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Extremal Problems for Finite Sets (Student Mathematical Library) PDF

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STUDENT MATHEMATICAL LIBRARY Volume 86 Extremal Problems for Finite Sets Peter Frankl Norihide Tokushige Extremal Problems for Finite Sets STUDENT MATHEMATICAL LIBRARY Volume 86 Extremal Problems for Finite Sets Peter Frankl Norihide Tokushige Editorial Board SatyanL. Devadoss John Stillwell (Chair) Erica Flapan Serge Tabachnikov 2010 Mathematics Subject Classification. Primary 05-01, 05D05. For additional informationand updates on this book, visit www.ams.org/bookpages/stml-86 Library of Congress Cataloging-in-Publication Data Names: Frankl,P.(Peter),1953-author. |Tokushige,Norihide,1963-author. Title: Extremalproblemsforfinitesets/PeterFrankl,NorihideTokushige. Description: Providence, Rhode Island: AmericanMathematicalSociety, [2018] | Series: Student mathematicallibrary ; volume 86 | Includes bibliographical referencesandindex. Identifiers: LCCN2017061643|ISBN9781470440398(alk. paper) Subjects: LCSH: Extremal problems (Mathematics)| Set theory. | AMS: Com- binatorics – Instructional exposition (textbooks, tutorial papers, etc.). msc | Combinatorics–Extremalcombinatorics–Extremalsettheory. msc Classification: LCCQA295.F8552018|DDC511/.6–dc23 LCrecordavailableathttps://lccn.loc.gov/2017061643 Copying and reprinting. Individual readers of this publication, and nonprofit li- braries acting for them, are permitted to make fair use of the material, such as to copyselectpagesforuseinteachingorresearch. Permissionisgrantedtoquotebrief passagesfromthispublicationinreviews,providedthecustomaryacknowledgmentof thesourceisgiven. Republication,systematiccopying,ormultiplereproductionofanymaterialinthis publicationispermittedonlyunderlicensefromtheAmericanMathematicalSociety. Requests for permission to reuse portions of AMS publication content are handled by the Copyright Clearance Center. For more information, please visit www.ams.org/ publications/pubpermissions. Send requests for translation rights and licensed reprints to reprint-permission @ams.org. (cid:2)c2018bytheauthors. Allrightsreserved. PrintedintheUnitedStatesofAmerica. (cid:2)∞ Thepaperusedinthisbookisacid-freeandfallswithintheguidelines establishedtoensurepermanenceanddurability. VisittheAMShomepageathttps://www.ams.org/ 10987654321 232221201918 Contents Notation vii Chapter 1. Introduction 1 Chapter 2. Operations on sets and set systems 5 Chapter 3. Theorems on traces 13 Chapter 4. The Erd˝os–Ko–Rado Theorem via shifting 19 Chapter 5. Katona’s circle 23 Chapter 6. The Kruskal–Katona Theorem 31 Chapter 7. Kleitman Theorem for no s pairwise disjoint sets 37 Chapter 8. The Hilton–Milner Theorem 43 Chapter 9. The Erd˝os matching conjecture 47 Chapter 10. The Ahlswede–Khachatrian Theorem 53 Chapter 11. Pushing-pulling method 61 Chapter 12. Uniform measure versus product measure 69 Chapter 13. Kleitman’s correlation inequality 77 v vi Contents Chapter 14. r-Cross union families 83 Chapter 15. Random walk method 87 Chapter 16. L-systems 95 Chapter 17. Exponent of a (10,{0,1,3,6})-system 103 Chapter 18. The Deza–Erdo˝s–Frankl Theorem 109 Chapter 19. Fu¨redi’s structure theorem 115 Chapter 20. R¨odl’s packing theorem 121 Chapter 21. Upper bounds using multilinear polynomials 127 Chapter 22. Application to discrete geometry 137 Chapter 23. Upper bounds using inclusion matrices 141 Chapter 24. Some algebraic constructions for L-systems 149 Chapter 25. Oddtown and eventown problems 155 Chapter 26. Tensor product method 161 Chapter 27. The ratio bound 175 Chapter 28. Measures of cross independent sets 181 Chapter 29. Application of semidefinite programming 189 Chapter 30. A cross intersection problem with measures 195 Chapter 31. Capsets and sunflowers 201 Chapter 32. Challenging open problems 211 Bibliography 217 Index 223 Notation • Let R be the set of real numbers. • Let Q be the set of rational numbers. • Let Z be the set of integers. • Let Z ={1,2,3,...} be the set of positive integers. >0 • Let N={0,1,2,...} be the set of nonnegative integers. • Let Z/mZ be the ring of congruence classes modulo m. • Let F denote the q-element field. q • Let Rm×n denote the set of m×n real matrices. • Let F [x] denote the set of polynomials in variable x with q coefficients in F . q • For a positive integer n, let [n]={1,2,...,n}. • For a finite set A, the size (cardinality) of A is denoted by |A| or #A. • For functions f,g :R→R we write – f(x)=o(g(x)) if limx→∞|f(x)/g(x)|=0, – f(x)=O(g(x))if|f(x)|<Cg(x)forallx>x ,where 0 x and C are some fixed constants, 0 – f(x)=Ω(g(x)) if g(x)=O(f(x)), – f(x)=Θ(g(x))iff(x)=O(g(x))andf(x)=Ω(g(x)), – f(n)(cid:4)g(n) if limn→∞f(n)/g(n)=0, vii viii Notation – f(n)∼g(n) if limn→∞f(n)/g(n)=1. • (Kronecker’s delta) δ =1 if i=j and δ =0 if i(cid:6)=j. ij ij • For integers a and b we write a|b to mean that a divides b. • (Disjoint union) We writeA(cid:7)B forA∪B withA∩B =∅. • For a family F ⊂2X and x∈X let (0.1) F(x)={F \{x}:x∈F ∈F}, (0.2) F(x¯)={F :x(cid:6)∈F ∈F}. • We say that two families F,G ⊂2X are isomorphic if G is obtained from F by renaming vertices, that is, if there is a permutation π on X such that G ={{π(x):x∈F}:F ∈F}. In this case we write F ∼=G. • For a family F ⊂2X, the complement family Fc is defined by Fc ={X\F :F ∈F}. • For a family F ⊂ 2X and x ∈ X, the degree of x in F is defined by deg (x) = #{F ∈ F : x ∈ F ∈ F}. If F deg (x)=d for all x∈X, then F is called d-regular. F • Avectorxisusuallyconsideredtobeacolumnvector,and x denotes the ith entry. i • For a matrix A, the transposed matrix is denoted by AT. Theidentitymatrixandtheall-onesmatrixaredenotedby I and J, respectively. If we need to specify the size, then I is the n×n identity matrix. Similarly we write 1 and n 1 for the all-ones vector. n • An n-vertex graph G is a graph with n vertices. The adja- cency matrix A=(a ) of G is an n×n matrix defined by i,j a =1if iand j are adjacent inG anda =0otherwise. i,j i,j • Let V be a vector space over a field F and let U ⊂V be a finite subset. Let spanU denote the subspace spanned by (cid:2) U, that is, spanU ={ α u:α ∈F}. u∈U u u Chapter 1 Introduction Apart from numbers, sets are the most fundamental notion in math- ematics. Arguably the simplest sets are finite sets, that is, sets with a finite number of elements. The present book deals with combina- torial, mostly extremal problems concerning systems of subsets of a given finite set. Let us introduce the basic notation first. For a set X let |X| denote its size, that is, the number of its elements. If|X|=n,thenX iscalledann-elementset. Forapositive integer n let [n] = {1,2,...,n} denote the standard n-element set. The power set 2[n] consists of the 2n subs(cid:3)ets(cid:4)(including [n] and the empty set ∅) of [n]. For 0 ≤ k ≤ n let [n] denote the collection k of all k-element subsets of [n]. A subset F of 2[n] is called a family of subsets. We can think of F ⊂ 2X as a hypergraph. In this case the vertex set is X and the edge set is F itself. In this sen(cid:3)se(cid:4)we sometimes call a member of F an edge of F. A family F ⊂ [n] is k called k-uniform (or a k-uniform hypergraph). To explain the topics in this book, probably it is best to state and prove Sperner’s Theorem, the first result in this area. We need some simple notions. If F (cid:2)F (cid:2)···(cid:2)F 0 1 l then (F ,...,F ) is called a chain of length l. If for a family F no 0 l F,G ∈ F satisfy F (cid:2) G, F is called an antichain. The reason is 1

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