Gabriel graph

The Gabriel graph of 100 random points

Points

a

and

b

are Gabriel neighbours, as

c

is outside their diameter circle.

The presence of point

c

within the circle prevents points

a

and

b

from being Gabriel neighbors.

In mathematics and computational geometry, the Gabriel graph of a set $S$ of points in the Euclidean plane expresses one notion of proximity or nearness of those points. Formally, it is the graph $G$ with vertex set $S$ in which any points $p\in S$ and $q\in S$ are adjacent precisely if they are distinct, i.e. $p \neq q$ , and the closed disc of which line segment ${\overline {pq}}$ is a diameter contains no other elements of $S$ . Gabriel graphs naturally generalize to higher dimensions, with the empty disks replaced by empty closed balls. Gabriel graphs are named after K. Ruben Gabriel, who introduced them in a paper with Robert R. Sokal in 1969.

Percolation

A finite site percolation threshold for Gabriel graphs has been proven to exist by Bertin, Billiot & Drouilhet (2002), and more precise values of both site and bond thresholds have been given by Norrenbrock (2014).

Related geometric graphs

The Gabriel graph is a subgraph of the Delaunay triangulation. It can be found in linear time if the Delaunay triangulation is given (Matula & Sokal 1980).

The Gabriel graph contains, as subgraphs, the Euclidean minimum spanning tree, the relative neighborhood graph, and the nearest neighbor graph.

It is an instance of a beta-skeleton. Like beta-skeletons, and unlike Delaunay triangulations, it is not a geometric spanner: for some point sets, distances within the Gabriel graph can be much larger than the Euclidean distances between points (Bose et al. 2006).

References

Bertin, Etienne; Billiot, Jean-Michel; Drouilhet, Rémy (2002), "Continuum percolation in the Gabriel graph", Advances in Applied Probability, 34 (4): 689–701, doi:10.1239/aap/1037990948, MR 1938937 .
Bose, Prosenjit; Devroye, Luc; Evans, William; Kirkpatrick, David (2006), "On the spanning ratio of Gabriel graphs and β-skeletons", SIAM Journal on Discrete Mathematics, 20 (2): 412–427, CiteSeerX 10.1.1.46.4728, doi:10.1137/S0895480197318088, MR 2257270 .
Gabriel, Kuno Ruben; Sokal, Robert Reuven (1969), "A new statistical approach to geographic variation analysis", Systematic Biology, Society of Systematic Biologists, 18 (3): 259–278, doi:10.2307/2412323, JSTOR 2412323 .
Matula, David W.; Sokal, Robert Reuven (1980), "Properties of Gabriel graphs relevant to geographic variation research and clustering of points in the plane", Geogr. Anal., 12 (3): 205–222, doi:10.1111/j.1538-4632.1980.tb00031.x .
Norrenbrock, Christoph (2014), Percolation threshold on planar Euclidean Gabriel Graphs, arXiv:1406.0663, Bibcode:2014arXiv1406.0663N .

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