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Realizability of Graphs Maria Belk and Robert Connelly.

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1 Realizability of Graphs Maria Belk and Robert Connelly

2 Graph Graphs: A graph has vertices…      

3 Graph Graphs: A graph has vertices and edges.      

4 Graph Graphs: A graph contains vertices and edges. Each edge connects two vertices.       The edge 

5 Realization Realization: A realization of a graph  is a placement of the vertices in some  .            

6 Realization Here are two realizations of the same graph:         

7  -realizability  -realizable: A graph is  -realizable if any realization can be moved into a  -dimensional subspace without changing the edge lengths. Example: A path is  -realizable.

8 Which graphs are  -realizable?

9 Tree: A connected graph without any cycles. Every tree is  -realizable.

10 Which graphs are  -realizable? The triangle is not  -realizable. But it is  -realizable.

11 Which graphs are  -realizable? The  -gon is not  -realizable. Neither is any graph that contains the  -gon.

12 Which graphs are  -realizable? The  -gon is not  -realizable. Neither is any graph that contains the  -gon.     

13 Theorem. (Connelly)  -realizable = Trees

14 Which graphs are  -realizable?

15  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

16  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

17  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

18  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

19  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

20 2-tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

21  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

22  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

23  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

24  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

25  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

26  -tree: Start with a triangle. Attach another triangle along an edge. Continue attaching triangles to edges.  -realizability

27  -trees are  -realizable.  -realizability

28 Partial  -tree: Subgraph of a  -tree

29  -realizability

30 Partial  -tree: Subgraph of a  -tree  -realizability

31 Partial  -trees are also  -realizable.

32  -realizability The tetrahedron is not  -realizable. But it is  -realizable.

33  -realizability Theorem. (Belk and Connelly) The following are equivalent:  is a partial  -tree.  does not “contain” the tetrahedron.  is  -realizable.

34 Realizability AllowedForbidden  -realizabilityTrees  -realizabilityPartial  -trees

35 Which graphs are  -realizable?

36 3-realizability  -tree: Start with a tetrahedron. Attach another tetrahedron along a triangle. Continue attaching tetrahedron to triangles.

37  -realizability  -tree: Start with a tetrahedron. Attach another tetrahedron along a triangle. Continue attaching tetrahedra along triangles.

38  -realizability  -tree: Start with a tetrahedron. Attach another tetrahedron along a triangle. Continue attaching tetrahedron to triangles.

39  -realizability  -trees are  -realizable.

40  -realizability Partial  -tree: Subgraph of a  -tree Partial 3-trees are 3-realizable.

41  -realizability Partial  -tree: Subgraph of a  -tree Partial 3-trees are 3-realizable.

42  -realizability Partial 3-tree: Subgraph of a  -tree Another example:

43  -realizability Partial 3-tree: Subgraph of a  -tree Another example:

44  -realizability   

45    Not  -realizable Not  -realizable Not  -realizable

46  -realizability Are the following all equal? Partial  -trees Not containing    -realizability

47 Are the following all equal? Partial  -trees Not containing    -realizability Answer: No, none of the three are equal.

48  -realizability None of the reverse directions are true. Partial  -trees  -realizability Does not contain    

49 From Graph Theory: The following graphs are the “minimal” graphs that are not partial  -trees.  octahedron     

50 Which of these graphs is  -realizable?  octahedron     

51 Which of these graphs is  -realizable?  octahedron      NO Yes YES

52 Conclusion AllowedForbidden  -realizableTrees  -realizablePartial  -trees  -realizable Partial  -trees

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