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Hanani–Tutte theorem

December 18, 2023

In topological graph theory, the Hanani–Tutte theorem is a result on the parity of edge crossings in a graph drawing. It states that every drawing in the plane of a non-planar graph contains a pair of independent edges (not both sharing an endpoint) that cross each other an odd number of times. Equivalently, it can be phrased as a planarity criterion: a graph is planar if and only if it has a drawing in which every pair of independent edges crosses evenly (or not at all).[1]

History edit

The result is named after Haim Hanani, who proved in 1934 that every drawing of the two minimal non-planar graphs K5 and K3,3 has a pair of edges with an odd number of crossings,[2] and after W. T. Tutte, who stated the full theorem explicitly in 1970.[3] A parallel development of similar ideas in algebraic topology has been credited to Egbert van Kampen, Arnold S. Shapiro, and Wu Wenjun.[4][5][6][7][8][9]

Applications edit

One consequence of the theorem is that testing whether a graph is planar may be formulated as solving a system of linear equations over the finite field of order two. These equations may be solved in polynomial time, but the resulting algorithms are less efficient than other known planarity tests.[1]

Generalizations edit

For other surfaces S than the plane, a graph can be drawn on S without crossings if and only if it can be drawn in such a way that all pairs of edges cross an even number of times; this is known as the weak Hanani–Tutte theorem for S. The strong Hanani–Tutte theorem states that a graph can be drawn without crossings on S if and only if it can be drawn in such a way that all independent pairs of edges cross an even number of times, without regard for the number of crossings between edges that share an endpoint;[10] this strong version does not hold for all surfaces,[11] but it is known to hold for the plane, the projective plane and the torus.[12]

The same approach, in which one shows that pairs of edges with an even number of crossings can be disregarded or eliminated in some type of graph drawing and uses this fact to set up a system of linear equations describing the existence of a drawing, has been applied to several other graph drawing problems, including upward planar drawings,[13] drawings minimizing the number of uncrossed edges,[14][15] and clustered planarity.[16]

References edit

  1. ^ a b Schaefer, Marcus (2013), "Toward a theory of planarity: Hanani–Tutte and planarity variants", Journal of Graph Algorithms and Applications, 17 (4): 367–440, doi:10.7155/jgaa.00298, MR 3094190.
  2. ^ Chojnacki, Ch. (1934), "Über wesentlich unplättbare Kurven im dreidimensionalen Raume", Fundamenta Mathematicae, Institute of Mathematics Polish Academy of Sciences, 23 (1): 135–142, doi:10.4064/fm-23-1-135-142. See in particular (1), p. 137.
  3. ^ Tutte, W. T. (1970), "Toward a theory of crossing numbers", Journal of Combinatorial Theory, 8: 45–53, doi:10.1016/s0021-9800(70)80007-2, MR 0262110.
  4. ^ Levow, Roy B. (1972), "On Tutte's algebraic approach to the theory of crossing numbers", Proceedings of the Third Southeastern Conference on Combinatorics, Graph Theory, and Computing (Florida Atlantic Univ., Boca Raton, Fla., 1972), Florida Atlantic Univ., Boca Raton, Fla., pp. 315–314, MR 0354426.
  5. ^ Schaefer, Marcus, "Hanani–Tutte and related results", in Bárány, I.; Böröczky, K. J.; Tóth, G. F.; et al. (eds.), Geometry—Intuitive, Discrete, and Convex—A Tribute to László Fejes Tóth (PDF), Bolyai Society Mathematical Studies, Berlin: Springer
  6. ^ van Kampen, E. R. (1933), "Komplexe in euklidischen Räumen", Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg, 9 (1): 72–78, doi:10.1007/BF02940628, MR 3069580, S2CID 121909529.
  7. ^ Wu, Wen-Tsün (1955), "On the realization of complexes in Euclidean spaces. I", Acta Mathematica Sinica, 5: 505–552, MR 0076334.
  8. ^ Shapiro, Arnold (1957), "Obstructions to the imbedding of a complex in a Euclidean space. I. The first obstruction", Annals of Mathematics, Second Series, 66 (2): 256–269, doi:10.2307/1969998, JSTOR 1969998, MR 0089410.
  9. ^ Wu, Wen Jun (1985), "On the planar imbedding of linear graphs. I", Journal of Systems Science and Mathematical Sciences, 5 (4): 290–302, MR 0818118. Continued in 6 (1): 23–35, 1986.
  10. ^ Pelsmajer, Michael J.; Schaefer, Marcus; Stasi, Despina (2009), "Strong Hanani-Tutte on the projective plane", SIAM Journal on Discrete Mathematics, 23 (3): 1317–1323, CiteSeerX 10.1.1.217.7182, doi:10.1137/08072485X, MR 2538654.
  11. ^ https://arxiv.org/abs/1709.00508. {{cite web}}: Missing or empty |title= (help)
  12. ^ https://arxiv.org/abs/2009.01683. {{cite web}}: Missing or empty |title= (help)
  13. ^ Fulek, Radoslav; Pelsmajer, Michael J.; Schaefer, Marcus; Štefanković, Daniel (2013), "Hanani–Tutte, monotone drawings, and level-planarity", in Pach, János (ed.), Thirty essays on geometric graph theory, Springer, ISBN 978-1-4614-0110-0.
  14. ^ Pach, János; Tóth, Géza (2000), "Which crossing number is it anyway?", Journal of Combinatorial Theory, Series B, 80 (2): 225–246, doi:10.1006/jctb.2000.1978, MR 1794693.
  15. ^ Pelsmajer, Michael J.; Schaefer, Marcus; Štefankovič, Daniel (2007), "Removing even crossings", Journal of Combinatorial Theory, Series B, 97 (4): 489–500, doi:10.1016/j.jctb.2006.08.001, MR 2325793.
  16. ^ Gutwenger, C.; Mutzel, P.; Schaefer, M., "Practical experience with Hanani–Tutte for testing c-planarity", 2014 Proceedings of the Sixteenth Workshop on Algorithm Engineering and Experiments (ALENEX), pp. 86–97, doi:10.1137/1.9781611973198.9.

December 18, 2023
hanani, tutte, theorem, topological, graph, theory, result, parity, edge, crossings, graph, drawing, states, that, every, drawing, plane, planar, graph, contains, pair, independent, edges, both, sharing, endpoint, that, cross, each, other, number, times, equiv. In topological graph theory the Hanani Tutte theorem is a result on the parity of edge crossings in a graph drawing It states that every drawing in the plane of a non planar graph contains a pair of independent edges not both sharing an endpoint that cross each other an odd number of times Equivalently it can be phrased as a planarity criterion a graph is planar if and only if it has a drawing in which every pair of independent edges crosses evenly or not at all 1 Contents 1 History 2 Applications 3 Generalizations 4 ReferencesHistory editThe result is named after Haim Hanani who proved in 1934 that every drawing of the two minimal non planar graphs K5 and K3 3 has a pair of edges with an odd number of crossings 2 and after W T Tutte who stated the full theorem explicitly in 1970 3 A parallel development of similar ideas in algebraic topology has been credited to Egbert van Kampen Arnold S Shapiro and Wu Wenjun 4 5 6 7 8 9 Applications editOne consequence of the theorem is that testing whether a graph is planar may be formulated as solving a system of linear equations over the finite field of order two These equations may be solved in polynomial time but the resulting algorithms are less efficient than other known planarity tests 1 Generalizations editFor other surfaces S than the plane a graph can be drawn on S without crossings if and only if it can be drawn in such a way that all pairs of edges cross an even number of times this is known as the weak Hanani Tutte theorem for S The strong Hanani Tutte theorem states that a graph can be drawn without crossings on S if and only if it can be drawn in such a way that all independent pairs of edges cross an even number of times without regard for the number of crossings between edges that share an endpoint 10 this strong version does not hold for all surfaces 11 but it is known to hold for the plane the projective plane and the torus 12 The same approach in which one shows that pairs of edges with an even number of crossings can be disregarded or eliminated in some type of graph drawing and uses this fact to set up a system of linear equations describing the existence of a drawing has been applied to several other graph drawing problems including upward planar drawings 13 drawings minimizing the number of uncrossed edges 14 15 and clustered planarity 16 References edit a b Schaefer Marcus 2013 Toward a theory of planarity Hanani Tutte and planarity variants Journal of Graph Algorithms and Applications 17 4 367 440 doi 10 7155 jgaa 00298 MR 3094190 Chojnacki Ch 1934 Uber wesentlich unplattbare Kurven im dreidimensionalen Raume Fundamenta Mathematicae Institute of Mathematics Polish Academy of Sciences 23 1 135 142 doi 10 4064 fm 23 1 135 142 See in particular 1 p 137 Tutte W T 1970 Toward a theory of crossing numbers Journal of Combinatorial Theory 8 45 53 doi 10 1016 s0021 9800 70 80007 2 MR 0262110 Levow Roy B 1972 On Tutte s algebraic approach to the theory of crossing numbers Proceedings of the Third Southeastern Conference on Combinatorics Graph Theory and Computing Florida Atlantic Univ Boca Raton Fla 1972 Florida Atlantic Univ Boca Raton Fla pp 315 314 MR 0354426 Schaefer Marcus Hanani Tutte and related results in Barany I Boroczky K J Toth G F et al eds Geometry Intuitive Discrete and Convex A Tribute to Laszlo Fejes Toth PDF Bolyai Society Mathematical Studies Berlin Springer van Kampen E R 1933 Komplexe in euklidischen Raumen Abhandlungen aus dem Mathematischen Seminar der Universitat Hamburg 9 1 72 78 doi 10 1007 BF02940628 MR 3069580 S2CID 121909529 Wu Wen Tsun 1955 On the realization of complexes in Euclidean spaces I Acta Mathematica Sinica 5 505 552 MR 0076334 Shapiro Arnold 1957 Obstructions to the imbedding of a complex in a Euclidean space I The first obstruction Annals of Mathematics Second Series 66 2 256 269 doi 10 2307 1969998 JSTOR 1969998 MR 0089410 Wu Wen Jun 1985 On the planar imbedding of linear graphs I Journal of Systems Science and Mathematical Sciences 5 4 290 302 MR 0818118 Continued in 6 1 23 35 1986 Pelsmajer Michael J Schaefer Marcus Stasi Despina 2009 Strong Hanani Tutte on the projective plane SIAM Journal on Discrete Mathematics 23 3 1317 1323 CiteSeerX 10 1 1 217 7182 doi 10 1137 08072485X MR 2538654 https arxiv org abs 1709 00508 a href Template Cite web html title Template Cite web cite web a Missing or empty title help https arxiv org abs 2009 01683 a href Template Cite web html title Template Cite web cite web a Missing or empty title help Fulek Radoslav Pelsmajer Michael J Schaefer Marcus Stefankovic Daniel 2013 Hanani Tutte monotone drawings and level planarity in Pach Janos ed Thirty essays on geometric graph theory Springer ISBN 978 1 4614 0110 0 Pach Janos Toth Geza 2000 Which crossing number is it anyway Journal of Combinatorial Theory Series B 80 2 225 246 doi 10 1006 jctb 2000 1978 MR 1794693 Pelsmajer Michael J Schaefer Marcus Stefankovic Daniel 2007 Removing even crossings Journal of Combinatorial Theory Series B 97 4 489 500 doi 10 1016 j jctb 2006 08 001 MR 2325793 Gutwenger C Mutzel P Schaefer M Practical experience with Hanani Tutte for testing c planarity 2014 Proceedings of the Sixteenth Workshop on Algorithm Engineering and Experiments ALENEX pp 86 97 doi 10 1137 1 9781611973198 9 Retrieved from https en wikipedia org w index php title Hanani Tutte theorem amp oldid 1185838699, wikipedia, wiki, book, books, library,

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