Turán number and decomposition number of intersecting odd cycles

Abstract The Turán number ex(n, H) of a graph H is the maximal number of edges in an H-free graph on n vertices. In 1983, Chung and Erdős asked which graphs H with e edges minimise ex(n, H). They resolved this question asymptotically for most of the range of e and asked to complete the picture. In this paper, we answer their question by resolving all remaining cases. Our result translates directly to the setting of universality, a well-studied notion of finding graphs which contain every graph belonging to a certain family. In this setting, we extend previous work done by Babai, Chung, Erdős, Graham and Spencer, and by Alon and Asodi.

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Solar-cycle phenomena in cosmic-ray intensity: Differences between even and odd cycles

Earth Moon and Planets ◽

10.1007/bf00058488 ◽

1988 ◽

Vol 42 (3) ◽

pp. 233-244 ◽

Cited By ~ 13

Author(s):

H. Mavromichalaki ◽

E. Marmatsouri ◽

A. Vassilaki

Keyword(s):

Solar Cycle ◽

Cosmic Ray ◽

Cosmic Ray Intensity ◽

Odd Cycles

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On the cover Turán number of Berge hypergraphs

European Journal of Combinatorics ◽

10.1016/j.ejc.2021.103416 ◽

2021 ◽

Vol 98 ◽

pp. 103416

Author(s):

Linyuan Lu ◽

Zhiyu Wang

Keyword(s):

Turán Number

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Variations in solar and geomagnetic activity with periods near to 1.3 year

Open Geosciences ◽

10.2478/v10085-009-0010-y ◽

2009 ◽

Vol 1 (2) ◽

Cited By ~ 3

Author(s):

Jaroslav Střeštïk

Keyword(s):

Geomagnetic Activity ◽

Time Series Data ◽

Interplanetary Space ◽

Short Interval ◽

Biological Data ◽

Series Data ◽

Solar Cycles ◽

Lower Amplitude ◽

Periodic Signals ◽

Odd Cycles

AbstractIt is known that solar wind velocity fluctuates regularly with a period of about 1.3 years. This periodicity (and other signals with periods near to 1.1 and 0.9 years) has also been observed in biological data. The variation is a temporary feature, mostly being observed in the early 1990s. Here, the occurrence of these periodic signals in solar and geomagnetic activity between 1932 and 2005 has been investigated. The signal with 1.3 year period is present in geomagnetic activity only in a short interval after 1990 and to a lesser extent around 1942. At other times the signal is very weak or not present at all. Other periods are much lower amplitude and appear only sporadically throughout the time investigated. A connection between these periods and solar cycles (e.g. different even or odd cycles) has not been proven. It is possible that there is a long-term periodicity in the occurrence of the 1.3 year period but the time series data available is insufficient to confirm this. There are no such periodicities in solar activity. In order to gain a greater understanding of these periodic signals, we should search for their origin in interplanetary space.

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The formula for Turán number of spanning linear forests

Discrete Mathematics ◽

10.1016/j.disc.2020.111924 ◽

2020 ◽

Vol 343 (8) ◽

pp. 111924

Author(s):

Bo Ning ◽

Jian Wang

Keyword(s):

Turán Number

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An Ordered Turán Problem for Bipartite Graphs

The Electronic Journal of Combinatorics ◽

10.37236/2471 ◽

2012 ◽

Vol 19 (4) ◽

Author(s):

Craig Timmons

Keyword(s):

Complete Bipartite Graph ◽

Bipartite Graphs ◽

Free Graph ◽

The Family ◽

Turan Problem ◽

Vertex Graph ◽

Turán Number ◽

Turán Problem ◽

Natural Way

Let $F$ be a graph. A graph $G$ is $F$-free if it does not contain $F$ as a subgraph. The Turán number of $F$, written $\textrm{ex}(n,F)$, is the maximum number of edges in an $F$-free graph with $n$ vertices. The determination of Turán numbers of bipartite graphs is a challenging and widely investigated problem. In this paper we introduce an ordered version of the Turán problem for bipartite graphs. Let $G$ be a graph with $V(G) = \{1, 2, \dots , n \}$ and view the vertices of $G$ as being ordered in the natural way. A zig-zag $K_{s,t}$, denoted $Z_{s,t}$, is a complete bipartite graph $K_{s,t}$ whose parts $A = \{n_1 < n_2 < \dots < n_s \}$ and $B = \{m_1 < m_2 < \dots < m_t \}$ satisfy the condition $n_s < m_1$. A zig-zag $C_{2k}$ is an even cycle $C_{2k}$ whose vertices in one part precede all of those in the other part. Write $\mathcal{Z}_{2k}$ for the family of zig-zag $2k$-cycles. We investigate the Turán numbers $\textrm{ex}(n,Z_{s,t})$ and $\textrm{ex}(n,\mathcal{Z}_{2k})$. In particular we show $\textrm{ex}(n, Z_{2,2}) \leq \frac{2}{3}n^{3/2} + O(n^{5/4})$. For infinitely many $n$ we construct a $Z_{2,2}$-free $n$-vertex graph with more than $(n - \sqrt{n} - 1) + \textrm{ex} (n,K_{2,2})$ edges.

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Between 2- and 3-Colorability

The Electronic Journal of Combinatorics ◽

10.37236/4673 ◽

2015 ◽

Vol 22 (1) ◽

Cited By ~ 1

Author(s):

Alan Frieze ◽

Wesley Pegden

Keyword(s):

Positive Integer ◽

Random Graphs ◽

The Other ◽

Chromatic Numbers ◽

Other Hand ◽

Odd Cycles

We consider the question of the existence of homomorphisms between $G_{n,p}$ and odd cycles when $p=c/n$, $1<c\leq 4$. We show that for any positive integer $\ell$, there exists $\epsilon=\epsilon(\ell)$ such that if $c=1+\epsilon$ then w.h.p. $G_{n,p}$ has a homomorphism from $G_{n,p}$ to $C_{2\ell+1}$ so long as its odd-girth is at least $2\ell+1$. On the other hand, we show that if $c=4$ then w.h.p. there is no homomorphism from $G_{n,p}$ to $C_5$. Note that in our range of interest, $\chi(G_{n,p})=3$ w.h.p., implying that there is a homomorphism from $G_{n,p}$ to $C_3$. These results imply the existence of random graphs with circular chromatic numbers $\chi_c$ satisfying $2<\chi_c(G)<2+\delta$ for arbitrarily small $\delta$, and also that $2.5\leq \chi_c(G_{n,\frac 4 n})<3$ w.h.p.

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A Turán Type Problem Concerning the Powers of the Degrees of a Graph

The Electronic Journal of Combinatorics ◽

10.37236/1525 ◽

2000 ◽

Vol 7 (1) ◽

Cited By ~ 5

Author(s):

Yair Caro ◽

Raphael Yuster

Keyword(s):

Positive Integer ◽

Lower Bounds ◽

Degree Sequence ◽

Upper And Lower Bounds ◽

Exact Results ◽

Type Problem ◽

Maximum Value ◽

Turán Number

For a graph $G$ whose degree sequence is $d_{1},\ldots ,d_{n}$, and for a positive integer $p$, let $e_{p}(G)=\sum_{i=1}^{n}d_{i}^{p}$. For a fixed graph $H$, let $t_{p}(n,H)$ denote the maximum value of $e_{p}(G)$ taken over all graphs with $n$ vertices that do not contain $H$ as a subgraph. Clearly, $t_{1}(n,H)$ is twice the Turán number of $H$. In this paper we consider the case $p>1$. For some graphs $H$ we obtain exact results, for some others we can obtain asymptotically tight upper and lower bounds, and many interesting cases remain open.

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A note on compact and compact circular edge-colorings of graphs

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.431 ◽

2008 ◽

Vol Vol. 10 no. 3 (Graph and Algorithms) ◽

Author(s):

Dariusz Dereniowski ◽

Adam Nadolski

Keyword(s):

Approximation Algorithm ◽

Decision Problem ◽

Edge Coloring ◽

Exact Algorithm ◽

Weighted Graphs ◽

Edge Colorings ◽

Odd Cycle ◽

International Audience ◽

Np Complete ◽

Odd Cycles

Graphs and Algorithms International audience We study two variants of edge-coloring of edge-weighted graphs, namely compact edge-coloring and circular compact edge-coloring. First, we discuss relations between these two coloring models. We prove that every outerplanar bipartite graph admits a compact edge-coloring and that the decision problem of the existence of compact circular edge-coloring is NP-complete in general. Then we provide a polynomial time 1:5-approximation algorithm and pseudo-polynomial exact algorithm for compact circular coloring of odd cycles and prove that it is NP-hard to optimally color these graphs. Finally, we prove that if a path P2 is joined by an edge to an odd cycle then the problem of the existence of a compact circular coloring becomes NP-complete.

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