Your search keyword '"David Conlon"' showing total 81 results

1. Random multilinear maps and the Erdős box problem

Author

David Conlon, Cosmin Pohoata, and Dmitriy Zakharov

Subjects

Mathematics, QA1-939

Abstract

Random multilinear maps and the Erdős box problem, Discrete Analysis 2021:17, 8 pp. A major theme in extremal combinatorics is determining the maximum number of edges that a graph or hypergraph can have if it does not contain a certain fixed graph or hypergraph. In the case of graphs, Turán's theorem gives an exact result when the forbidden subgraph is the complete graph $K_r$ (the maximum number of edges is attained when the graph is an $(r-1)$-partite graph with vertex sets as equal as possible in size), and the Erdős-Stone theorem shows that if the forbidden subgraph has chromatic number $r$ then the same example is at least asymptotically best possible. When $r=2$, meaning that the forbidden subgraph is bipartite, the Erdős-Stone theorem merely tells us that the asymptotic density of the graph is zero, which can be proved by a relatively simple direct argument, first noted by Kővári, Sós and Turán. The _Zarankiewicz problem_, which has led to a large amount of research, is to obtain more precise bounds for the number of edges. Even for general complete bipartite graphs there is a significant gap between the best known upper and lower bounds. One case of interest is that of 4-cycles. If $G$ is a graph with $n$ vertices and we write $N(x)$ for the neighbourhood of a vertex $x$, then the number of edges of $G$ is $\sum_x|N(x)|$ (ignoring a factor 2) and the number of labelled 4-cycles, including degenerate ones, is $\sum_{x,y}|N(x)\cap N(y)|^2$. By Cauchy-Schwarz, the latter quantity is at least $n^{-2}(\sum_{x,y}|N(x)\cap N(y)|)^2$. But $\sum_{x,y}|N(x)\cap N(y)|$ counts the number of labelled and possibly degenerate paths of length 2, so it is equal to $\sum_z|N(z)|^2$, which is up to a constant also the number of degenerate 4-cycles. Thus, there is a non-degenerate cycle provided that $$n^{-2}(\sum_z|N(z)|^2)^2\gg\sum_z|N(z)|^2,$$ or in other words provided that $\sum_z|N(z)|^2\gg n^2$. But by Cauchy-Schwarz again, $\sum_z|N(z)|^2\geq n^{-1}(\sum_z|N(z)|)^2=m^2n^{-1}$. Thus, if $m\gg n^{3/2}$, then $G$ contains a non-degenerate 4-cycle. One might expect an upper bound proved in as natural a way as this to be matched by a lower bound given by the standard technique of picking a random graph and removing a few edges. However, if we choose edges independently with probability $p$, then the expected number of (labelled and possibly degenerate) 4-cycles is $p^4n^4$ while the number of edges is $pn^2$ (up to a constant), so for this to work we need $p^3\gg n^{-2}$, which results in a graph with around $n^{4/3}$ edges instead of $n^{3/2}$. Nevertheless, the $n^{3/2}$ bound can be shown to be sharp using a construction due to Klein that appears in a paper of Erdős. Define a graph by taking the vertex set to be $\mathbb F_p^2$ and join $(x_1,y_1)$ to $(x_2,y_2)$ if $y_1+y_2=(x_1+x_2)^2$. If $(x_1,y_1), (x_2,y_2), (x_3,y_3), (x_4,y_4)$ forms a 4-cycle in this graph, then setting $a_i=x_i+x_{i+1}$ (where $i+1$ is interpreted as 1 when $i=4$), we have that $a_1+a_3=a_2+a_4$ and $a_1^2+a_3^2=a_2^2+a_4^2$. This implies that $a_1-a_2=a_4-a_3$ and $a_1^2-a_2^2=a_4^2-a_3^2$, which implies that either $a_1=a_2$ or $a_1+a_2=a_4+a_3$, and therefore that $a_1=a_4$ and $a_2=a_3$. Thus, all 4-cycles are degenerate. There are many situations like this in extremal graph theory and extremal combinatorics more generally, where random constructions work reasonably well, but are outperformed by explicit algebraic constructions. However, for many of these situations, even the best known algebraic constructions do not give bounds that match what is known in the other direction. Recently, an interesting new method has emerged, which is a sort of hybrid of the random and algebraic approaches. Though the roots of the idea can be found earlier, it took off properly in 2014 with an influential paper by Boris Bukh entitled [Random algebraic construction of extremal graphs](https://arxiv.org/abs/1409.3856). (A somewhat different mixture of randomness and algebra can also be found in Peter Keevash's remarkable constructions of designs from the same year.) Broadly speaking, Bukh's insight was that if a random construction has algebraic aspects to it, then it is sometimes possible to show that if a forbidden configuration is present, then some much larger configuration must also be present. It is easier to rule out the larger configuration, and this ultimately leads to a better bound. Bukh's example was a bipartite graph with vertex sets equal to $\mathbb F_q^s$, with $x$ joined to $y$ if and only if $(x,y)$ is a zero of a random polynomial in $2s$ variables of degree at most $d$ in each variable (for suitably chosen $d$). The randomness of the polynomial is enough for the calculation of various moments, but the all-important non-randomness arises because the size of the zero set of a polynomial is tightly constrained: the zero set itself has a dimension $k$ and the size of the set must be approximately $q^k$. In particular, if it is not bounded, then it must be at least comparable to $q$. This paper concerns the natural hypergraph generalization of the 4-cycle problem above. That is, one is looking for the maximum number of edges in a $d$-partite $d$-uniform hypergraph that contains no complete $d$-partite subhypergraph with two vertices in each vertex class. If the vertex sets of the hypergraph are $X_1,\dots,X_d$ and one represents edges by points in $X_1\times\dots\times X_d$, then this forbidden configuration is a set of the form $Y_1\times\dots\times Y_d$ where each $Y_i$ is a set of size 2: that is, it is a discrete aligned cuboid, which explains the name "box problem". Alternatively, if we think of the edges of the hypergraph as simplices, then the forbidden configuration is a $d$-dimensional octahedron (often known as a _cross-polytope_). One motivation for these extremal problems is that $d$-dimensional octahedra are important in the theory of quasirandomness: just as a graph is quasirandom if it has as few 4-cycles as possible given its density, so a hypergraph is quasirandom (in many useful senses) if it has as few $d$-dimensional octahedra as possible. Cauchy-Schwarz type arguments show that if the $d$ vertex sets have size $n$, then a box-free hypergraph has $O(n^{d-1/2^{d-1}})$ edges. However, as we have already seen when $d=2$, the probabilistic method with deletions does not give a matching lower bound: instead it gives a hypergraph with $cn^{d-d/(2^d-1)}$ edges. Gunderson, Rödl and Sidorenko used a random algebraic construction to improve on this bound for all $d$ such that $d$ is coprime to $2^d-1$. When $d=3$, they took three copies $X,Y$ and $Z$ of $\mathbb F_p^5$ as their vertex sets and for each $x\in X$ and $y\in Y$ they took all triples $(x,y,z)$ such that $z$ belonged to a randomly chosen 3-dimensional affine subspace $R_{xy}$ of $\mathbb F_p^5$. This construction yields a lower bound of $cn^{13/5}$, whereas the bound from the purely random method is $cn^{18/7}$, which is smaller (by 1/35). In this paper the authors use random multilinear maps. That is, they let each $X_i$ be a copy of $\mathbb F_q^s$ for a carefully chosen $s$, and then for suitable $r$ they choose a random multilinear map $\mu:X_1\times\dots\times X_d\to\mathbb F_q^r$ and take as their edge set the set of all $(x_1,\dots,x_d)$ such that $\mu(x_1,\dots,x_d)=(1,1,\dots,1)$. The key point about this construction is that if the resulting hypergraph contains a box $Y_1\times\dots\times Y_d$, then in fact it contains the much larger set $Z_1\times\dots\times Z_d$, where each $Z_i$ is the line the contains $Y_i$. This enables the authors to obtain a non-trivial gain using a double counting argument and then to apply the deletion method more efficiently. Their method works for all $d$ and improves on the bound of Gunderson, Rödl and Sidorenko, when their method works, except if $d$ is a power of 2. This very interesting proof technique may well have further applications. The bound they obtain is slightly complicated to specify, but the exponent is at least $d-1/{\lceil d^{-1}(2^d-1)\rceil}$. Since $d$ cannot divide $2^d-1$, this is bigger than the $d-d/(2^d-1)$ that is given by the probabilistic method. Though the gain is small, it turns out that by a result of Ferber, McKinley and Samotij, any power-type gain on the obvious probabilistic bound yields an optimal counting result for the number of box-free hypergraphs with $n$ vertices in each class -- thus, the small gain has a very satisfying corollary. More details can be found in the paper, or in the following talk given by one of the authors.

Published

2021

2. Sidorenko's conjecture for blow-ups

Author

David Conlon and Joonkyung Lee

Subjects

Mathematics, QA1-939

Abstract

Sidorenko's conjecture for blow-ups, Discrete Analysis 2021:2, 13 pp. Let $G$ be a bipartite graph with finite vertex sets $X$ and $Y$. If $G$ has density $\alpha$, then the average degree of the vertices in $X$ is $\alpha|Y|$, so the mean-square degree is at least $\alpha^2|Y|^2$. This is easily seen to be equivalent to the statement that if two vertices $y_1,y_2$ are selected independently and uniformly at random from $Y$, then the average number of neighbours they have in common in $X$ is at least $\alpha^2|X|$. It follows that the mean-square number of common neighbours is at least $\alpha^4|X|^2$, and this translates into the statement that if $(x_1,x_2,y_1,y_2)$ is a random element of $X^2\times Y^2$, then the probability that all four pairs $x_iy_j$ are edges of $G$ is at least $\alpha^4$. This can be interpreted as saying that the 4-cycle density of a graph $G$ is always at least as large as it would be for a typical random graph of the same density. The above argument can be straightforwardly generalized from 4-cycles to general complete bipartite graphs $K_{r,s}$. The famous Sidorenko conjecture (also asked by Erdős and Simonovits) states that the conclusion holds for _all_ bipartite graphs. That is, if $H$ is a bipartite graph with vertex sets $U$ and $V$ of size $r$ and $s$, $G$ is as above, and $\phi:U\to X$ and $\psi:V\to Y$ are random functions, then the probability that $\phi(u)\psi(v)$ is an edge of $G$ for every $uv\in E(H)$ is at least $\alpha^{|E(H)|}$. One might think that this conjecture would either have a simple counterexample or would follow fairly easily from known inequalities, but this appears not to be the case. A good way to get a feel for the difficulty is to try to prove it for paths of length 3. It is known to be true in this case, but a certain amount of ingenuity is required to prove it. In fact, it is known to be true for quite a large class of bipartite graphs, with results typically taking the form that a bipartite graph satisfies the conjecture if it can be built up in a certain way from graphs that belong to a particularly simple class. The achievement of this paper is that it proves the conjecture for a class of graphs that _cannot_ be built up in that way. In other words, it obtains a proof that is not just a refinement of existing methods but a genuine extension of the available techniques. A particular class of graphs for which they obtain a positive result is that of _blow-ups_. These are bipartite graphs obtained as follows: let $H$ be a bipartite graph with vertex sets $A$ and $B$ and let $p$ be a positive integer, take $p$ disjoint copies $H_1,\dots,H_p$ of $H$ and identify corresponding vertices that belong to $A$. (For example, if $H$ is a single edge, then the blow-up is the complete bipartite graph $K_{1,p}$ -- that is, a star with $p$ edges.) The authors show that for every bipartite graph $H$ there is some $p$ such that the blow-up satisfies Sidorenko's conjecture. The rough idea behind the proof is that blow-ups have a property that allows one to replace the graph by a simpler graph to which known techniques apply. Perhaps the simplest case for which Sidorenko's conjecture is still unknown is the graph obtained from the complete bipartite graph $K_{5,5}$ by removing a 10-cycle. While the authors do not resolve this question, their result does imply that the "square" of this graph (that is, the blow-up when $p=2$) satisfies the conjecture. Another consequence of their results is that for every bipartite graph $H$ there is a bipartite graph $H'$ such that the disjoint union of $H$ and $H'$ satisfies the conjecture. So is Sidorenko's conjecture true? The experts on the problem are reluctant to take a strong view either way. The results proved so far place significant restrictions on what a counterexample could be like (though these leave open relatively small possibilities such as the $K_{5,5}\setminus C_{10}$ example), which perhaps points in the positive direction. On the other hand, a natural analogue of the conjecture for 3-uniform hypergraphs, which places a restriction on what a proof could be like -- it cannot be too generalizable. This paper is a valuable addition to our understanding of a tantalizing question.

Published

2021

3. Quasirandom Cayley graphs

Author

David Conlon and Yufei Zhao

Subjects

Mathematics, QA1-939

Abstract

Quasirandom Cayley graphs, Discrete Analysis 2017:6, 14 pp. An extremely important phenomenon in extremal combinatorics is that of _quasirandomness_: for many combinatorial structures, it is possible to identify a list of deterministic properties, each one of which says in one way or another that the structure behaves like a typical random example of that structure, and each of which implies all the others. The first results of this kind were due to Thomason and to Chung, Graham and Wilson. They identified several equivalent properties of graphs. For example, if $G$ is a graph with $n$ vertices and average degree $\alpha n$, then the following conditions are equivalent. (1) For any two large subsets $A,B\subset V(G)$ the number of pairs $(x,y)\in A\times B$ such that $xy\in E(G)$ is approximately $\alpha|A||B|$. (2) The number of labelled 4-cycles $xyzw$ in $G$ is approximately $\alpha^4n^4$. (3) The largest eigenvalue of the adjacency matrix of $G$ is approximately $\alpha n$ and the second largest eigenvalue is small compared with $\alpha n$. (4) For almost all pairs of vertices $x,y\in V(G)$ the intersection of their neighbourhoods has size approximately $\alpha^2 n$. (5) For every graph $H$ with a bounded number of vertices $v_1,\dots,v_k$, if $x_1,\dots,x_k$ are randomly and independently chosen vertices of $G$, then the probability that $x_ix_j\in E(G)$ for all $i,j$ such that $v_iv_j\in E(H)$ is approximately $\alpha^{|E(H)|}$. Of course, these statements are not precise, but one can make them precise by quantifying the errors, and expressing them as a proportion of the main term. For example, the number of labelled 4-cycles is regarded as being approximately $\alpha^4n^4$ if it differs from $\alpha^4n^4$ by at most $cn^4$ for some small constant $c$. Then to say that one statement implies another is to say that the error in the second statement tends to zero as the error in the first statement tends to zero. Note that this notion of equivalence is a "loose" one, meaning that if one applies one of the implications and then applies the reverse implication, one may not be able to recover the original error estimate, but one still obtains an error estimate that tends to zero as the original error estimate tends to zero. When it comes to applications, this looseness often does not matter, but sometimes it causes problems. That is particularly the case when $\alpha$ is not a fixed constant but tends to zero as $n$ tends to infinity. That is, it can be problematic for _sparse_ graphs. Moreover, there are examples that show that some of the important implications cannot be improved, so there is a genuine obstacle to the use of quasirandomness in proofs about sparse graphs. A particularly important implication that _does_ hold for sparse graphs is that (3) implies (1), even when $\alpha=d/n$ for some constant $d$: that is, when $G$ has constant average degree. However, simple examples show that this implication cannot be reversed when $G$ is sparse. It came as something of a surprise, therefore, when Kohayakawa, Rödl and Schacht proved that if $G$ is a Cayley graph of an Abelian group with respect to some set of generators, then (1) and (3) _are_ equivalent. This is surprising because in many contexts the properties of Cayley graphs are very similar to those of general graphs. This paper extends the work of Kohayakawa, Rödl and Schacht to the non-Abelian case. Since Cayley graphs of general groups are significantly more diverse than those of Abelian groups, this adds to the surprise of the Abelian case. In order to prove this result, the authors reformulate properties (1) and (3) in terms of two matrix norms, the cut norm and the spectral norm. They then use [Grothendieck's inequality](https://en.wikipedia.org/wiki/Grothendieck_inequality) to prove that the cut norm is equivalent to a third norm, which they call the Grothendieck norm. And then a short argument establishes that for adjacency matrices of Cayley graphs the Grothendieck norm is equal to the spectral norm. An alternative argument for the last implication, based on non-Abelian Fourier analysis, is given in an appendix. This alternative argument is a more direct generalization of the proof of Kohayakawa, Rödl and Schacht.

Published

2017

4. A flor, o fim do mundo: sensual media, lost futures and the end of cinema in Kleber Mendonça Filho’s Aquarius

Author

David Conlon

Subjects

Cultural Studies, Visual Arts and Performing Arts, Communication

Published

2023

5. Ramsey Numbers of Books and Quasirandomness

Author

David Conlon, Jacob Fox, and Yuval Wigderson

Subjects

Computational Mathematics, FOS: Mathematics, Mathematics - Combinatorics, Discrete Mathematics and Combinatorics, Combinatorics (math.CO)

Abstract

The book graph $B_n^{(k)}$ consists of $n$ copies of $K_{k+1}$ joined along a common $K_k$. The Ramsey numbers of $B_n^{(k)}$ are known to have strong connections to the classical Ramsey numbers of cliques. Recently, the first author determined the asymptotic order of these Ramsey numbers for fixed $k$, thus answering an old question of Erd\H{o}s, Faudree, Rousseau, and Schelp. In this paper, we first provide a simpler proof of this theorem. Next, answering a question of the first author, we present a different proof that avoids the use of Szemer\'edi's regularity lemma, thus providing much tighter control on the error term. Finally, we prove a conjecture of Nikiforov, Rousseau, and Schelp by showing that all extremal colorings for this Ramsey problem are quasirandom., Comment: 42 pages

Published

2022

6. A new bound for the Brown-Erdős-Sós problem

Author

David Conlon, Lior Gishboliner, Yevgeny Levanzov, and Asaf Shapira

Subjects

Brown-Erdős-Sós conjecture, Computational Theory and Mathematics, FOS: Mathematics, Discrete Mathematics and Combinatorics, Hypergraph removal lemma, Combinatorics (math.CO), Theoretical Computer Science

Abstract

Let f(n,v,e) denote the maximum number of edges in a 3-uniform hypergraph not containing e edges spanned by at most v vertices. One of the most influential open problems in extremal combinatorics then asks, for a given number of edges e≥3, what is the smallest integer d=d(e) such that f(n,e+d,e)=o(n2)? This question has its origins in work of Brown, Erdős and Sós from the early 70's and the standard conjecture is that d(e)=3 for every e≥3. The state of the art result regarding this problem was obtained in 2004 by Sárközy and Selkow, who showed that f(n,e+2+⌊log2e⌋,e)=o(n2). The only improvement over this result was a recent breakthrough of Solymosi and Solymosi, who improved the bound for d(10) from 5 to 4. We obtain the first asymptotic improvement over the Sárközy–Selkow bound, showing that f(n,e+O(loge/logloge),e)=o(n2)., Journal of Combinatorial Theory. Series B, 158, ISSN:0095-8956

Published

2023

7. Ramsey-type results for semi-algebraic relations.

Author

David Conlon, Jacob Fox, János Pach, Benny Sudakov, and Andrew Suk

Published

2013

8. Hypergraph Ramsey numbers of cliques versus stars

Author

David Conlon, Jacob Fox, Xiaoyu He, Dhruv Mubayi, Andrew Suk, and Jacques Verstraëte

Subjects

Applied Mathematics, General Mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), Computer Graphics and Computer-Aided Design, Software

Abstract

Let $K_m^{(3)}$ denote the complete $3$-uniform hypergraph on $m$ vertices and $S_n^{(3)}$ the $3$-uniform hypergraph on $n+1$ vertices consisting of all $\binom{n}{2}$ edges incident to a given vertex. Whereas many hypergraph Ramsey numbers grow either at most polynomially or at least exponentially, we show that the off-diagonal Ramsey number $r(K_{4}^{(3)},S_n^{(3)})$ exhibits an unusual intermediate growth rate, namely, \[ 2^{c \log^2 n} \le r(K_{4}^{(3)},S_n^{(3)}) \le 2^{c' n^{2/3}\log n} \] for some positive constants $c$ and $c'$. The proof of these bounds brings in a novel Ramsey problem on grid graphs which may be of independent interest: what is the minimum $N$ such that any $2$-edge-coloring of the Cartesian product $K_N \square K_N$ contains either a red rectangle or a blue $K_n$?, 13 pages

Published

2022

9. More on the Extremal Number of Subdivisions

Author

Joonkyung Lee, David Conlon, and Oliver Janzer

Subjects

Rational number, Conjecture, 010102 general mathematics, 0102 computer and information sciences, 16. Peace & justice, 01 natural sciences, Prime (order theory), Combinatorics, Computational Mathematics, 010201 computation theory & mathematics, Limit point, FOS: Mathematics, Bipartite graph, Graph (abstract data type), Mathematics - Combinatorics, Discrete Mathematics and Combinatorics, Combinatorics (math.CO), 0101 mathematics, Constant (mathematics), Mathematics

Abstract

Given a graph $H$, the extremal number $\mathrm{ex}(n,H)$ is the largest number of edges in an $H$-free graph on $n$ vertices. We make progress on a number of conjectures about the extremal number of bipartite graphs. First, writing $K'_{s,t}$ for the subdivision of the bipartite graph $K_{s,t}$, we show that $\mathrm{ex}(n, K'_{s,t}) = O(n^{3/2 - \frac{1}{2s}})$. This proves a conjecture of Kang, Kim and Liu and is tight up to the implied constant for $t$ sufficiently large in terms of $s$. Second, for any integers $s, k \geq 1$, we show that $\mathrm{ex}(n, L) = \Theta(n^{1 + \frac{s}{sk+1}})$ for a particular graph $L$ depending on $s$ and $k$, answering another question of Kang, Kim and Liu. This result touches upon an old conjecture of Erd\H{o}s and Simonovits, which asserts that every rational number $r \in (1,2)$ is realisable in the sense that $\mathrm{ex}(n,H) = \Theta(n^r)$ for some appropriate graph $H$, giving infinitely many new realisable exponents and implying that $1 + 1/k$ is a limit point of realisable exponents for all $k \geq 1$. Writing $H^k$ for the $k$-subdivision of a graph $H$, this result also implies that for any bipartite graph $H$ and any $k$, there exists $\delta > 0$ such that $\mathrm{ex}(n,H^{k-1}) = O(n^{1 + 1/k - \delta})$, partially resolving a question of Conlon and Lee. Third, extending a recent result of Conlon and Lee, we show that any bipartite graph $H$ with maximum degree $r$ on one side which does not contain $C_4$ as a subgraph satisfies $\mathrm{ex}(n, H) = o(n^{2 - 1/r})$., Comment: 21 pages

Published

2021

10. Some remarks on the Zarankiewicz problem

Author

David Conlon

Subjects

General Mathematics, 010102 general mathematics, 0102 computer and information sciences, 01 natural sciences, Upper and lower bounds, Combinatorics, Matrix (mathematics), Range (mathematics), 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Algebraic method, Constant (mathematics), Zarankiewicz problem, Mathematics

Abstract

The Zarankiewicz problem asks for an estimate on $z(m, n; s, t)$, the largest number of $1$'s in an $m \times n$ matrix with all entries $0$ or $1$ containing no $s \times t$ submatrix consisting entirely of $1$'s. We show that a classical upper bound for $z(m, n; s, t)$ due to K\H{o}v\'ari, S\'os and Tur\'an is tight up to the constant for a broad range of parameters. The proof relies on a new quantitative variant of the random algebraic method., Comment: 6 pages

Published

2021

11. Reviews of Books

Author

Kátia Sherman, David Conlon, Teresa Hancock-Parmer, Don W. Cruickshank, Encarnación Juárez-Almendros, Toni Dorca, Sonja Kleij, Jean Andrews, Xabier Granja Ibarreche, Lynn K. Talbot, Andrew M. Beresford, Pamela Beth Radcliff, Benjamin Bryce, Bethan Fisk, Filipe Ribeiro de Meneses, Antonio Cazorla Sánchez, Fraser Raeburn, Robert L. Turner, David González Ramírez, Heidi Backes, Irina Alexandra Feldman, David T. Gies, Helen E. Rawlings, Sarah A. Radcliffe, and Janelle Rodriques

Subjects

Cultural Studies, Space (punctuation), White (horse), Literature and Literary Theory, media_common.quotation_subject, Art history, Art, media_common

Published

2020

12. The regularity method for graphs with few 4-cycles

Author

Yufei Zhao, Benny Sudakov, David Conlon, and Jacob Fox

Subjects

05C35, 05D40, 11B99, 11P99 (primary), Dense graph, General Mathematics, 010102 general mathematics, 0102 computer and information sciences, Girth (graph theory), 01 natural sciences, Graph, Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

We develop a sparse graph regularity method that applies to graphs with few 4-cycles, including new counting and removal lemmas for 5-cycles in such graphs. Some applications include: * Every $n$-vertex graph with no 5-cycle can be made triangle-free by deleting $o(n^{3/2})$ edges. * For $r \geq 3$, every $n$-vertex $r$-graph with girth greater than $5$ has $o(n^{3/2})$ edges. * Every subset of $[n]$ without a nontrivial solution to the equation $x_1 + x_2 + 2x_3 = x_4 + 3x_5$ has size $o(\sqrt{n})$., 23 pages

Published

2021

13. Repeated Patterns in Proper Colorings

Author

David Conlon and Mykhaylo Tyomkyn

Subjects

Discrete mathematics, General Mathematics, 010102 general mathematics, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Complete graph, 0102 computer and information sciences, 01 natural sciences, Graph, Combinatorics, 010201 computation theory & mathematics, TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, 0101 mathematics, ComputingMethodologies_COMPUTERGRAPHICS, MathematicsofComputing_DISCRETEMATHEMATICS, Mathematics

Abstract

For a fixed graph H, what is the smallest number of colors C such that there is a proper edge-coloring of the complete graph K_n with C colors containing no two vertex-disjoint color-isomorphic copies, or repeats, of H? We study this function and its generalization to more than two copies using a variety of combinatorial, probabilistic, and algebraic techniques. For example, we show that for any tree T there exists a constant c such that any proper edge-coloring of K_n with at most c n^2 colors contains two repeats of T, while there are colorings with at most c' n^(3/2) colors for some absolute constant c' containing no three repeats of any tree with at least two edges. We also show that for any graph H containing a cycle there exist k and c such that there is a proper edge-coloring of K_n with at most c n colors containing no k repeats of H, while for a tree T with m edges, a coloring with o(n^((m+1)/m)) colors contains ω(1) repeats of T.

Published

2021

14. Which graphs can be counted in $C_4$-free graphs?

Author

David Conlon, Jacob Fox, Benny Sudakov, and Yufei Zhao

Subjects

Computer Science::Discrete Mathematics, General Mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO)

Abstract

For which graphs $F$ is there a sparse $F$-counting lemma in $C_4$-free graphs? We are interested in identifying graphs $F$ with the property that, roughly speaking, if $G$ is an $n$-vertex $C_4$-free graph with on the order of $n^{3/2}$ edges, then the density of $F$ in $G$, after a suitable normalization, is approximately at least the density of $F$ in an $\epsilon$-regular approximation of $G$. In recent work, motivated by applications in extremal and additive combinatorics, we showed that $C_5$ has this property. Here we construct a family of graphs with the property., Comment: 13 pages

Published

2021

15. Short proofs of some extremal results III

Author

Benny Sudakov, David Conlon, and Jacob Fox

Subjects

Random graph, Discrete mathematics, Applied Mathematics, General Mathematics, 010102 general mathematics, Ramsey theory, 0102 computer and information sciences, Mathematical proof, 01 natural sciences, Computer Graphics and Computer-Aided Design, Extremal graph theory, extremal graph theory, Random graphs, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Software, Mathematics

Abstract

We prove a selection of results from different areas of extremal combinatorics, including complete or partial solutions to a number of open problems. These results, coming mainly from extremal graph theory and Ramsey theory, have been collected together because in each case the relevant proofs are reasonably short., 27 pages, subsumes arXiv:1901.05084

Published

2020

16. Lower bounds for multicolor Ramsey numbers

Author

Asaf Ferber and David Conlon

Subjects

Combinatorics, Mathematics::Logic, General Mathematics, Diagonal, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), Ramsey's theorem, Upper and lower bounds, Exponential function, Mathematics

Abstract

We give an exponential improvement to the lower bound on diagonal Ramsey numbers for any fixed number of colors greater than two., 4 pages

Published

2020

17. Books versus triangles at the extremal density

Author

Benny Sudakov, Jacob Fox, and David Conlon

Subjects

Combinatorics, Discrete mathematics, extremal graph theory, Rademacher-type theorems, books, 010201 computation theory & mathematics, General Mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0102 computer and information sciences, 01 natural sciences, Graph, Mathematics, Extremal graph theory

Abstract

A celebrated result of Mantel shows that every graph on $n$ vertices with $\lfloor n^2/4 \rfloor + 1$ edges must contain a triangle. A robust version of this result, due to Rademacher, says that there must in fact be at least $\lfloor n/2 \rfloor$ triangles in any such graph. Another strengthening, due to the combined efforts of many authors starting with Erd\H{o}s, says that any such graph must have an edge which is contained in at least $n/6$ triangles. Following Mubayi, we study the interplay between these two results, that is, between the number of triangles in such graphs and their book number, the largest number of triangles sharing an edge. Among other results, Mubayi showed that for any $1/6 \leq \beta < 1/4$ there is $\gamma > 0$ such that any graph on $n$ vertices with at least $\lfloor n^2/4\rfloor + 1$ edges and book number at most $\beta n$ contains at least $(\gamma -o(1))n^3$ triangles. He also asked for a more precise estimate for $\gamma$ in terms of $\beta$. We make a conjecture about this dependency and prove this conjecture for $\beta = 1/6$ and for $0.2495 \leq \beta < 1/4$, thereby answering Mubayi's question in these ranges., Comment: 15 pages

Published

2020

18. Extremal numbers of cycles revisited

Author

David Conlon

Subjects

Discrete mathematics, Simple (abstract algebra), General Mathematics, 010102 general mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Algebraic construction, 01 natural sciences, Mathematics, Interpretation (model theory)

Abstract

We give a simple geometric interpretation of an algebraic construction of Wenger that yields $n$-vertex graphs with no cycle of length $4$, $6$ or $10$ and close to the maximum number of edges., Comment: 4 pages, to appear in Amer. Math. Monthly

Published

2020

19. Ramsey games near the critical threshold

Author

Tamás Mészáros, David Conlon, Joonkyung Lee, and Shagnik Das

Subjects

Random graph, positional games, Applied Mathematics, General Mathematics, Existential quantification, 010102 general mathematics, Ramsey theory, 500 Naturwissenschaften und Mathematik::510 Mathematik::510 Mathematik, 0102 computer and information sciences, 01 natural sciences, Computer Graphics and Computer-Aided Design, Graph, Combinatorics, 010201 computation theory & mathematics, Critical threshold, FOS: Mathematics, Mathematics - Combinatorics, Monochromatic color, Combinatorics (math.CO), 0101 mathematics, Software, random graphs, Mathematics

Abstract

A well-known result of R\"odl and Ruci\'nski states that for any graph $H$ there exists a constant $C$ such that if $p \geq C n^{- 1/m_2(H)}$, then the random graph $G_{n,p}$ is a.a.s. $H$-Ramsey, that is, any $2$-colouring of its edges contains a monochromatic copy of $H$. Aside from a few simple exceptions, the corresponding $0$-statement also holds, that is, there exists $c>0$ such that whenever $p\leq cn^{-1/m_2(H)}$ the random graph $G_{n,p}$ is a.a.s. not $H$-Ramsey. We show that near this threshold, even when $G_{n,p}$ is not $H$-Ramsey, it is often extremely close to being $H$-Ramsey. More precisely, we prove that for any constant $c > 0$ and any strictly $2$-balanced graph $H$, if $p \geq c n^{-1/m_2(H)}$, then the random graph $G_{n,p}$ a.a.s. has the property that every $2$-edge-colouring without monochromatic copies of $H$ cannot be extended to an $H$-free colouring after $\omega(1)$ extra random edges are added. This generalises a result by Friedgut, Kohayakawa, R\"odl, Ruci\'nski and Tetali, who in 2002 proved the same statement for triangles, and addresses a question raised by those authors. We also extend a result of theirs on the three-colour case and show that these theorems need not hold when $H$ is not strictly $2$-balanced., Comment: 18 pages, 6 figures; to appear in Random Structures & Algorithms

Published

2020

20. Reviews of Books

Author

Niamh Thornton, Sheldon Penn, Breixo Viejo, Lorraine Ryan, Vinodh Venkatesh, Julián Daniel Gutiérrez-Albilla, David Conlon, Eamon McCarthy, Robert McKee Irwin, José Riello, Hilary Macartney, Véronique Gerard Powell, Guillem Colom-Montero, Ricardo Fernández Romero, Genoveva Tusell García, Nathanial Gardner, Lara Demori, Sebastiaan Faber, Chris Perriam, and Jonathan Risner

Subjects

Cultural Studies, Visual Arts and Performing Arts

Published

2018

21. Online Ramsey Numbers and the Subgraph Query Problem

Author

Xiaoyu He, Jacob Fox, David Conlon, and Andrey Grinshpun

Subjects

Random graph, Infinite set, 010102 general mathematics, Diagonal, Combinatorial game theory, 0102 computer and information sciences, 01 natural sciences, Upper and lower bounds, Graph, Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), Ramsey's theorem, 0101 mathematics, Mathematics

Abstract

The $(m,n)$-online Ramsey game is a combinatorial game between two players, Builder and Painter. Starting from an infinite set of isolated vertices, Builder draws an edge on each turn and Painter immediately paints it red or blue. Builder's goal is to force Painter to create either a red $K_m$ or a blue $K_n$ using as few turns as possible. The online Ramsey number $\tilde{r}(m,n)$ is the minimum number of edges Builder needs to guarantee a win in the $(m,n)$-online Ramsey game. By analyzing the special case where Painter plays randomly, we obtain an exponential improvement \[ \tilde{r}(n,n) \ge 2^{(2-\sqrt{2})n + O(1)} \] for the lower bound on the diagonal online Ramsey number, as well as a corresponding improvement \[ \tilde{r}(m,n) \ge n^{(2-\sqrt{2})m + O(1)} \] for the off-diagonal case, where $m\ge 3$ is fixed and $n\rightarrow\infty$. Using a different randomized Painter strategy, we prove that $\tilde{r}(3,n)=\tilde{\Theta}(n^3)$, determining this function up to a polylogarithmic factor. We also improve the upper bound in the off-diagonal case for $m \geq 4$. In connection with the online Ramsey game with a random Painter, we study the problem of finding a copy of a target graph $H$ in a sufficiently large unknown Erd\H{o}s--R\'{e}nyi random graph $G(N,p)$ using as few queries as possible, where each query reveals whether or not a particular pair of vertices are adjacent. We call this problem the Subgraph Query Problem. We determine the order of the number of queries needed for complete graphs up to five vertices and prove general bounds for this problem., Comment: Corrected substantial error in the proof of Theorem 4

Published

2019

22. Almost-spanning universality in random graphs

Author

Rajko Nenadov, Asaf Ferber, David Conlon, and Nemanja Škorić

Subjects

General Mathematics, Symmetric graph, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 0102 computer and information sciences, 01 natural sciences, Combinatorics, Random regular graph, FOS: Mathematics, Data_FILES, Mathematics - Combinatorics, Graph toughness, 0101 mathematics, Pancyclic graph, Universal graph, Mathematics, Random graph, Discrete mathematics, Degree (graph theory), Applied Mathematics, 010102 general mathematics, Computer Graphics and Computer-Aided Design, Vertex-transitive graph, TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGES, 010201 computation theory & mathematics, Combinatorics (math.CO), Software_PROGRAMMINGLANGUAGES, Software

Abstract

A graph $G$ is said to be $\mathcal H(n,\Delta)$-universal if it contains every graph on $n$ vertices with maximum degree at most $\Delta$. It is known that for any $\varepsilon > 0$ and any natural number $\Delta$ there exists $c > 0$ such that the random graph $G(n,p)$ is asymptotically almost surely $\mathcal H((1-\varepsilon)n,\Delta)$-universal for $p \geq c (\log n/n)^{1/\Delta}$. Bypassing this natural boundary, we show that for $\Delta \geq 3$ the same conclusion holds when $p = \omega\left(n^{-\frac{1}{\Delta-1}}\log^5 n\right)$.

Published

2016

23. Monochromatic combinatorial lines of length three

Author

David Conlon

Subjects

Combinatorics, Physics, Line (geometry), FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), Monochromatic color, Astrophysics::Cosmology and Extragalactic Astrophysics, Cube, Constant (mathematics), Astrophysics::Galaxy Astrophysics

Abstract

We show that there is a constant $c$ such that any colouring of the cube $[3]^n$ in $c \log \log n$ colours contains a monochromatic combinatorial line., 3 pages

Published

2018

24. Sidorenko's conjecture for blow-ups

Author

David Conlon and Joonkyung Lee

Subjects

Mathematics::Combinatorics, lcsh:Mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), lcsh:QA1-939

Abstract

A celebrated conjecture of Sidorenko and Erd\H{o}s-Simonovits states that, for all bipartite graphs $H$, quasirandom graphs contain asymptotically the minimum number of copies of $H$ taken over all graphs with the same order and edge density. This conjecture has attracted considerable interest over the last decade and is now known to hold for a broad range of bipartite graphs, with the overall trend saying that a graph satisfies the conjecture if it can be built from simple building blocks such as trees in a certain recursive fashion. Our contribution here, which goes beyond this paradigm, is to show that the conjecture holds for any bipartite graph $H$ with bipartition $A \cup B$ where the number of vertices in $B$ of degree $k$ satisfies a certain divisibility condition for each $k$. As a corollary, we have that for every bipartite graph $H$ with bipartition $A \cup B$, there is a positive integer $p$ such that the blow-up $H_A^p$ formed by taking $p$ vertex-disjoint copies of $H$ and gluing all copies of $A$ along corresponding vertices satisfies the conjecture. Another way of viewing this latter result is that for every bipartite $H$ there is a positive integer $p$ such that an $L^p$-version of Sidorenko's conjecture holds for $H$., Comment: Reformatted for Discrete Analysis

Published

2018

25. Quasirandomness in hypergraphs

Author

Hiệp Hàn, David Conlon, Mathias Schacht, Yury Person, and Elad Aigner-Horev

Subjects

Random graph, Edge density, Applied Mathematics, 010102 general mathematics, Combinatorial proof, 0102 computer and information sciences, 01 natural sciences, Graph, Theoretical Computer Science, Combinatorics, Computational Theory and Mathematics, 05C65 (primary), 05C80 (secondary), 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Discrete Mathematics and Combinatorics, Combinatorics (math.CO), Geometry and Topology, 0101 mathematics, Graph property, Mathematics

Abstract

An $n$-vertex graph $G$ of edge density $p$ is considered to be quasirandom if it shares several important properties with the random graph $G(n,p)$. A well-known theorem of Chung, Graham and Wilson states that many such `typical' properties are asymptotically equivalent and, thus, a graph $G$ possessing one such property automatically satisfies the others. In recent years, work in this area has focused on uncovering more quasirandom graph properties and on extending the known results to other discrete structures. In the context of hypergraphs, however, one may consider several different notions of quasirandomness. A complete description of these notions has been provided recently by Towsner, who proved several central equivalences using an analytic framework. We give short and purely combinatorial proofs of the main equivalences in Towsner's result., Comment: 19 pages

Published

2018

26. On the extremal number of subdivisions

Author

Joonkyung Lee and David Conlon

Subjects

Conjecture, business.industry, General Mathematics, 010102 general mathematics, 0102 computer and information sciences, 01 natural sciences, Random choice, Graph, Extremal graph theory, Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Bipartite graph, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, business, Subdivision, Mathematics

Abstract

One of the cornerstones of extremal graph theory is a result of F\"uredi, later reproved and given due prominence by Alon, Krivelevich and Sudakov, saying that if $H$ is a bipartite graph with maximum degree $r$ on one side, then there is a constant $C$ such that every graph with $n$ vertices and $C n^{2 - 1/r}$ edges contains a copy of $H$. This result is tight up to the constant when $H$ contains a copy of $K_{r,s}$ with $s$ sufficiently large in terms of $r$. We conjecture that this is essentially the only situation in which F\"uredi's result can be tight and prove this conjecture for $r = 2$. More precisely, we show that if $H$ is a $C_4$-free bipartite graph with maximum degree $2$ on one side, then there are positive constants $C$ and $\delta$ such that every graph with $n$ vertices and $C n^{3/2 - \delta}$ edges contains a copy of $H$. This answers a question of Erd\H{o}s from 1988. The proof relies on a novel variant of the dependent random choice technique which may be of independent interest., Comment: 18 pages

Published

2018

27. Some advances on Sidorenko's conjecture

Author

David Conlon, Joonkyung Lee, Choongbum Lee, and Jeong Han Kim

Subjects

Vertex (graph theory), Conjecture, Mathematics::Combinatorics, General Mathematics, 010102 general mathematics, 0102 computer and information sciences, Cartesian product, Random walk, 01 natural sciences, Tree decomposition, Combinatorics, symbols.namesake, 010201 computation theory & mathematics, Product (mathematics), Bipartite graph, symbols, FOS: Mathematics, Mathematics - Combinatorics, Homomorphism, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

A bipartite graph $H$ is said to have Sidorenko's property if the probability that the uniform random mapping from $V(H)$ to the vertex set of any graph $G$ is a homomorphism is at least the product over all edges in $H$ of the probability that the edge is mapped to an edge of $G$. In this paper, we provide three distinct families of bipartite graphs that have Sidorenko's property. First, using branching random walks, we develop an embedding algorithm which allows us to prove that bipartite graphs admitting a certain type of tree decomposition have Sidorenko's property. Second, we use the concept of locally dense graphs to prove that subdivisions of certain graphs, including cliques, have Sidorenko's property. Third, we prove that if $H$ has Sidorenko's property, then the Cartesian product of $H$ with an even cycle also has Sidorenko's property., Comment: 19 pages

Published

2018

28. Rational exponents in extremal graph theory

Author

Boris Bukh and David Conlon

Subjects

010201 computation theory & mathematics, Applied Mathematics, General Mathematics, 010102 general mathematics, FOS: Mathematics, Mathematics - Combinatorics, 19999 Mathematical Sciences not elsewhere classified, 0102 computer and information sciences, Combinatorics (math.CO), 0101 mathematics, 01 natural sciences

Abstract

Given a family of graphs $\mathcal{H}$, the extremal number $\textrm{ex}(n, \mathcal{H})$ is the largest $m$ for which there exists a graph with $n$ vertices and $m$ edges containing no graph from the family $\mathcal{H}$ as a subgraph. We show that for every rational number $r$ between $1$ and $2$, there is a family of graphs $\mathcal{H}_r$ such that $\textrm{ex}(n, \mathcal{H}_r) = \Theta(n^r)$. This solves a longstanding problem in the area of extremal graph theory., Comment: 11 pages. arXiv admin note: text overlap with arXiv:1411.0856

Published

2018

29. On the KŁR conjecture in random graphs

Author

Mathias Schacht, Wojciech Samotij, W. T. Gowers, and David Conlon

Subjects

Combinatorics, Random graph, Lemma (mathematics), Mathematics::Combinatorics, Conjecture, Computer Science::Discrete Mathematics, General Mathematics, Mathematics - Combinatorics, Embedding, Almost surely, Mathematics

Abstract

The K{\L}R conjecture of Kohayakawa, {\L}uczak, and R\"odl is a statement that allows one to prove that asymptotically almost surely all subgraphs of the random graph G_{n,p}, for sufficiently large p : = p(n), satisfy an embedding lemma which complements the sparse regularity lemma of Kohayakawa and R\"odl. We prove a variant of this conjecture which is sufficient for most known applications to random graphs. In particular, our result implies a number of recent probabilistic versions, due to Conlon, Gowers, and Schacht, of classical extremal combinatorial theorems. We also discuss several further applications., Comment: 33 pages

Published

2018

30. Lines in Euclidean Ramsey theory

Author

David Conlon and Jacob Fox

Subjects

050101 languages & linguistics, Sequence, 05 social sciences, Ramsey theory, Natural number, Astrophysics::Cosmology and Extragalactic Astrophysics, 02 engineering and technology, Theoretical Computer Science, Combinatorics, Computational Theory and Mathematics, Euclidean geometry, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Exponent, Mathematics - Combinatorics, Astrophysics::Solar and Stellar Astrophysics, Discrete Mathematics and Combinatorics, 020201 artificial intelligence & image processing, 0501 psychology and cognitive sciences, Combinatorics (math.CO), Geometry and Topology, Astrophysics::Galaxy Astrophysics, Mathematics

Abstract

Let $\ell_m$ be a sequence of $m$ points on a line with consecutive points of distance one. For every natural number $n$, we prove the existence of a red/blue-coloring of $\mathbb{E}^n$ containing no red copy of $\ell_2$ and no blue copy of $\ell_m$ for any $m \geq 2^{cn}$. This is best possible up to the constant $c$ in the exponent. It also answers a question of Erd\H{o}s, Graham, Montgomery, Rothschild, Spencer and Straus from 1973. They asked if, for every natural number $n$, there is a set $K \subset \mathbb{E}^1$ and a red/blue-coloring of $\mathbb{E}^n$ containing no red copy of $\ell_2$ and no blue copy of $K$., Comment: 7 pages

Published

2018

31. Hypergraph cuts above the average

Author

Matthew Kwan, Benny Sudakov, David Conlon, and Jacob Fox

Subjects

Vertex (graph theory), Hypergraph, General Mathematics, 010102 general mathematics, Significant difference, 0102 computer and information sciences, 01 natural sciences, Omega, Graph, Standard deviation, Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Partition (number theory), Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

An r-cut of a k-uniform hypergraph H is a partition of the vertex set of H into r parts and the size of the cut is the number of edges which have a vertex in each part. A classical result of Edwards says that every m-edge graph has a 2-cut of size $$m{\rm/}2 + {\rm\Omega)}(\sqrt m)$$ and this is best possible. That is, there exist cuts which exceed the expected size of a random cut by some multiple of the standard deviation. We study analogues of this and related results in hypergraphs. First, we observe that similarly to graphs, every m-edge k-uniform hypergraph has an r-cut whose size is $${\rm\Omega}(\sqrt m)$$ larger than the expected size of a random r-cut. Moreover, in the case where k = 3 and r = 2 this bound is best possible and is attained by Steiner triple systems. Surprisingly, for all other cases (that is, if k ≥ 4 or r ≥ 3), we show that every m-edge k-uniform hypergraph has an r-cut whose size is Ω(m5/9) larger than the expected size of a random r-cut. This is a significant difference in behaviour, since the amount by which the size of the largest cut exceeds the expected size of a random cut is now considerably larger than the standard deviation.

Published

2018

32. Hypergraph expanders of all uniformities from Cayley graphs

Author

Yufei Zhao, Jonathan Tidor, and David Conlon

Subjects

Hypergraph, Mathematics::Combinatorics, Degree (graph theory), Cayley graph, 05C65, 05C81, General Mathematics, 010102 general mathematics, 0102 computer and information sciences, 01 natural sciences, Combinatorics, 010201 computation theory & mathematics, Simple (abstract algebra), Computer Science::Discrete Mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

Hypergraph expanders are hypergraphs with surprising, non-intuitive expansion properties. In a recent paper, the first author gave a simple construction, which can be randomized, of $3$-uniform hypergraph expanders with polylogarithmic degree. We generalize this construction, giving a simple construction of $r$-uniform hypergraph expanders for all $r \geq 3$., Comment: 32 pages

Published

2018

33. The Ramsey number of books

Author

David Conlon

Subjects

010102 general mathematics, Ramsey theory, Complete graph, Lower order, 0102 computer and information sciences, 01 natural sciences, Graph, Vertex (geometry), Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Discrete Mathematics and Combinatorics, Monochromatic color, Ramsey's theorem, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

We show that in every two-colouring of the edges of the complete graph $K_N$ there is a monochromatic $K_k$ which can be extended in at least $(1 + o_k(1))2^{-k}N$ ways to a monochromatic $K_{k+1}$. This result is asymptotically best possible, as may be seen by considering a random colouring. Equivalently, defining the book $B_n^{(k)}$ to be the graph consisting of $n$ copies of $K_{k+1}$ all sharing a common $K_k$, we show that the Ramsey number $r(B_n^{(k)}) = 2^k n + o_k(n)$. In this form, our result answers a question of Erd\H{o}s, Faudree, Rousseau and Schelp and establishes an asymptotic version of a conjecture of Thomason., Comment: Reformatted for Advances in Combinatorics

Published

2018

34. ‘Discourse with the Incorporeal Air’: Spectres of Walsh in Plata quemada

Author

David Conlon

Subjects

Linguistics and Language, Literature and Literary Theory, media_common.quotation_subject, Art, Capitalism, Language and Linguistics, Military regime, Argument, Dramatization, Point of departure, Humanities, Hamlet (place), Period (music), media_common

Abstract

This article suggests that Ricardo Piglia’s non-fiction crime novel Plata quemada (1997) be read as a conscious homage to Rodolfo Walsh’s earlier non-fiction novel ¿Quién mató a Rosendo? (1969). The suggested reading takes as its point of departure the appearance in Piglia’s text of an oblique reference to the ‘play-within-theplay’ of Shakespeare’s Hamlet, which also contains echoes of a detail from ¿Quién mató a Rosendo?. Following on from this, the article’s argument is threefold: 1) that ¿Quién mató a Rosendo? and Plata quemada are both concerned with a dramatization of economic paradigms, which amounts to an unveiling of the hidden violence of capitalism; 2) that Plata quemada reflects the evolution of the nature of capitalism, labour, and society in the period between 1969 and 1997; 3) that in its engagement with Walsh’s text via Hamlet, Plata quemada constitutes an act of mourning for Walsh, who was killed by the 1976–1983 military regime, but also in respect of the decline of the traditional left more generally.

Published

2018

35. Monochromatic Cycle Partitions in Local Edge Colorings

Author

Maya Stein and David Conlon

Subjects

Discrete mathematics, Vertex (graph theory), 010102 general mathematics, Complete graph, Neighbourhood (graph theory), 0102 computer and information sciences, Complete coloring, 01 natural sciences, Combinatorics, Edge coloring, Circulant graph, 010201 computation theory & mathematics, Discrete Mathematics and Combinatorics, Geometry and Topology, 0101 mathematics, Fractional coloring, Graph factorization, Mathematics

Abstract

An edge coloring of a graph is said to be an r-local coloring if the edges incident to any vertex are colored with at most r colors. Generalizing a result of Bessy and Thomasse, we prove that the vertex set of any 2-locally colored complete graph may be partitioned into two disjoint monochromatic cycles of different colors. Moreover, for any natural number r, we show that the vertex set of any r-locally colored complete graph may be partitioned into Or2logr disjoint monochromatic cycles. This generalizes a result of Erdi¾?s, Gyarfas, and Pyber.

Published

2015

36. Finite reflection groups and graph norms

Author

Joonkyung Lee and David Conlon

Subjects

Vertex (graph theory), Conjecture, Lebesgue measure, General Mathematics, 010102 general mathematics, 0102 computer and information sciences, Automorphism, 01 natural sciences, Graph, Functional Analysis (math.FA), Combinatorics, Mathematics - Functional Analysis, 010201 computation theory & mathematics, Natural family, Bipartite graph, FOS: Mathematics, Mathematics - Combinatorics, Hypercube, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

Given a graph $H$ on vertex set $\{1,2,\cdots, n\}$ and a function $f:[0,1]^2 \rightarrow \mathbb{R}$, define \begin{align*} \|f\|_{H}:=\left\vert\int \prod_{ij\in E(H)}f(x_i,x_j)d\mu^{|V(H)|}\right\vert^{1/|E(H)|}, \end{align*} where $\mu$ is the Lebesgue measure on $[0,1]$. We say that $H$ is norming if $\|\cdot\|_H$ is a semi-norm. A similar notion $\|\cdot\|_{r(H)}$ is defined by $\|f\|_{r(H)}:=\||f|\|_{H}$ and $H$ is said to be weakly norming if $\|\cdot\|_{r(H)}$ is a norm. Classical results show that weakly norming graphs are necessarily bipartite. In the other direction, Hatami showed that even cycles, complete bipartite graphs, and hypercubes are all weakly norming. We demonstrate that any graph whose edges percolate in an appropriate way under the action of a certain natural family of automorphisms is weakly norming. This result includes all previously known examples of weakly norming graphs, but also allows us to identify a much broader class arising from finite reflection groups. We include several applications of our results. In particular, we define and compare a number of generalisations of Gowers' octahedral norms and we prove some new instances of Sidorenko's conjecture., Comment: 29 pages

Published

2017

37. Tower-type bounds for unavoidable patterns in words

Author

Benny Sudakov, Jacob Fox, and David Conlon

Subjects

Applied Mathematics, General Mathematics, 010102 general mathematics, Function (mathematics), Type (model theory), 01 natural sciences, Tower (mathematics), Constant factor, Combinatorics, Integer, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Alphabet, Word (group theory), Mathematics

Abstract

A word $w$ is said to contain the pattern $P$ if there is a way to substitute a nonempty word for each letter in $P$ so that the resulting word is a subword of $w$. Bean, Ehrenfeucht and McNulty and, independently, Zimin characterised the patterns $P$ which are unavoidable, in the sense that any sufficiently long word over a fixed alphabet contains $P$. Zimin's characterisation says that a pattern is unavoidable if and only if it is contained in a Zimin word, where the Zimin words are defined by $Z_1 = x_1$ and $Z_n=Z_{n-1} x_n Z_{n-1}$. We study the quantitative aspects of this theorem, obtaining essentially tight tower-type bounds for the function $f(n,q)$, the least integer such that any word of length $f(n, q)$ over an alphabet of size $q$ contains $Z_n$. When $n = 3$, the first non-trivial case, we determine $f(n,q)$ up to a constant factor, showing that $f(3,q) = \Theta(2^q q!)$., Comment: 17 pages

Published

2017

38. A Sequence of Triangle-Free Pseudorandom Graphs

Author

David Conlon

Subjects

Statistics and Probability, Pseudorandom number generator, Random graph, Edge density, Applied Mathematics, 010102 general mathematics, 0102 computer and information sciences, 01 natural sciences, Theoretical Computer Science, Combinatorics, Computational Theory and Mathematics, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Mathematics, Sequence (medicine), MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

A construction of Alon yields a sequence of highly pseudorandom triangle-free graphs with edge density significantly higher than one might expect from comparison with random graphs. We give an alternative construction for such graphs., 6 pages

Published

2017

39. Quasirandom Cayley graphs

Author

Yufei Zhao and David Conlon

Subjects

Extremal combinatorics, Algebra and Number Theory, Mathematics::Combinatorics, Cayley graph, lcsh:Mathematics, Matrix norm, Group Theory (math.GR), lcsh:QA1-939, Combinatorics, Bounded function, Norm (mathematics), FOS: Mathematics, Discrete Mathematics and Combinatorics, Mathematics - Combinatorics, Geometry and Topology, Adjacency matrix, Combinatorics (math.CO), Abelian group, Graph property, Mathematics - Group Theory, Mathematics

Abstract

We prove that the properties of having small discrepancy and having small second eigenvalue are equivalent in Cayley graphs, extending a result of Kohayakawa, R\"odl, and Schacht, who treated the abelian case. The proof relies on Grothendieck's inequality. As a corollary, we also prove that a similar result holds in all vertex-transitive graphs., Comment: Reformatted for Discrete Analysis

Published

2017

40. The Trauma of Nature: Antonio Di Benedetto’s Zama as Ecological Noir

Author

David Conlon

Subjects

History, Action (philosophy), Ecology, Reading (process), media_common.quotation_subject, Perspective (graphical), Natural (music), Apprenticeship, Modality (semiotics), media_common

Abstract

This paper suggests a reading of Zama (1956), the acclaimed debut novel of Argentine writer Antonio Di Benedetto, from an eco-critical perspective. In light of a remark by Sergio Chejfec, it will look at how the novel’s eponymous protagonist, a colonial-era bureaucrat based in Asuncion, encounters the natural environment as traumatic, engendering cognitive upheaval. On this basis, it will go on to consider how the work conforms to a variant of Bildungsroman, or, in this case, novel of ecological apprenticeship, insofar as the protagonist undergoes a process of cognitive re-orientation as his experience of the environment comes into conflict with Old World epistemologies. It will be argued that the temporal setting is, for this reason, significant, as it sets the action against the backdrop of then-emergent geological and proto-Darwinian discourses. In the final sections, the paper aims to contextualise the novel’s publication in 1956 in terms of its affiliations with film noir, and to assess the grounds for considering noir as a paradigm for understanding latter-day iterations of the Bildungsroman, as well as an exemplary modality for the working-through of post-World War II epistemological trauma. Finally, and within the same broadly eco-critical framework, some reasons will be suggested for the renewed interest in Di Benedetto’s novel in recent years.

Published

2017

41. On the Grid Ramsey Problem and Related Questions: Fig. 1

Author

Jacob Fox, Choongbum Lee, Benny Sudakov, and David Conlon

Subjects

Combinatorics, Lemma (mathematics), symbols.namesake, Ramsey problem, General Mathematics, Ramsey theory, symbols, Primitive recursive function, Rectangle, Cartesian product, Grid, Upper and lower bounds, Mathematics

Abstract

The Hales–Jewett theorem is one of the pillars of Ramsey theory, from which many other results follow. A celebrated theorem of Shelah says that Hales–Jewett numbers are primitive recursive. A key tool used in his proof, now known as the cube lemma, has become famous in its own right. In its simplest form, this lemma says that if we color the edges of the Cartesian product Kn × Knin r colors, then, for nsufficiently large, there is a rectangle with both pairs of opposite edges receiving the same color. Shelah’s proof shows that n=r � r+1 2 � + 1 suffices. More than 20 years ago, Graham, Rothschild, and Spencer asked whether this bound can be improved to a polynomial in r. We show that this is not possible by providing a superpolynomial lower bound in r. We also discuss a number of related problems.

Published

2014

42. Ramsey-type results for semi-algebraic relations

Author

János Pach, David Conlon, Andrew Suk, Benny Sudakov, Jacob Fox, Massachusetts Institute of Technology. Department of Mathematics, Fox, Jacob, and Suk, Andrew

Subjects

Matching (graph theory), General Mathematics, Natural number, 0102 computer and information sciences, Disjoint sets, Type (model theory), 01 natural sciences, Upper and lower bounds, Combinatorics, FOS: Mathematics, Mathematics - Combinatorics, 0101 mathematics, Finite set, Mathematics, Discrete mathematics, Applied Mathematics, 010102 general mathematics, Ramsey theory, Function (mathematics), 16. Peace & justice, Hyperplane, 010201 computation theory & mathematics, Bounded function, Combinatorics (math.CO), Ramsey's theorem, Order type

Abstract

For natural numbers d and t there exists a positive C such that if F is a family of n[superscript C] semi-algebraic sets in R[superscript d] of description complexity at most t, then there is a subset F' of F of size $n$ such that either every pair of elements in F' intersect or the elements of F' are pairwise disjoint. This result, which also holds if the intersection relation is replaced by any semi-algebraic relation of bounded description complexity, was proved by Alon, Pach, Pinchasi, Radoicic, and Sharir and improves on a bound of 4[superscript n] for the family F which follows from a straightforward application of Ramsey's theorem. We extend this semi-algebraic version of Ramsey's theorem to k-ary relations and give matching upper and lower bounds for the corresponding Ramsey function, showing that it grows as a tower of height k-1. This improves on a direct application of Ramsey's theorem by one exponential. We apply this result to obtain new estimates for some geometric Ramsey-type problems relating to order types and one-sided sets of hyperplanes. We also study the off-diagonal case, achieving some partial results., Simons Foundation (Fellowship), National Science Foundation (U.S.) (Grant DMS 1069197), NEC Corporation (MIT Award), National Science Foundation (U.S.) (Postdoctoral Fellowship), Swiss National Science Foundation (Grant 200021-125287/1)

Published

2014

43. The Ramsey number of dense graphs

Author

David Conlon

Subjects

Random graph, Mathematics::Combinatorics, General Mathematics, T-vertices, Graph, Combinatorics, Mathematics::Logic, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), Ramsey's theorem, Monochromatic color, 05C55, Mathematics

Abstract

The Ramsey number r(H) of a graph H is the smallest number n such that, in any two-colouring of the edges of K_n, there is a monochromatic copy of H. We study the Ramsey number of graphs H with t vertices and density \r, proving that r(H) \leq 2^{c \sqrt{\r} \log (2/\r) t}. We also investigate some related problems, such as the Ramsey number of graphs with t vertices and maximum degree \r t and the Ramsey number of random graphs in \mathcal{G}(t, \r), that is, graphs on t vertices where each edge has been chosen independently with probability \r., Comment: 15 pages

Published

2012

44. Hereditary quasirandomness without regularity

Author

Benny Sudakov, David Conlon, and Jacob Fox

Subjects

Polynomial (hyperelastic model), Combinatorics, Lemma (mathematics), General Mathematics, 010102 general mathematics, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), 0101 mathematics, Clique (graph theory), 01 natural sciences, Tower (mathematics), Mathematics

Abstract

A result of Simonovits and S\'os states that for any fixed graph $H$ and any $\epsilon > 0$ there exists $\delta > 0$ such that if $G$ is an $n$-vertex graph with the property that every $S \subseteq V(G)$ contains $p^{e(H)} |S|^{v(H)} \pm \delta n^{v(H)}$ labeled copies of $H$, then $G$ is quasirandom in the sense that every $S \subseteq V(G)$ contains $\frac{1}{2} p |S|^2 \pm \epsilon n^2$ edges. The original proof of this result makes heavy use of the regularity lemma, resulting in a bound on $\delta^{-1}$ which is a tower of twos of height polynomial in $\epsilon^{-1}$. We give an alternative proof of this theorem which avoids the regularity lemma and shows that $\delta$ may be taken to be linear in $\epsilon$ when $H$ is a clique and polynomial in $\epsilon$ for general $H$. This answers a problem raised by Simonovits and S\'os., Comment: 15 pages

Published

2016

45. Combinatorial theorems in sparse random sets

Author

W. T. Gowers and David Conlon

Subjects

Extremal combinatorics, Random graph, Lemma (mathematics), Hypergraph, Mathematics::Combinatorics, Mathematics - Number Theory, 010102 general mathematics, 0102 computer and information sciences, 01 natural sciences, Stability (probability), Combinatorics, Mathematics (miscellaneous), Integer, 05D40, 05C80, 05C55, 05D10, 05C35, 05C65, 11B30, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Almost surely, Combinatorics (math.CO), Number Theory (math.NT), 0101 mathematics, Statistics, Probability and Uncertainty, Constant (mathematics), Mathematics

Abstract

We develop a new technique that allows us to show in a unified way that many well-known combinatorial theorems, including Tur\'an's theorem, Szemer\'edi's theorem and Ramsey's theorem, hold almost surely inside sparse random sets. For instance, we extend Tur\'an's theorem to the random setting by showing that for every $\epsilon > 0$ and every positive integer $t \geq 3$ there exists a constant $C$ such that, if $G$ is a random graph on $n$ vertices where each edge is chosen independently with probability at least $C n^{-2/(t+1)}$, then, with probability tending to $1$ as $n$ tends to infinity, every subgraph of $G$ with at least $(1 - \frac{1}{t-1} + \epsilon) e(G)$ edges contains a copy of $K_t$. This is sharp up to the constant $C$. We also show how to prove sparse analogues of structural results, giving two main applications, a stability version of the random Tur\'an theorem stated above and a sparse hypergraph removal lemma. Many similar results have recently been obtained independently in a different way by Schacht and by Friedgut, R\"odl and Schacht., Comment: 69 pages

Published

2016

46. A note on induced Ramsey numbers

Author

Vojtěch Rödl, David Conlon, Steven La Fleur, Mathias Schacht, Domingos Dellamonica, Loebl, Martin, Nešetřil, Jaroslav, and Thomas, Robin

Subjects

Discrete mathematics, Hypergraph, Mathematics::Combinatorics, 010102 general mathematics, Natural number, 0102 computer and information sciences, Function (mathematics), 01 natural sciences, Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Mathematics - Combinatorics, Ramsey's theorem, Combinatorics (math.CO), 0101 mathematics, Mathematics

Abstract

The induced Ramsey number $r_{\mathrm{ind}}(F)$ of a $k$-uniform hypergraph $F$ is the smallest natural number $n$ for which there exists a $k$-uniform hypergraph $G$ on $n$ vertices such that every two-coloring of the edges of $G$ contains an induced monochromatic copy of $F$. We study this function, showing that $r_{\mathrm{ind}}(F)$ is bounded above by a reasonable power of $r(F)$. In particular, our result implies that $r_{\mathrm{ind}}(F) \leq 2^{2^{ct}}$ for any $3$-uniform hypergraph $F$ with $t$ vertices, mirroring the best known bound for the usual Ramsey number. The proof relies on an application of the hypergraph container method., Dedicated to the memory of Jirka Matou\v{s}ek, 10 pages, second version addresses changes arising from the referee reports

Published

2016

47. Weak quasi-randomness for uniform hypergraphs

Author

Yury Person, Mathias Schacht, David Conlon, and Hiệp Hàn

Subjects

Discrete mathematics, Mathematics::Combinatorics, Applied Mathematics, General Mathematics, Symmetric graph, Computer Graphics and Computer-Aided Design, law.invention, Planar graph, Combinatorics, symbols.namesake, Windmill graph, Graph power, law, Line graph, Graph minor, symbols, Cubic graph, Software, Forbidden graph characterization, Mathematics

Abstract

We study quasi-random properties of k-uniform hypergraphs. Our central notion is uniform edge distribution with respect to large vertex sets. We will nd several equivalent characterisations of this property and our work can be viewed as an extension of the well known Chung-Graham-Wilson theorem for quasi-random graphs. Moreover, let Kk be the complete graph on k vertices and M(k) the line graph of the graph of the k-dimensional hypercube. We will show that the pair of graphs (Kk;M(k)) has the property that if the number of copies of both Kk and M(k) in another graph G are as expected in the random graph of density d, then G is quasi-random (in the sense of the Chung-Graham-Wilson theorem) with density close to d.

Published

2011

48. Large almost monochromatic subsets in hypergraphs

Author

Benny Sudakov, David Conlon, and Jacob Fox

Subjects

Discrete mathematics, Mathematics::Combinatorics, General Mathematics, Pigeonhole principle, Complete bipartite graph, Upper and lower bounds, Combinatorics, Multipartite, Cardinality, FOS: Mathematics, Bipartite graph, Mathematics - Combinatorics, Combinatorics (math.CO), Ramsey's theorem, Monochromatic color, Mathematics

Abstract

We show that for all l and e > 0 there is a constant c = c(l, e) > 0 such that every l-coloring of the triples of an N-element set contains a subset S of size $$ c\sqrt {\log N} $$ such that at least 1 − e fraction of the triples of S have the same color. This result is tight up to the constant c and answers an open question of Erdős and Hajnal from 1989 on discrepancy in hypergraphs. For l ≥ 4 colors, it is known that there is an l-coloring of the triples of an N-element set whose largest monochromatic subset has cardinality only Θ(log log N). Thus, our result demonstrates that the maximum almost monochromatic subset that an l-coloring of the triples must contain is much larger than the corresponding monochromatic subset. This is in striking contrast with graphs, where these two quantities have the same order of magnitude. To prove our result, we obtain a new upper bound on the l-color Ramsey numbers of complete multipartite 3-uniform hypergraphs, which answers another open question of Erdős and Hajnal.

Published

2011

49. A new upper bound for diagonal Ramsey numbers

Author

David Conlon

Subjects

Mathematics::Combinatorics, Diagonal, Graph theory, Upper and lower bounds, Combinatorics, Mathematics (miscellaneous), Log-log plot, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), Ramsey's theorem, Statistics, Probability and Uncertainty, Constant (mathematics), 05C55, Mathematics

Abstract

We prove a new upper bound for diagonal two-colour Ramsey numbers, showing that there exists a constant $C$ such that \[r(k+1, k+1) \leq k^{- C \frac{\log k}{\log \log k}} \binom{2k}{k}.\], Comment: 22 pages

Published

2009

50. Hypergraph Packing and Sparse Bipartite Ramsey Numbers

Author

David Conlon

Subjects

Statistics and Probability, Discrete mathematics, Hypergraph, Applied Mathematics, Existential quantification, Probabilistic logic, Theoretical Computer Science, Combinatorics, Computational Theory and Mathematics, Integer, TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, Bipartite graph, Exponent, Ramsey's theorem, Constant (mathematics), MathematicsofComputing_DISCRETEMATHEMATICS, Mathematics

Abstract

We prove that there exists a constant c such that, for any integer Δ, the Ramsey number of a bipartite graph on n vertices with maximum degree Δ is less than 2cΔn. A probabilistic argument due to Graham, Rödl and Ruciński implies that this result is essentially sharp, up to the constant c in the exponent. Our proof hinges upon a quantitative form of a hypergraph packing result of Rödl, Ruciński and Taraz.

Published

2009