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تسجيل مستخدم جديدProper vertex-pancyclicity of edge-colored complete graphs without joint monochromatic triangles
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In an edge-colored graph $(G,c)$, let $d^c(v)$ denote the number of colors on the edges incident with a vertex $v$ of $G$ and $delta^c(G)$ denote the minimum value of $d^c(v)$ over all vertices $vin V(G)$. A cycle of $(G,c)$ is called proper if any two adjacent edges of the cycle have distinct colors. An edge-colored graph $(G,c)$ on $ngeq 3$ vertices is called properly vertex-pancyclic if each vertex of $(G,c)$ is contained in a proper cycle of length $ell$ for every $ell$ with $3 le ell le n$. Fujita and Magnant conjectured that every edge-colored complete graph on $ngeq 3$ vertices with $delta^c(G)geq frac{n+1}{2}$ is properly vertex-pancyclic. Chen, Huang and Yuan partially solve this conjecture by adding an extra condition that $(G,c)$ does not contain any monochromatic triangle. In this paper, we show that this conjecture is true if the edge-colored complete graph contain no joint monochromatic triangles.
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