On some packing and partition problems in geometric graphs

Graph packing problem refers to the problem of finding maximum number of edge-disjoint copies of a fixed subgraph in a given graph G. A related problem is the partition problem. In this case, the edge-disjoint subgraphs are sought but require that the union of subgraphs in this packing is exactly...

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Bibliographic Details
Main Author: Trao, Hazim Michman
Format: Thesis
Language:English
Published: 2018
Subjects:
Online Access:http://psasir.upm.edu.my/id/eprint/76910/1/FS%202018%2085%20-%20IR.pdf
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Summary:Graph packing problem refers to the problem of finding maximum number of edge-disjoint copies of a fixed subgraph in a given graph G. A related problem is the partition problem. In this case, the edge-disjoint subgraphs are sought but require that the union of subgraphs in this packing is exactly G. It is often useful to restrict the subgraphs of G to a certain graph or property. In this thesis, packing and partition problems are studied for different properties such as matching, tree and cycle, and these problems are considered in various geometric graphs. The families of geometric graphs that are investigated include the complete geometric graphs, triangle-free geometric graphs, and complete bipartite geometric graphs. First, the problem of partitioning the complete geometric graph into plane spanning trees is investigated, giving sufficient conditions, which generalize the convex case and the wheel configuration case. The problem of packing plane perfect matchings is studied in triangle-free geometric graphs where we establish lower and upper bounds for the problem. An algorithm for computing such plane perfect matchings is also presented. Moreover, a sufficient condition is provided for the existence the set of edge-disjoint plane perfect matchings whose union is a maximal triangle-free geometric graph. Furthermore, the problem of partitioning the complete bipartite geometric graphs into plane perfect matchings is studied and sufficient conditions for the problem are presented. Finally, the problem of packing 1-plane Hamiltonian cycles into the complete geometric graph is studied in order to establish lower and upper bounds for the problem. An algorithm for computing such 1-plane Hamiltonian cycles is also presented.