1993
DOI: 10.1016/0012-365x(93)90166-q
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Largest planar graphs of diameter two and fixed maximum degree

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1997
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Cited by 29 publications
(20 citation statements)
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“…We now consider the degree-diameter problem for graphs with given Euler genus. Note that the case of planar graphs has been widely studied [12,13,19,25,30,31].Šiagiová and Simanjuntak [27] proved that for every graph G with Euler genus g, Theorem 14. For all > 0 there is a constant c such that for every graph G with Euler genus g, maximum degree ∆ and diameter k,…”
Section: Now Consider the Even K Case For ∆mentioning
confidence: 99%
“…We now consider the degree-diameter problem for graphs with given Euler genus. Note that the case of planar graphs has been widely studied [12,13,19,25,30,31].Šiagiová and Simanjuntak [27] proved that for every graph G with Euler genus g, Theorem 14. For all > 0 there is a constant c such that for every graph G with Euler genus g, maximum degree ∆ and diameter k,…”
Section: Now Consider the Even K Case For ∆mentioning
confidence: 99%
“…Consider the graph G in Figure 1; this graph was constructed in [2] to show that Let S be a surface other than the sphere (for the ''spherical''result we refer to [5]) and let G be as in Figure 1 with vertices a 1 , . . .…”
Section: Proof Of Theoremmentioning
confidence: 99%
“…One of the possible ways was proposed in [2] where it is proved that a planar graph of diameter two and maximum degree d ≥ 8 has at most (3/2)d + 1 vertices. In addition, as shown in [5], this bound is best possible in the following (strong) sense: For each d ≥ 8 there exists a planar triangulation of diameter two and maximum degree d that contains exactly (3/2)d + 1 vertices.…”
Section: Introductionmentioning
confidence: 98%
“…She proved that, in this case, the number of vertices is n 3 2 ∆ + 1 if ∆ 8, and that this bound is best possible. Later, Hell and Seyffarth [9] showed that this result also holds for the larger class of all simple planar graphs. Yang, Lin, and Dai [19] solved the remaining case ∆ < 8 with D = 2, for both graph classes.…”
Section: Introductionmentioning
confidence: 88%