scholarly journals A lower bound for the number of triangular embeddings of some complete graphs and complete regular tripartite graphs

2008 ◽  
Vol 98 (4) ◽  
pp. 637-650 ◽  
Author(s):  
M.J. Grannell ◽  
T.S. Griggs
Keyword(s):  
Lower Bound ◽  
Complete Graphs ◽  
Tripartite Graphs

scholarly journals Minimum Number of Monotone Subsequences of Length 4 in Permutations

2014 ◽  
Vol 24 (4) ◽  
pp. 658-679 ◽  
Author(s):  
JÓZSEF BALOGH ◽  
PING HU ◽  
BERNARD LIDICKÝ ◽  
OLEG PIKHURKO ◽  
BALÁZS UDVARI ◽  
...  
Keyword(s):  
Lower Bound ◽  
Complete Graphs ◽  
Formula Group ◽  
Minimum Number ◽  
Additional Stability ◽  
Edge Colourings ◽  
Image Position

We show that for every sufficiently largen, the number of monotone subsequences of length four in a permutation onnpoints is at least\begin{equation*} \binom{\lfloor{n/3}\rfloor}{4} + \binom{\lfloor{(n+1)/3}\rfloor}{4} + \binom{\lfloor{(n+2)/3}\rfloor}{4}. \end{equation*}Furthermore, we characterize all permutations on [n] that attain this lower bound. The proof uses the flag algebra framework together with some additional stability arguments. This problem is equivalent to some specific type of edge colourings of complete graphs with two colours, where the number of monochromaticK4is minimized. We show that all the extremal colourings must contain monochromaticK4only in one of the two colours. This translates back to permutations, where all the monotone subsequences of length four are all either increasing, or decreasing only.

scholarly journals On the Ramsey Number $R(4,6)$

10.37236/2102 ◽  
2012 ◽  
Vol 19 (1) ◽  
Author(s):  
Geoffrey Exoo
Keyword(s):  
Fixed Point ◽  
Automorphism Group ◽  
Lower Bound ◽  
Heuristic Search ◽  
Ramsey Number ◽  
Complete Graphs ◽  
Search Procedure ◽  
Edge Colorings

The lower bound for the classical Ramsey number $R(4,6)$ is improved from 35 to 36. The author has found 37 new edge colorings of $K_{35}$ that have no complete graphs of order 4 in the first color, and no complete graphs of order 6 in the second color. The most symmetric of the colorings has an automorphism group of order 4, with one fixed point, and is presented in detail. The colorings were found using a heuristic search procedure.

scholarly journals An Improvement to Mathon's Cyclotomic Ramsey Colorings

10.37236/239 ◽  
2009 ◽  
Vol 16 (1) ◽  
Author(s):  
Xiaodong Xu ◽  
Stanisław P. Radziszowski
Keyword(s):  
Lower Bound ◽  
Complete Graphs ◽  
Maximum Order ◽  
Ramsey Numbers

In this note we show how to extend Mathon's cyclotomic colorings of the edges of some complete graphs without increasing the maximum order of monochromatic complete subgraphs. This improves the well known lower bound construction for multicolor Ramsey numbers, in particular we obtain $R_3(7) \ge 3214$.

On Cyclic Decompositions of Complete Graphs into Tripartite Graphs

2012 ◽  
Vol 72 (1) ◽  
pp. 90-111 ◽  
Author(s):  
Ryan C. Bunge ◽  
Avapa Chantasartrassmee ◽  
Saad I. El-Zanati ◽  
Charles Vanden Eynden
Keyword(s):  
Complete Graphs ◽  
Tripartite Graphs

scholarly journals On 1-rotational decompositions of complete graphs into tripartite graphs

2019 ◽  
Vol 39 (5) ◽  
pp. 623-643
Author(s):  
Ryan C. Bunge
Keyword(s):  
Positive Integer ◽  
Simple Graph ◽  
Vertex Coloring ◽  
Complete Graphs ◽  
Tripartite Graph ◽  
Tripartite Graphs ◽  
Proper Vertex

Consider a tripartite graph to be any simple graph that admits a proper vertex coloring in at most 3 colors. Let \(G\) be a tripartite graph with \(n\) edges, one of which is a pendent edge. This paper introduces a labeling on such a graph \(G\) used to achieve 1-rotational \(G\)-decompositions of \(K_{2nt}\) for any positive integer \(t\). It is also shown that if \(G\) with a pendent edge is the result of adding an edge to a path on \(n\) vertices, then \(G\) admits such a labeling.

scholarly journals The total disjoint irregularity strength of some certain graphs

2020 ◽  
Vol 4 (2) ◽  
pp. 91
Author(s):  
Meilin I Tilukay ◽  
A. N. M. Salman
Keyword(s):  
Lower Bound ◽  
Title Page ◽  
Edge Weight ◽  
Complete Graphs ◽  
Vertex Weight ◽  
Minimum Value ◽  
Irregularity Strength

<div class="page" title="Page 1"><div class="layoutArea"><div class="column"><p><span>Under a totally irregular total </span><em>k</em><span>-labeling of a graph </span><span><em>G</em> </span><span>= (</span><span><em>V</em>,<em>E</em></span><span>), we found that for some certain graphs, the edge-weight set </span><em>W</em><span>(</span><em>E</em><span>) and the vertex-weight set </span><em>W</em><span>(</span><em>V</em><span>) of </span><span><em>G</em> </span><span>which are induced by </span><span><em>k</em> </span><span>= </span><span>ts</span><span>(</span><em>G</em><span>), </span><em>W</em><span>(</span><em>E</em><span>) </span><span>∩ </span><em>W</em><span>(</span><em>V</em><span>) is a non empty set. For which </span><span>k</span><span>, a graph </span><span>G </span><span>has a totally irregular total labeling if </span><em>W</em><span>(</span><em>E</em><span>) </span><span>∩ </span><em>W</em><span>(</span><em>V</em><span>) = </span><span>∅</span><span>? We introduce the total disjoint irregularity strength, denoted by </span><span>ds</span><span>(</span><em>G</em><span>), as the minimum value </span><span><em>k</em> </span><span>where this condition satisfied. We provide the lower bound of </span><span>ds</span><span>(</span><em>G</em><span>) and determine the total disjoint irregularity strength of cycles, paths, stars, and complete graphs.</span></p></div></div></div>

scholarly journals Expansion of Percolation Critical Points for Hamming Graphs

2019 ◽  
Vol 29 (1) ◽  
pp. 68-100
Author(s):  
Lorenzo Federico ◽  
Remco Van Der Hofstad ◽  
Frank Den Hollander ◽  
Tim Hulshof
Keyword(s):  
Lower Bound ◽  
Cartesian Product ◽  
Branching Random Walk ◽  
Bond Percolation ◽  
Complete Graphs ◽  
Lace Expansion ◽  
Critical Window ◽  
Hamming Graphs ◽  
Image Position ◽  
Crucial Ingredient

AbstractThe Hamming graph H(d, n) is the Cartesian product of d complete graphs on n vertices. Let ${m=d(n-1)}$ be the degree and $V = n^d$ be the number of vertices of H(d, n). Let $p_c^{(d)}$ be the critical point for bond percolation on H(d, n). We show that, for $d \in \mathbb{N}$ fixed and $n \to \infty$, $$p_c^{(d)} = {1 \over m} + {{2{d^2} - 1} \over {2{{(d - 1)}^2}}}{1 \over {{m^2}}} + O({m^{ - 3}}) + O({m^{ - 1}}{V^{ - 1/3}}),$$ which extends the asymptotics found in [10] by one order. The term $O(m^{-1}V^{-1/3})$ is the width of the critical window. For $d=4,5,6$ we have $m^{-3} = O(m^{-1}V^{-1/3})$, and so the above formula represents the full asymptotic expansion of $p_c^{(d)}$. In [16] we show that this formula is a crucial ingredient in the study of critical bond percolation on H(d, n) for $d=2,3,4$. The proof uses a lace expansion for the upper bound and a novel comparison with a branching random walk for the lower bound. The proof of the lower bound also yields a refined asymptotics for the susceptibility of a subcritical Erdös–Rényi random graph.

scholarly journals A Global Poincaré inequality on Graphs via a Conical Curvature-Dimension Condition

2018 ◽  
Vol 6 (1) ◽  
pp. 32-47 ◽  
Author(s):  
Sajjad Lakzian ◽  
Zachary Mcguirk
Keyword(s):  
Lower Bound ◽  
Sharp Estimate ◽  
Sufficient Conditions ◽  
Poincaré Inequality ◽  
Complete Graphs ◽  
Poincare Inequality ◽  
Underlying Graph ◽  
Dimension Analysis ◽  
Necessary And Sufficient ◽  
Sharp Lower Bound

Abstract We introduce and study the conical curvature-dimension condition, CCD(K, N), for finite graphs.We show that CCD(K, N) provides necessary and sufficient conditions for the underlying graph to satisfy a sharp global Poincaré inequality which in turn translates to a sharp lower bound for the first eigenvalues of these graphs. Another application of the conical curvature-dimension analysis is finding a sharp estimate on the curvature of complete graphs

scholarly journals A Lower Bound on the Average Degree Forcing a Minor

10.37236/8847 ◽  
2020 ◽  
Vol 27 (1) ◽  
Author(s):  
Sergey Norin ◽  
Bruce Reed ◽  
Andrew Thomason ◽  
David R. Wood
Keyword(s):  
Lower Bound ◽  
Upper Bound ◽  
Constant Factor ◽  
Average Degree ◽  
Complete Graphs ◽  
Sparse Graphs ◽  
Dense Graphs ◽  
A Minor

We show that for sufficiently large $d$ and for $t\geq d+1$,  there is a graph $G$ with average degree $(1-\varepsilon)\lambda  t \sqrt{\ln d}$ such that almost every graph $H$ with $t$ vertices and average degree $d$ is not a minor of $G$, where $\lambda=0.63817\dots$ is an explicitly defined constant. This generalises analogous results for complete graphs by Thomason (2001) and for general dense graphs by Myers and Thomason (2005). It also shows that an upper bound for sparse graphs by Reed and Wood (2016) is best possible up to a constant factor.

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