Brouwer–Haemers graph
| Brouwer–Haemers graph | |
|---|---|
 | |
| Vertices | 81 |
| Edges | 810 |
| Radius | 2 |
| Diameter | 2 |
| Girth | 3 |
| Chromatic number | 7 |
| Properties | |
| Table of graphs and parameters | |
In the mathematical field of graph theory, the Brouwer–Haemers graph is a 20-regular undirected graph with 81 vertices and 810 edges. It is a strongly regular graph, a distance-transitive graph, and a Ramanujan graph. Although its construction is folklore, it was named after Andries Brouwer and Willem H. Haemers, who proved its uniqueness as a strongly regular graph.
Construction
The Brouwer–Haemers graph has several related algebraic constructions. One of the simplest is as a degree-4 generalized Paley graph: it can be defined by making a vertex for each element in the finite field [math]\displaystyle{ GF(81) }[/math] and an edge for every two elements that differ by a fourth power.[1][2]
Properties
The Brouwer–Haemers graph is the unique strongly regular graph with parameters (81, 20, 1, 6). This means that it has 81 vertices, 20 edges per vertex, 1 triangle per edge, and 6 length-two paths connecting each non-adjacent pair of distinct vertices.[3] As a strongly regular graph with the third parameter equal to 1, the Brouwer–Haemers graph has the property that every edge belongs to a unique triangle; that is, it is locally linear. Finding large dense graphs with this property is one of the formulations of the Ruzsa–Szemerédi problem.[4]
As well as being strongly regular it is a distance-transitive graph.[5]
History
Although Brouwer writes that this graph's "construction is folklore", and cites as an early reference a 1964 paper on Latin squares by Dale M. Mesner,[1] it is named after Andries Brouwer and Willem H. Haemers, who in 1992 published a proof that it is the only strongly regular graph with the same parameters.[3]
Related graphs
The Brouwer–Haemers graph is the first in an infinite family of Ramanujan graphs defined as generalized Paley graphs over fields of characteristic three.[2] With the [math]\displaystyle{ 3\times 3 }[/math] Rook's graph and the Games graph, it is one of only three possible strongly regular graphs whose parameters have the form [math]\displaystyle{ \bigl((n^2+3n-1)^2,n^2(n+3),1,n(n+1)\bigr) }[/math].[6]
It should be distinguished from the Sudoku graph, a different 20-regular 81-vertex graph. The Sudoku graph is derived from Sudoku puzzles by making a vertex for each square of the puzzle and connecting two squares by an edge when they belong to the same row, column, or [math]\displaystyle{ 3\times 3 }[/math] block of the puzzle. It has many 9-vertex cliques and requires 9 colors in any graph coloring; a 9-coloring of this graph describes a solved Sudoku puzzle.[7][8] In contrast, for the Brouwer–Haemers graph, the largest cliques are the triangles and the number of colors needed is 7.[5]
References
- ↑ 1.0 1.1 "Brouwer–Haemers graph", Descriptions of various graphs, https://www.win.tue.nl/~aeb/graphs/Brouwer-Haemers.html, retrieved 2019-02-11
- ↑ 2.0 2.1 Podestá, Ricardo A.; Videla, Denis E. (2018), The spectra of generalized Paley graphs and applications
- ↑ 3.0 3.1 "Structure and uniqueness of the (81,20,1,6) strongly regular graph", Discrete Mathematics 106/107: 77–82, 1992, doi:10.1016/0012-365X(92)90532-K
- ↑ Clark, L. H.; Entringer, R. C.; McCanna, J. E.; Székely, L. A. (1991), "Extremal problems for local properties of graphs", The Australasian Journal of Combinatorics 4: 25–31, https://ajc.maths.uq.edu.au/pdf/4/ocr-ajc-v4-p25.pdf
- ↑ 5.0 5.1 Weisstein, Eric W.. "Brouwer–Haemers Graph". http://mathworld.wolfram.com/Brouwer-HaemersGraph.html.
- ↑ Bondarenko, Andriy V.; Radchenko, Danylo V. (2013), "On a family of strongly regular graphs with [math]\displaystyle{ \lambda=1 }[/math]", Journal of Combinatorial Theory, Series B 103 (4): 521–531, doi:10.1016/j.jctb.2013.05.005
- ↑ Gago-Vargas, Jesús; Hartillo-Hermoso, Maria Isabel; Martín-Morales, Jorge; Ucha-Enríquez, Jose Maria (2006), "Sudokus and Gröbner bases: Not only a divertimento", in Ganzha, Victor G.; Mayr, Ernst W.; Vorozhtsov, Evgenii V., Computer Algebra in Scientific Computing, 9th International Workshop, CASC 2006, Chisinau, Moldova, September 11-15, 2006, Proceedings, Lecture Notes in Computer Science, 4194, Springer, pp. 155–165, doi:10.1007/11870814_13
- ↑ "Sudoku squares and chromatic polynomials", Notices of the American Mathematical Society 54 (6): 708–717, 2007, https://www.ams.org/notices/200706/tx070600708p.pdf
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