{"title":"Complexity of Some Types of Cyclic Snake Graphs","authors":"Basma Mohamed, Mohamed Amin","doi":"10.11648/j.mma.20240901.12","DOIUrl":null,"url":null,"abstract":"The number of spanning trees in graphs (networks) is a crucial invariant, and it is also an important measure of the reliability of a network. Spanning trees are special subgraphs of a graph that have several important properties. First, <I>T</I> must span <I>G</I>, which means it must contain every vertex in graph <I>G</I>, if <I>T</I> is a spanning tree of graph <I>G</I>. <I>T</I> needs to be a subgraph of <I>G</I>, second. Stated differently, any edge present in <I>T</I> needs to be present in <I>G </I>as well. Third, <I>G</I> is the same as <I>T</I> if each edge in <I>T</I> is likewise present in <I>G</I>. In path-finding algorithms like Dijkstra's shortest path algorithm and A* search algorithm, spanning trees play an essential part. In those approaches, spanning trees are computed as component components. Protocols for network routing also take advantage of it. In numerous techniques and applications, minimum spanning trees are highly beneficial. Computer networks, electrical grids, and water networks all frequently use them. They are also utilized in significant algorithms like the min-cut max-flow algorithm and in graph issues like the travelling salesperson problem. In this paper, we use matrix analysis and linear algebra techniques to obtain simple formulas for the number of spanning trees of certain kinds of cyclic snake graphs.","PeriodicalId":340874,"journal":{"name":"Mathematical Modelling and Applications","volume":"720 ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-02-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Mathematical Modelling and Applications","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.11648/j.mma.20240901.12","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
The number of spanning trees in graphs (networks) is a crucial invariant, and it is also an important measure of the reliability of a network. Spanning trees are special subgraphs of a graph that have several important properties. First, T must span G, which means it must contain every vertex in graph G, if T is a spanning tree of graph G. T needs to be a subgraph of G, second. Stated differently, any edge present in T needs to be present in G as well. Third, G is the same as T if each edge in T is likewise present in G. In path-finding algorithms like Dijkstra's shortest path algorithm and A* search algorithm, spanning trees play an essential part. In those approaches, spanning trees are computed as component components. Protocols for network routing also take advantage of it. In numerous techniques and applications, minimum spanning trees are highly beneficial. Computer networks, electrical grids, and water networks all frequently use them. They are also utilized in significant algorithms like the min-cut max-flow algorithm and in graph issues like the travelling salesperson problem. In this paper, we use matrix analysis and linear algebra techniques to obtain simple formulas for the number of spanning trees of certain kinds of cyclic snake graphs.
图(网络)中的生成树数量是一个重要的不变量,也是衡量网络可靠性的一个重要指标。生成树是图的特殊子图,具有几个重要特性。首先,如果 T 是图 G 的生成树,T 必须跨越 G,这意味着它必须包含图 G 中的每个顶点。换句话说,T 中存在的任何边也必须存在于 G 中。第三,如果 T 中的每条边也同样存在于 G 中,那么 G 就与 T 相同。在路径查找算法(如 Dijkstra 的最短路径算法和 A* 搜索算法)中,生成树起着至关重要的作用。在这些算法中,生成树是作为组成部分来计算的。网络路由协议也利用了它。在许多技术和应用中,最小生成树都大有裨益。计算机网络、电网和水网都经常使用它们。最小生成树还被用于重要算法(如最小切割最大流量算法)和图问题(如旅行推销员问题)中。在本文中,我们利用矩阵分析和线性代数技术,获得了某些类型循环蛇形图的生成树数的简单公式。
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