Degree diameter problem: Difference between revisions

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In graph theory, the degree diameter problem is the problem of finding the largest possible graph Template:Mvar (in terms of the size of its vertex set Template:Mvar) of diameter Template:Mvar such that the largest degree of any of the vertices in Template:Mvar is at most Template:Mvar. The size of Template:Mvar is bounded above by the Moore bound; for Template:Math and Template:Math, only the Petersen graph, the Hoffman-Singleton graph, and possibly graphs (not yet proven to exist) of diameter Template:Math and degree Template:Math attain the Moore bound. In general, the largest degree-diameter graphs are much smaller in size than the Moore bound.

Let ${\displaystyle n_{d,k}}$ be the maximum possible number of vertices for a graph with degree at most d and diameter k. Then ${\displaystyle n_{d,k}\le M_{d,k}}$, where ${\displaystyle M_{d,k}}$ is the Moore bound:

${\displaystyle M_{d,k}=\{\begin{array}{cc}1+d\frac{(d-1{)}^k-1}{d-2}& \text{ if }d>2\\ 2k+1& \text{ if }d=2\end{array}}$

This bound is attained for very few graphs, thus the study moves to how close there exist graphs to the Moore bound. For asymptotic behaviour note that ${\displaystyle M_{d,k}=d^k+O(d^{k-1})}$.

Define the parameter ${\displaystyle {\mu }_k=\underset{d\to \mathrm{\infty }}{\mathrm{lim\; inf}}\frac{n_{d,k}}{d^k}}$. It is conjectured that ${\displaystyle {\mu }_k=1}$ for all k. It is known that ${\displaystyle {\mu }_1={\mu }_2={\mu }_3={\mu }_5=1}$ and that ${\displaystyle {\mu }_4\ge 1/4}$.

• Cage (graph theory)
• Table of the largest known graphs of a given diameter and maximal degree
• Table of vertex-symmetric degree diameter digraphs
• Maximum degree-and-diameter-bounded subgraph problem

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