed: its closure is a different set, the whole rectangle). But this is not the only way that it is not tree-like: it no longer has the property of having a unique arc connecting each two points! This is because it has certain simple closed curves as subsets, within which you can connect pairs of points in two different ways around the curve.

In this it differs from some other fractal space-filling trees like the one below, which might be called an X-tree. An X-tree can be formed by recursively subdividing a square into four smaller squares, adding an open line segment for the diagonal of each square. Or, instead, you could form an X-tree the way my code drew it: start with a grid of a power of two size, draw the diagonals of the whole grid, and then remove (or redraw as white) the grid points whose coordinates have binary representations ending in differing numbers of \(0\) bits. You can find arcs of the X-tree whose two ends get arbitrarily close to each other, but they do not form simple closed curves because their limit point is missing. Instead, in the H-tree, a branch of the tree can have an interior point of another segment as its limit point, so the limit point is not missing.

Looking again at the H-tree, one can see additional tree-like structures in the negative space where the H-tree isn’t.

It’s common to see planar surfaces divided up by pairs of interdigitating trees: the two trees of a river network and of the ridgelines separating the river’s branches are a familiar example.

I’ve used this idea of interdigitating trees in several of my research papers and in several old posts here. The complement of a tree would have a tree-like skeleton (for instance the X-tree has a \(45^\circ\)-rotated X-tree-like dual skeleton). But because the H-tree is not a tree, its interdigitated forest has many separate fractal trees. These trees are not exactly the same as the connected components of the complement of the H-tree: like the H-tree itself their points have one coordinate that is a dyadic rational multiple of the initial rectangle side, so they miss many points of the outer rectangle. But I think they have the same closures as the connected components.

(Discuss on Mastodon)

Online guides

I have found three helpful guides to accessible LaTeX (not specifically about ltx-talk): “Using LaTeX to produce accessible PDF” from the LaTeX tagging project, “A quick primer on modifying existing LaTeX for digital accessibility” by Richard Wong at Rice University, and “Creating accessible PDFs in LaTeX” from Overleaf. If you are using some unusual LaTeX packages or document classes, the LaTeX tagging project also maintains a useful list of the tagging status of LaTeX packages and classes. This includes the information that beamer cannot generate accessible tagged pdf but ltx-talk can. These links got me from a state of having no idea how to generate accessible pdf files from my slides to a state where I thought it might be possible, and helped me start setting up my files. Most of the rest was from carefully reading log files and accessibility reports and then experimenting to figure out what to change in order to make the errors and warnings go away.

This posting is not intended as a substitute for these guides, but rather as a collection of tips and tricks for converting beamer slide decks into accessible ltx-talk slide decks.

Compilation

To compile ltx-talk files and produce accessible tagged pdf files, you need to run lualatex instead of pdflatex. Sometimes you need as many as four runs: one run of lualatex to get an aux file with bibliography items, a run of bibtex, and then three more runs of lualatex before it stabilizes and stops telling you to run again because the labels have changed or because it miscalculated page numbers and added a dummy page. Check the log files for these things.

You also need to be running a very recent version of LaTeX, dated November 2025 or more recent. TeX Live 2025, released in March 2025, will not work. The new TeX Live 2026 pretest will. I use MacOS and have not figured out whether there is any way to access the TeX Live pretest on a Mac. Instead I have been using either Overleaf (through its Overleaf Labs feature) or a linux install on some departmental machines accessible to me via ssh. This already includes the ltx-talk package; you do not need to install it separately.

There are apparently incompatibilities between recent releases of LaTeX and the cleveref package. Fortunately, my slide decks do not use cleveref.

Preamble

The magic incantation at the start of your file is different, of course, because it’s a different package but also because tagged pdf needs a metadata command before the document class to set it up. The old incantation (for, say, a \(16\times 9\) target aspect ratio) was:

\documentclass[aspectratio=169]{beamer}

Instead, now it is:

\DocumentMetadata{
  lang          = en,
  pdfstandard   = {ua-2,a-4f},
  tagging       = on,
  tagging-setup = {math/setup=mathml-SE} 
}
\documentclass[aspect-ratio=16:9]{ltx-talk}

Change the lang = en line if you are writing in a different language than English. Wong suggests instead tagging-setup={math/setup=mathml-SE,math/alt/use}; I have no idea whether that would be an improvement.

The other important change in the LaTeX preamble works around what I think is a bug in ltx-talk. By default, it tags frame titles with an h4-level header tag. But there are no h1, h2, or h3-level header tags that it produces. This causes Acrobat’s accessibility checker to complain about header nesting. Maybe the right thing to do is to add some h1, h2, and h3-level tags, for instance on the title page, but I haven’t figured out how to do that. Instead, I changed the frame titles to h1, with

\tagpdfsetup{
  role / new-tag = frametitle / H1
}

The default appearance produced by ltx-talk is close to beamer with the structure skin, but not quite the same. You can change it in your LaTeX preamble but the documentation for how to change it is somewhat lacking. What worked for me is to look for code like DeclareTemplateInterface in ltx-talk.cls and to use \EditInstance to change it. For instance I use the code

\definecolor{ksblue}{RGB}{0,129,205}
\EditInstance{header}{std}{
  color            = ksblue,
  left-hspace      = 0cm plus 1fil,
  right-hspace     = 0cm plus 1fil
}

to change the color of frame titles and center them. I also use

\renewcommand{\labelitemi}{ {\footnotesize\color{ksblue}$\blacktriangleright$}}
\renewcommand{\labelitemii}{ {\scriptsize\color{ksblue}$\blacktriangleright$}}

to make big triangular itemize bullets like beamer, instead of the default little circular ones. (So far I have only converted slides with two levels of itemize nesting.)

Figures

In the article content, the easiest change to explain but the most time-consuming one, for me, is adding alt-text to all images. The syntax is straightforward: \includegraphics[alt={Alt text goes here}]{filename}. I have seen big online debates on what alt-text should describe and how detailed it should be. The important thing to remember is that you’re not trying to describe the image in vivid-enough detail that an AI image generator could make a copy of it. The purpose of these things is to substitute for the image when people use a screenreader to convert your slides into spoken text. So it should be concise enough that it doesn’t interrupt the flow of the text when spoken but informative enough that people using a screenreader don’t miss out on the meaning. For complicated mathematical examples that can be a big ask.

I had one figure, created as a pdf file by Adobe Illustrator, that triggered a flate decode error in lualatex. The same image had worked correctly in pdflatex and beamer. The compilation continued with a warning but the figure did not render correctly in the compiled file. I could not figure out why. The only workaround I could find was to save it as a different pdf version in Illustrator.

Environments

Getting ltx-talk to run required a few changes elsewhere in my LaTeX files. I was using \begin{frame}{Title of frame}, and ltx-talk has an option to make that work, but by default it doesn’t. Instead you need to use \begin{frame}\frametitle{Title of frame}. Using unicode characters such as an en-dash in a frametitle leads to a “unreferenced destination” error; code them in ASCII (in this case a double hyphen) instead.

Columns need to be delimited by \begin{column}{size}…\end{column} instead of starting them by \column. (Also the spacing between columns is different between beamer and ltx-talk so you may need some reformatting to get them to look good.) And the same thing about using an environment rather than a command applies to some formatting things like \flushright: it won’t cause a LaTeX error but it will cause the tagging to get mismatched with a warning message at the end of the log. Then you have to work through your file trying to figure out which slide caused the mismatch.

If you use verbatim environments, beamer needed to mark this by \begin{frame}[fragile]. This still works in ltx-talk but with a different syntax, \begin{frame*}. If you use tabular environments, you need to tell LaTeX which rows of your table are header rows. See the accessibility guides linked above.

Formulas

There is lua code somewhere that generates mathml tags for the mathematical formulas (I think this is the main reason that you need to use lualatex). It is not as robust as LaTeX itself. Using code like \bigl and \bigr will cause a tagging mismatch; use \left and \right instead and let LaTeX choose for itself how big to make the parentheses. Using \dots inside math often does not work at all, and in one case using $\dots$ inside a tabular environment caused lualatex to crash hard. Use \ldots or \cdots instead. Also, I think using mathematics inside \text inside more mathematics caused a tagging mismatch; don’t nest them like that. This code will also generate files with names of the form *-luamml-mathml.html; add that pattern to your .gitignore file.

I had one deck (discussing the Ackermann function) containing the expression \(\approx 2\times 10^{19728}\). This caused lualatex to freeze. The only hypothesis I can find is that it looks like a formula whose numerical value can be calculated and that the mathml conversion code was trying to calculate it, using a slow exponentiation algorithm.

Sections

If your deck has 21 or more slides, Acrobat will complain if it doesn’t also have bookmarks for navigation within sections of the deck. I did this using \pdfbookmark[1]{Bookmark name}{Bookmark name} at the start of each section. Maybe there is a better way. This would be a good place to put more higher-level header tags than the H4 frame titles, if I knew how.

Many of my slide decks have bibtex bibliography sections. I don’t generally show these when speaking but I want them to be part of the pdf files of my slide decks that I distribute. I like to use natbib for this (plus the doi package to make the external links and dois work properly). But natbib never worked correctly in beamer; I needed to add the code \newcommand{\newblock}{} to the preamble to make it work. In ltx-talk, I also needed to add \newcommand{\thebibliography}{\relax} before loading natbib. Then you can just put your bibliography within one of the frames. A problem I have not found a good workaround for is that beamer allows multi-frame bibliographies with \begin{frame}[allowframebreaks]. However, ltx-talk does not and reading its documentation reveals that its developer is very hostile to long bibliographies (such as would arise in a talk incorporating a literature review). The only workaround I have found is to use a small-enough font size (in some cases \tiny) to allow the whole bibliography to fit on one slide. This is mildly problematic with respect to accessibility but better than truncating the bibliography because it overflows the slide.

(Discuss on Mastodon)

Anyway, on to the links:

• 175 years of 3d viewing failure, starting with the 1851 Brewer Stereoscope, in honor of the big mid-January layoffs and cuts at Meta’s Reality Labs and Metaverse divisions.

• The joys of data archaeology (\(\mathbb{M}\)): I happened to be looking up one of my old papers, “On triangulating three-dimensional polygons” (with Gill Barequet and Matt Dickerson, SoCG 1996 and CGTA 1998) when I realized that, although both published versions are open-access, the journal version has figures that have somehow been made completely illegible (all the grayscale is blacked out) and the conference version’s figures weren’t well reproduced either. My ftp links for alternative copies were long dead (nobody uses nor provides ftp any more). I do still have LaTeX source for the final version, but I couldn’t find all the figure files (probably buried as attachments in an associated unix-mail archive). And when I tried to compile it, even without having found all of the figures, the idiosyncratic LaTeX formatting from however long ago caused the text to keep switching mid-paragraph between two very different font sizes. Fortunately I was able to recover a preprint of the full journal version from one of those academic-web paper scrapers. The text is a little spindly because of the old formatting, but the figures are better. I put it back online and linked it from my publications page.

  The main result of the paper, by the way, is that it is NP-complete to test whether a 3d polygon has a non-self-intersecting triangulation. Knotted polygons obviously don’t, but the polygons from the NP-completeness reduction are unknotted. Unknotted curves always form the boundary of a disk, but triangulating this disk might require many internal vertices, and the triangulations studied in this paper are allowed to use only the given vertices.

• Purdue rescinds departmental graduate acceptance letters to over 100 students (\(\mathbb{M}\), via), mostly from China, under an unwritten university policy formulated in response to Trump administration pressure. A faculty quote: “when we’ve asked to get it in writing, [administrators] say they haven’t done it because then somebody could sue us.” As usual don’t read comments on the Y.

• Nice profile of Robert Lang from 2024 by NASA (\(\mathbb{M}\)), explaining how his methods for designing the folding patterns for his artistic origami came out of methods he had been applying to pack components into integrated optical circuitry, and then later how he brought the same expertise back to NASA in work for them on packing components into space missions.

• Warm winter weather and a holiday weekend made for a busy day at our local beach (\(\mathbb{M}\)). A few more photos.

  

• A surprising fact about polyhedral self-duality (\(\mathbb{M}\)): There exist self-dual polyhedra for which the duality is not a self-inverse permutation of the set of vertices and faces. Robin Houston makes a 3d printable model.

• An old Mastodon thread about triangular billiards and a new Wikipedia article about triangular billiards. The question is: if you made a billiards table in an arbitrary triangular shape, would it always be possible to find a starting position and direction for a billiards ball to travel so that (with ideal reflection and no friction) it would return to the same position and direction after finitely many bounces? It’s solved for triangles whose angles are acute or rational multiples of \(\pi\), but open in general.

• Why do so many authors of enjoyable books end up being so problematic (\(\mathbb{M}\))? J. K. Rowling, transphobe. Neil Gaiman, sexual predator. And now I’m saddened to learn that R. A. Lafferty was a Holocaust denier. (Via a Wikipedia discussion where another editor, who does believe the accusations against Lafferty, was falsely accused of white nationalism for enforcing Wikipedia’s strict sourcing standards in this case. The source above does not meet those standards, but it is good enough for me personally.)

• The 2026 Michael and Sheila Held Prize goes to Irit Dinur, Subhash Khot, Guy Kindler, Dor Minzer and Muli Safra for their work on the 2-to-2 games theorem (\(\mathbb{M}\)).

• Temporary outage of full-text search in Google Books (\(\mathbb{M}\), via), only for books with preview rather than full view or snippet view. A few days later it started working again, as mysteriously as it stopped.

• Calls for the IMU to publicly address the situation of the US hosting the International Congress of Mathematicians this year. Meanwhile the French Mathematical Society has announced that they will not be participating.

  As I wrote in response: This is a big issue for academic conference planning in general, and not just for the ICM. My European friends are telling me that nobody they know there is currently willing to travel to the US and that for some of them there are institutional barriers in place (including issues of the security of institution-owned electronics) that prevent them from doing so. I have also talked to Canadians who have stopped attending conferences they would otherwise travel to in the US. Meanwhile there are also many people within the US who are unable to travel elsewhere for fear of not being allowed to return (which is not a strong argument for hosting international conferences in the US, but does raise problems for conference organizers elsewhere who might normally expect strong US attendance).

• LICS breaks with ACM and IEEE, becoming an independently-run conference.

• Domes made from rings of trapezoids topped by a pyramid of isosceles triangles have been seen in architecture since the construction of the Pantheon, and studied in geometry since della Francesca’s 15th-century De quinque corporibus regularibus. But what are they called? One possible answer: trapezium domes.

• Generative AI and Wikipedia editing: What we learned in 2025 (\(\mathbb{M}\), via), from the Wiki Education project, which mainly interfaces Wikipedia with academic course projects involving editing Wikipedia. Their takeaway message: “Wikipedia editors should never copy and paste the output from generative AI chatbots like ChatGPT into Wikipedia articles.”

  In more detail, they used Pangram to detect AI-written content, then checked it by hand (finding very few false positives!). They found only a low rate of hallucinated sources. However, more concerningly, in more than 2/3 of the flagged articles, they found sourced sentences whose sources did not contain the information in the sentence. More strongly, “For most of the articles Pangram flagged as written by GenAI, nearly every cited sentence in the article failed verification.” This also led to a high rate of wasted WikiEdu staff time cleaning up after the student-made AI additions (“far more time attempting to verify facts in AI-generated articles than if we’d simply done the research and writing ourselves”).

• The staircase paradox gets linked from BoingBoing (\(\mathbb{M}\)).