Alex Meiburg / Timeroot

“Broadcast coloring” aka “Packing coloring” as mentioned in this paper. Also mentions “packing numbers” η_i. Here η_1 is the independence number, and η_2 is the largest independent set with all vertices more than distance 2, etc. Nice fact: η_2 is preserved by the Mycielskian if there’s no isolated vertices, and η_3 is preserved if connected.

See this – maximum induced path length (“detour number”), maximum induced cycle length, induced path number, and induced path cover – seem related to parameterized complexity (detour number ~= tree-depth (only for sparse graphs?)), and it’s cool that detour number is within a constant factor hard to approximate as independent sets. Check Hostad for info on how hard that is

Bandwidth and … broadcast time for “gossip”?

Average distance-ish things: Wiener, Wiener Sum, Balaban, Kirckhoff

Algebraic connectivity describes mixing time. It has good relationships and bounds. Unfortunately, standards are a bit of a mess of which Laplacian matrix you use. See MathWorld too.

Mathjax testing

\[Hi\]

It’s $ 5^3 $ and $2_5$. I can write in $ \mathbb{r} \bf{r} \nabla_\boldsymbol{r}$

\[\begin{aligned} E = mc^2 \end{aligned}\]

And I can try \[ 3 + 5 \] here and $ 3+5 $ or $3^5$. Symbols:

\[\nabla \delta \Delta \Gamma \gamma \epsilon \varepsilon \times \square \circ \Circle \otimes \oplus\]

$a^2 + b^2 = c^2$ –> note that all equations between these tags will not need escaping!

[ \frac{1}{n^{2}} ]