Homotopy in graphs
This thesis is an exposition of Sections 1 to 7 of the article entitled Homotopy in Q-Polynomial Distance-Regular Graphs by Heather A. Lewis submitted to Discrete Mathematics. The aforementioned article constitutes the first two chapters of Lewis' dissertation Homotopy and Distance-Regular Grap...
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| Format: | text |
| Language: | English |
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Animo Repository
1999
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| Online Access: | https://animorepository.dlsu.edu.ph/etd_masteral/2025 |
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| Institution: | De La Salle University |
| Language: | English |
| Summary: | This thesis is an exposition of Sections 1 to 7 of the article entitled Homotopy in Q-Polynomial Distance-Regular Graphs by Heather A. Lewis submitted to Discrete Mathematics. The aforementioned article constitutes the first two chapters of Lewis' dissertation Homotopy and Distance-Regular Graphs , University of Wisconsin Madison, U.S.A., 1997.Let G denote an undirected graph without loops or multiple edges. Fix a vertex x in G, and consider the set u/(x) of all closed paths in G with base vertex x. We define a relation on this set, called homotophy, and prove that it is an equivalence relation. We denote the equivalence classes by minimum degree (x) and show that path concatenation induces a group structure on minimum degree (x). We define essential length of an element in minimum degree (x), and using this concept, we define a collection of subgroups minimum degree (x,i).Now, suppose x, y are vertices in G, and suppose there exists a path from x to y. We show the groups minimum degree (x) and minimum degree (y) are isomorphic, and that the isomorphism preserves essential length.We define a geodesic path and prove a sufficient condition for a path to be geodesic. Finally, we assume G is finite and connected with diameter d. We find an upper bound for the length of a geodesic closed path. We prove that for any fix vertex x, minimum degree (x,2d+1)=minimum degree (x). |
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