Disjointness graphs of segments in the space
J Pach, G Tardos, G Tóth - Combinatorics, Probability and Computing, 2021 - cambridge.org
J Pach, G Tardos, G Tóth
Combinatorics, Probability and Computing, 2021•cambridge.orgThe disjointness graph G= G (𝒮) of a set of segments 𝒮 in, where ω (G) denotes the clique
number of G. It follows that 𝒮 has Ω (n1/5) pairwise intersecting or pairwise disjoint
elements. Stronger bounds are established for lines in space, instead of segments. We show
that computing ω (G) and χ (G) for disjointness graphs of lines in space are NP-hard tasks.
However, we can design efficient algorithms to compute proper colourings of G in which the
number of colours satisfies the above upper bounds. One cannot expect similar results for …
number of G. It follows that 𝒮 has Ω (n1/5) pairwise intersecting or pairwise disjoint
elements. Stronger bounds are established for lines in space, instead of segments. We show
that computing ω (G) and χ (G) for disjointness graphs of lines in space are NP-hard tasks.
However, we can design efficient algorithms to compute proper colourings of G in which the
number of colours satisfies the above upper bounds. One cannot expect similar results for …
The disjointness graph G = G(𝒮) of a set of segments 𝒮 in , where ω(G) denotes the clique number of G. It follows that 𝒮 has Ω(n1/5) pairwise intersecting or pairwise disjoint elements. Stronger bounds are established for lines in space, instead of segments.We show that computing ω(G) and χ(G) for disjointness graphs of lines in space are NP-hard tasks. However, we can design efficient algorithms to compute proper colourings of G in which the number of colours satisfies the above upper bounds. One cannot expect similar results for sets of continuous arcs, instead of segments, even in the plane. We construct families of arcs whose disjointness graphs are triangle-free (ω(G) = 2), but whose chromatic numbers are arbitrarily large.
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