In 1932, Karol Borsuk showed[2] that an ordinary 3-dimensional ball in Euclidean space can be easily dissected into 4 solids, each of which has a smaller diameter than the ball, and generally n-dimensional ball can be covered with n + 1compactsets of diameters smaller than the ball. At the same time he proved that nsubsets are not enough in general. The proof is based on the Borsuk–Ulam theorem. That led Borsuk to a general question:[2]
Die folgende Frage bleibt offen: Lässt sich jede beschränkte Teilmenge E des Raumes in (n + 1) Mengen zerlegen, von denen jede einen kleineren Durchmesser als E hat?
The following question remains open: Can every bounded subset E of the space be partitioned into (n + 1) sets, each of which has a smaller diameter than E?
— Drei Sätze über die n-dimensionale euklidische Sphäre
The question was answered in the positive in the following cases:
n = 2 — which is the original result by Karol Borsuk (1932).
n = 3 — shown by Julian Perkal (1947),[3] and independently, 8 years later, by H. G. Eggleston (1955).[4] A simple proof was found later by Branko Grünbaum and Aladár Heppes.
The problem was finally solved in 1993 by Jeff Kahn and Gil Kalai, who showed that the general answer to Borsuk's question is no.[9] They claim that their construction shows that n + 1 pieces do not suffice for n = 1325 and for each n > 2014. However, as pointed out by Bernulf Weißbach,[10] the first part of this claim is in fact false. But after improving a suboptimal conclusion within the corresponding derivation, one can indeed verify one of the constructed point sets as a counterexample for n = 1325 (as well as all higher dimensions up to 1560).[11]
Their result was improved in 2003 by Hinrichs and Richter, who constructed finite sets for n ≥ 298, which cannot be partitioned into n + 11 parts of smaller diameter.[1]
In 2013, Andriy V. Bondarenko had shown that Borsuk's conjecture is false for all n ≥ 65.[12] Shortly after, Thomas Jenrich derived a 64-dimensional counterexample from Bondarenko's construction, giving the best bound up to now.[13][14]
Apart from finding the minimum number n of dimensions such that the number of pieces α(n) > n + 1, mathematicians are interested in finding the general behavior of the function α(n). Kahn and Kalai show that in general (that is, for n sufficiently large), one needs many pieces. They also quote the upper bound by Oded Schramm, who showed that for every ε, if n is sufficiently large, .[15] The correct order of magnitude of α(n) is still unknown.[16] However, it is conjectured that there is a constant c > 1 such that α(n) > cn for all n ≥ 1.
^As Hinrichs and Richter say in the introduction to their work,[1] the "Borsuk's conjecture [was] believed by many to be true for some decades" (hence commonly called a conjecture) so "it came as a surprise when Kahn and Kalai constructed finite sets showing the contrary". It's worth noting, however, that Karol Borsuk has formulated the problem just as a question, not suggesting the expected answer would be positive.
Referencesedit
^ abHinrichs, Aicke; Richter, Christian (28 August 2003). "New sets with large Borsuk numbers". Discrete Mathematics. Elsevier. 270 (1–3): 137–147. doi:10.1016/S0012-365X(02)00833-6.
^ abBorsuk, Karol (1933), "Drei Sätze über die n-dimensionale euklidische Sphäre" (PDF), Fundamenta Mathematicae (in German), 20: 177–190, doi:10.4064/fm-20-1-177-190
^Perkal, Julian (1947), "Sur la subdivision des ensembles en parties de diamètre inférieur", Colloquium Mathematicum (in French), 2: 45
^Hadwiger, Hugo (1946), "Mitteilung betreffend meine Note: Überdeckung einer Menge durch Mengen kleineren Durchmessers", Commentarii Mathematici Helvetici (in German), 19 (1): 72–73, doi:10.1007/BF02565947, MR 0017515, S2CID 121053805
^Riesling, A. S. (1971), "Проблема Борсука в трехмерных пространствах постоянной кривизны" [Borsuk's problem in three-dimensional spaces of constant curvature] (PDF), Ukr. Geom. Sbornik (in Russian), Kharkov State University (now National University of Kharkiv), 11: 78–83
^Dekster, Boris (1995), "The Borsuk conjecture holds for bodies of revolution", Journal of Geometry, 52 (1–2): 64–73, doi:10.1007/BF01406827, MR 1317256, S2CID 121586146
^Alon, Noga (2002), "Discrete mathematics: methods and challenges", Proceedings of the International Congress of Mathematicians, Beijing, 1: 119–135, arXiv:math/0212390, Bibcode:2002math.....12390A
Further readingedit
Oleg Pikhurko, , course notes.
Andrei M. Raigorodskii, The Borsuk partition problem: the seventieth anniversary, Mathematical Intelligencer26 (2004), no. 3, 4–12.
Raigorodskii, Andreii M. (2008). "Three lectures on the Borsuk partition problem". In Young, Nicholas; Choi, Yemon (eds.). Surveys in contemporary mathematics. London Mathematical Society Lecture Note Series. Vol. 347. Cambridge University Press. pp. 202–247. ISBN978-0-521-70564-6. Zbl 1144.52005.
borsuk, conjecture, borsuk, problem, geometry, historical, reasons, note, incorrectly, called, question, discrete, geometry, named, after, karol, borsuk, example, hexagon, into, three, pieces, smaller, diameter, contents, problem, also, note, references, furth. The Borsuk problem in geometry for historical reasons note 1 incorrectly called Borsuk s conjecture is a question in discrete geometry It is named after Karol Borsuk An example of a hexagon cut into three pieces of smaller diameter Contents 1 Problem 2 See also 3 Note 4 References 5 Further reading 6 External linksProblem editIn 1932 Karol Borsuk showed 2 that an ordinary 3 dimensional ball in Euclidean space can be easily dissected into 4 solids each of which has a smaller diameter than the ball and generally n dimensional ball can be covered with n 1 compact sets of diameters smaller than the ball At the same time he proved that n subsets are not enough in general The proof is based on the Borsuk Ulam theorem That led Borsuk to a general question 2 Die folgende Frage bleibt offen Lasst sich jede beschrankte Teilmenge E des Raumes R n displaystyle mathbb R n nbsp in n 1 Mengen zerlegen von denen jede einen kleineren Durchmesser als E hat The following question remains open Can every bounded subset E of the space R n displaystyle mathbb R n nbsp be partitioned into n 1 sets each of which has a smaller diameter than E Drei Satze uber die n dimensionale euklidische Sphare The question was answered in the positive in the following cases n 2 which is the original result by Karol Borsuk 1932 n 3 shown by Julian Perkal 1947 3 and independently 8 years later by H G Eggleston 1955 4 A simple proof was found later by Branko Grunbaum and Aladar Heppes For all n for smooth convex bodies shown by Hugo Hadwiger 1946 5 6 For all n for centrally symmetric bodies shown by A S Riesling 1971 7 For all n for bodies of revolution shown by Boris Dekster 1995 8 The problem was finally solved in 1993 by Jeff Kahn and Gil Kalai who showed that the general answer to Borsuk s question is no 9 They claim that their construction shows that n 1 pieces do not suffice for n 1325 and for each n gt 2014 However as pointed out by Bernulf Weissbach 10 the first part of this claim is in fact false But after improving a suboptimal conclusion within the corresponding derivation one can indeed verify one of the constructed point sets as a counterexample for n 1325 as well as all higher dimensions up to 1560 11 Their result was improved in 2003 by Hinrichs and Richter who constructed finite sets for n 298 which cannot be partitioned into n 11 parts of smaller diameter 1 In 2013 Andriy V Bondarenko had shown that Borsuk s conjecture is false for all n 65 12 Shortly after Thomas Jenrich derived a 64 dimensional counterexample from Bondarenko s construction giving the best bound up to now 13 14 Apart from finding the minimum number n of dimensions such that the number of pieces a n gt n 1 mathematicians are interested in finding the general behavior of the function a n Kahn and Kalai show that in general that is for n sufficiently large one needs a n 1 2 n textstyle alpha n geq 1 2 sqrt n nbsp many pieces They also quote the upper bound by Oded Schramm who showed that for every e if n is sufficiently large a n 3 2 e n textstyle alpha n leq left sqrt 3 2 varepsilon right n nbsp 15 The correct order of magnitude of a n is still unknown 16 However it is conjectured that there is a constant c gt 1 such that a n gt cn for all n 1 See also editHadwiger s conjecture on covering convex bodies with smaller copies of themselves Kahn Kalai conjectureNote edit As Hinrichs and Richter say in the introduction to their work 1 the Borsuk s conjecture was believed by many to be true for some decades hence commonly called a conjecture so it came as a surprise when Kahn and Kalai constructed finite sets showing the contrary It s worth noting however that Karol Borsuk has formulated the problem just as a question not suggesting the expected answer would be positive References edit a b Hinrichs Aicke Richter Christian 28 August 2003 New sets with large Borsuk numbers Discrete Mathematics Elsevier 270 1 3 137 147 doi 10 1016 S0012 365X 02 00833 6 a b Borsuk Karol 1933 Drei Satze uber die n dimensionale euklidische Sphare PDF Fundamenta Mathematicae in German 20 177 190 doi 10 4064 fm 20 1 177 190 Perkal Julian 1947 Sur la subdivision des ensembles en parties de diametre inferieur Colloquium Mathematicum in French 2 45 Eggleston H G 1955 Covering a three dimensional set with sets of smaller diameter Journal of the London Mathematical Society 30 11 24 doi 10 1112 jlms s1 30 1 11 MR 0067473 Hadwiger Hugo 1945 Uberdeckung einer Menge durch Mengen kleineren Durchmessers Commentarii Mathematici Helvetici in German 18 1 73 75 doi 10 1007 BF02568103 MR 0013901 S2CID 122199549 Hadwiger Hugo 1946 Mitteilung betreffend meine Note Uberdeckung einer Menge durch Mengen kleineren Durchmessers Commentarii Mathematici Helvetici in German 19 1 72 73 doi 10 1007 BF02565947 MR 0017515 S2CID 121053805 Riesling A S 1971 Problema Borsuka v trehmernyh prostranstvah postoyannoj krivizny Borsuk s problem in three dimensional spaces of constant curvature PDF Ukr Geom Sbornik in Russian Kharkov State University now National University of Kharkiv 11 78 83 Dekster Boris 1995 The Borsuk conjecture holds for bodies of revolution Journal of Geometry 52 1 2 64 73 doi 10 1007 BF01406827 MR 1317256 S2CID 121586146 Kahn Jeff Kalai Gil 1993 A counterexample to Borsuk s conjecture Bulletin of the American Mathematical Society 29 1 60 62 arXiv math 9307229 doi 10 1090 S0273 0979 1993 00398 7 MR 1193538 S2CID 119647518 Weissbach Bernulf 2000 Sets with Large Borsuk Number PDF Beitrage zur Algebra und Geometrie in German 41 2 417 423 Jenrich Thomas 2018 On the counterexamples to Borsuk s conjecture by Kahn and Kalai arXiv 1809 09612v4 Bondarenko Andriy 2014 2013 On Borsuk s Conjecture for Two Distance Sets Discrete amp Computational Geometry 51 3 509 515 arXiv 1305 2584 doi 10 1007 s00454 014 9579 4 MR 3201240 Jenrich Thomas 2013 A 64 dimensional two distance counterexample to Borsuk s conjecture arXiv 1308 0206 Bibcode 2013arXiv1308 0206J Jenrich Thomas Brouwer Andries E 2014 A 64 Dimensional Counterexample to Borsuk s Conjecture Electronic Journal of Combinatorics 21 4 P4 29 doi 10 37236 4069 MR 3292266 Schramm Oded 1988 Illuminating sets of constant width Mathematika 35 2 180 189 doi 10 1112 S0025579300015175 MR 0986627 Alon Noga 2002 Discrete mathematics methods and challenges Proceedings of the International Congress of Mathematicians Beijing 1 119 135 arXiv math 0212390 Bibcode 2002math 12390AFurther reading editOleg Pikhurko Algebraic Methods in Combinatorics course notes Andrei M Raigorodskii The Borsuk partition problem the seventieth anniversary Mathematical Intelligencer 26 2004 no 3 4 12 Raigorodskii Andreii M 2008 Three lectures on the Borsuk partition problem In Young Nicholas Choi Yemon eds Surveys in contemporary mathematics London Mathematical Society Lecture Note Series Vol 347 Cambridge University Press pp 202 247 ISBN 978 0 521 70564 6 Zbl 1144 52005 External links editWeisstein Eric W Borsuk s Conjecture MathWorld Retrieved from https en wikipedia org w index php title Borsuk 27s conjecture amp oldid 1167456693, wikipedia, wiki, book, books, library,
