{"title":"Lagrangian-Perfect Hypergraphs","authors":"Zilong Yan, Yuejian Peng","doi":"10.1007/s00026-022-00634-y","DOIUrl":null,"url":null,"abstract":"<div><p>Hypergraph Lagrangian function has been a helpful tool in several celebrated results in extremal combinatorics. Let <i>G</i> be an <i>r</i>-uniform graph on [<i>n</i>] and let <span>\\({\\textbf{x}}=(x_1,\\ldots ,x_n) \\in [0,\\infty )^n.\\)</span> The graph Lagrangian function is defined to be <span>\\(\\lambda (G,{\\textbf{x}})=\\sum _{e \\in E(G)}\\prod _{i\\in e}x_{i}.\\)</span> The graph Lagrangian is defined as <span>\\(\\lambda (G)=\\max \\{\\lambda (G, {\\textbf{x}}): {\\textbf{x}} \\in \\Delta \\},\\)</span> where <span>\\(\\Delta =\\{{\\textbf{x}}=(x_1,x_2,\\ldots ,x_n) \\in [0, 1]^{n}: x_1+x_2+\\dots +x_n =1 \\}.\\)</span> The Lagrangian density <span>\\(\\pi _{\\lambda }(F)\\)</span> of an <i>r</i>-graph <i>F</i> is defined to be <span>\\(\\pi _{\\lambda }(F)=\\sup \\{r! \\lambda (G): G \\text { does not contain }F \\}.\\)</span> Sidorenko (Combinatorica 9:207–215, 1989) showed that the Lagrangian density of an <i>r</i>-uniform hypergraph <i>F</i> is the same as the Turán density of the extension of <i>F</i>. Therefore, determining the Lagrangian density of a hypergraph will add a result to the very few known results on Turán densities of hypergraphs. For an <i>r</i>-uniform graph <i>H</i> with <i>t</i> vertices, <span>\\(\\pi _{\\lambda }(H)\\ge r!\\lambda {(K_{t-1}^r)}\\)</span> since <span>\\(K_{t-1}^r\\)</span> (the complete <i>r</i>-uniform graph with <span>\\(t-1\\)</span> vertices) does not contain a copy of <i>H</i>. We say that an <i>r</i>-uniform hypergraph <i>H</i> with <i>t</i> vertices is <span>\\(\\lambda \\)</span>-perfect if the equality <span>\\(\\pi _{\\lambda }(H)= r!\\lambda {(K_{t-1}^r)}\\)</span> holds. A fundamental theorem of Motzkin and Straus implies that all 2-uniform graphs are <span>\\(\\lambda \\)</span>-perfect. It is interesting to understand the <span>\\(\\lambda \\)</span>-perfect property for <span>\\(r\\ge 3.\\)</span> Our first result is to show that the disjoint union of a <span>\\(\\lambda \\)</span>-perfect 3-graph and <span>\\(S_{2,t}=\\{123,124,125,126,\\ldots ,12(t+2)\\}\\)</span> is <span>\\(\\lambda \\)</span>-perfect, this result implies several previous results: Taking <i>H</i> to be the 3-graph spanned by one edge and <span>\\(t=1,\\)</span> we obtain the result by Hefetz and Keevash (J Comb Theory Ser A 120:2020–2038, 2013) that a 3-uniform matching of size 2 is <span>\\(\\lambda \\)</span>-perfect. Doing it repeatedly, we obtain the result in Jiang et al. (Eur J Comb 73:20–36, 2018) that any 3-uniform matching is <span>\\(\\lambda \\)</span>-perfect. Taking <i>H</i> to be the 3-uniform linear path of length 2 or 3 and <span>\\(t=1\\)</span> repeatedly, we obtain the results in Hu et al. (J Comb Des 28:207–223, 2020). Earlier results indicate that <span>\\(K_4^{3-}=\\{123, 124, 134\\}\\)</span> and <span>\\(F_5=\\{123, 124, 345\\}\\)</span> are not <span>\\(\\lambda \\)</span>-perfect, we show that the disjoint union of <span>\\(K_4^{3-}\\)</span> (or <span>\\(F_5\\)</span>) and <span>\\(S_{2,t}\\)</span> are <span>\\(\\lambda \\)</span>-perfect. Furthermore, we show the disjoint union of a 3-uniform hypergraph <i>H</i> and <span>\\(S_{2,t}\\)</span> is <span>\\(\\lambda \\)</span>-perfect if <i>t</i> is large. We also give an irrational Lagrangian density of a family of four 3-uniform hypergraphs.</p></div>","PeriodicalId":0,"journal":{"name":"","volume":null,"pages":null},"PeriodicalIF":0.0,"publicationDate":"2023-01-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"","FirstCategoryId":"100","ListUrlMain":"https://link.springer.com/article/10.1007/s00026-022-00634-y","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 1
Abstract
Hypergraph Lagrangian function has been a helpful tool in several celebrated results in extremal combinatorics. Let G be an r-uniform graph on [n] and let \({\textbf{x}}=(x_1,\ldots ,x_n) \in [0,\infty )^n.\) The graph Lagrangian function is defined to be \(\lambda (G,{\textbf{x}})=\sum _{e \in E(G)}\prod _{i\in e}x_{i}.\) The graph Lagrangian is defined as \(\lambda (G)=\max \{\lambda (G, {\textbf{x}}): {\textbf{x}} \in \Delta \},\) where \(\Delta =\{{\textbf{x}}=(x_1,x_2,\ldots ,x_n) \in [0, 1]^{n}: x_1+x_2+\dots +x_n =1 \}.\) The Lagrangian density \(\pi _{\lambda }(F)\) of an r-graph F is defined to be \(\pi _{\lambda }(F)=\sup \{r! \lambda (G): G \text { does not contain }F \}.\) Sidorenko (Combinatorica 9:207–215, 1989) showed that the Lagrangian density of an r-uniform hypergraph F is the same as the Turán density of the extension of F. Therefore, determining the Lagrangian density of a hypergraph will add a result to the very few known results on Turán densities of hypergraphs. For an r-uniform graph H with t vertices, \(\pi _{\lambda }(H)\ge r!\lambda {(K_{t-1}^r)}\) since \(K_{t-1}^r\) (the complete r-uniform graph with \(t-1\) vertices) does not contain a copy of H. We say that an r-uniform hypergraph H with t vertices is \(\lambda \)-perfect if the equality \(\pi _{\lambda }(H)= r!\lambda {(K_{t-1}^r)}\) holds. A fundamental theorem of Motzkin and Straus implies that all 2-uniform graphs are \(\lambda \)-perfect. It is interesting to understand the \(\lambda \)-perfect property for \(r\ge 3.\) Our first result is to show that the disjoint union of a \(\lambda \)-perfect 3-graph and \(S_{2,t}=\{123,124,125,126,\ldots ,12(t+2)\}\) is \(\lambda \)-perfect, this result implies several previous results: Taking H to be the 3-graph spanned by one edge and \(t=1,\) we obtain the result by Hefetz and Keevash (J Comb Theory Ser A 120:2020–2038, 2013) that a 3-uniform matching of size 2 is \(\lambda \)-perfect. Doing it repeatedly, we obtain the result in Jiang et al. (Eur J Comb 73:20–36, 2018) that any 3-uniform matching is \(\lambda \)-perfect. Taking H to be the 3-uniform linear path of length 2 or 3 and \(t=1\) repeatedly, we obtain the results in Hu et al. (J Comb Des 28:207–223, 2020). Earlier results indicate that \(K_4^{3-}=\{123, 124, 134\}\) and \(F_5=\{123, 124, 345\}\) are not \(\lambda \)-perfect, we show that the disjoint union of \(K_4^{3-}\) (or \(F_5\)) and \(S_{2,t}\) are \(\lambda \)-perfect. Furthermore, we show the disjoint union of a 3-uniform hypergraph H and \(S_{2,t}\) is \(\lambda \)-perfect if t is large. We also give an irrational Lagrangian density of a family of four 3-uniform hypergraphs.
超图拉格朗日函数在极值组合学的几个著名结果中是一个有用的工具。设G是[n]上的r-一致图,并且设\({\textbf{x}}=(x_1,\ldots,x_n)\ in[0,\infty)^n。\)图拉格朗日函数被定义为\(\lambda(G,{\txtbf{s})=\sum_{e\in e(G)}\prod_{i\ in e}x_{i}。\)\},\)其中\(\Delta=\{\textbf{x}}=(x_1,x_2,\ldots,x_n)\在[0,1]^{n}中:x_1+x_2+\dots+x_n=1\)r图F的拉格朗日密度\(\pi_{\lambda}(F)\)被定义为\(\pi-{\ lambda}(F)=\sup\{r!\lambda(G):G\text{不包含}F\}。\)Sidorenko(Combinatorica 9:207–2151989)证明了r-一致超图F的拉格朗日密度与F的扩张的Turán密度相同。因此,确定超图的拉格朗日密度将为关于超图的Turón密度的极少数已知结果增加一个结果。对于具有t个顶点的r-一致图H!\λ{(K_{t-1}^r)}),因为\(K_!\λ{(K_{t-1}^r)}\)成立。Motzkin和Straus的一个基本定理暗示了所有2-一致图都是\(λ)-完美图。理解\(r\ge3)的\(\lambda\)-完美性质是很有趣的。我们的第一个结果是证明\(\λ\)-完全3-图和\(S_{2,t}=\{123124125126,\ldots,12(t+2)\}\)的不相交并集是\,这个结果暗示了以前的几个结果:将H设为由一条边跨越的3-图,并且\(t=1,\)我们得到了Hefetz和Keevash的结果(J Comb Theory Ser A 120:2020–20382013),大小为2的3-一致匹配是\(λ\)-完美的。重复进行,我们在Jiang等人(Eur J Comb 73:20–361018)中得到了任何3-一致匹配都是\(\lambda\)-完美的结果。将H设为长度为2或3的3-均匀线性路径,并重复\(t=1\),我们在Hu等人中得到了结果。(J Comb-Des 28:207–2232020)。早期的结果表明,(K_4^{3-}=(123124134\)和(F_5=(123123345\))不是(λ)-完美的,我们证明了(K_4^{3-})(或(F_5\))和(S_{2,t})的不相交并集是(λ)完美的。此外,我们还证明了3-一致超图H与(S_{2,t})的不相交并集是(λ)-完美的,如果t很大。我们还给出了四个3-一致超图族的无理拉格朗日密度。
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