Random regular graph

A random r-regular graph is a graph selected from ${\mathcal {G}}_{n,r}$ , which denotes the probability space of all r-regular graphs on $n$ vertices, where $3\leq r<n$ and $nr$ is even.^[1] It is therefore a particular kind of random graph, but the regularity restriction significantly alters the properties that will hold, since most graphs are not regular.

Properties of random regular graphs[edit]

As with more general random graphs, it is possible to prove that certain properties of random $m$ –regular graphs hold asymptotically almost surely. In particular, for $r\geq 3$ , a random r-regular graph of large size is asymptotically almost surely r-connected.^[2] In other words, although $r$ –regular graphs with connectivity less than $r$ exist, the probability of selecting such a graph tends to 0 as $n$ increases.

If $\epsilon >0$ is a positive constant, and $d$ is the least integer satisfying

$(r-1)^{d-1}\geq (2+\epsilon )rn\ln n$

then, asymptotically almost surely, a random r-regular graph has diameter at most d. There is also a (more complex) lower bound on the diameter of r-regular graphs, so that almost all r-regular graphs (of the same size) have almost the same diameter.^[3]

The distribution of the number of short cycles is also known: for fixed $m\geq 3$ , let $Y_{3},Y_{4},...Y_{m}$ be the number of cycles of lengths up to $m$ . Then the $Y_{i}$ are asymptotically independent Poisson random variables with means^[4]

$\lambda _{i}={\frac {(r-1)^{i}}{2i}}$

Algorithms for random regular graphs[edit]

It is non-trivial to implement the random selection of r-regular graphs efficiently and in an unbiased way, since most graphs are not regular. The pairing model (also configuration model) is a method which takes nr points, and partitions them into n buckets with r points in each of them. Taking a random matching of the nr points, and then contracting the r points in each bucket into a single vertex, yields an r-regular graph or multigraph. If this object has no multiple edges or loops (i.e. it is a graph), then it is the required result. If not, a restart is required.^[5]

A refinement of this method was developed by Brendan McKay and Nicholas Wormald.^[6]

References[edit]

^ Béla Bollobás, Random Graphs, 2nd edition, Cambridge University Press (2001), section 2.4: Random Regular Graphs
^ Bollobás, section 7.6: Random Regular Graphs
^ Bollobás, section 10.3: The Diameter of Random Regular Graphs
^ Bollobás, section 2.4: Random Regular Graphs (Corollary 2.19)
^ N. Wormald, "Models of Random Regular Graphs," in Surveys in Combinatorics, Cambridge University Press (1999), pp 239-298
^ B. McKay and N. Wormald, "Uniform Generation of Random Regular Graphs of Moderate Degree," Journal of Algorithms, Vol. 11 (1990), pp 52-67: [1]

[1] Béla Bollobás, Random Graphs, 2nd edition, Cambridge University Press (2001), section 2.4: Random Regular Graphs

[2] Bollobás, section 7.6: Random Regular Graphs

[3] Bollobás, section 10.3: The Diameter of Random Regular Graphs

[4] Bollobás, section 2.4: Random Regular Graphs (Corollary 2.19)

[5] N. Wormald, "Models of Random Regular Graphs," in Surveys in Combinatorics, Cambridge University Press (1999), pp 239-298

[6] B. McKay and N. Wormald, "Uniform Generation of Random Regular Graphs of Moderate Degree," Journal of Algorithms, Vol. 11 (1990), pp 52-67: [1]

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