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Drawing a graph http://mathworld.wolfram.com/GraphEmbedding.html.

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Presentation on theme: "Drawing a graph http://mathworld.wolfram.com/GraphEmbedding.html."— Presentation transcript:

1 Drawing a graph

2 Graph Theory and Complex Networks by Maarten van Steen

3 Graph Theory and Complex Networks by Maarten van Steen

4 What is a planar embedding?
     drp.math.umd.edu/Project-Slides/Characteristics of Planar Graphs.pptx What is a planar embedding? K4

5 Kuratowski’s Theorem (1930)
A graph is planar if and only if it does not contain a subdivision of K5 or K3,3.

6 Kuratowski Subgraphs What is a subdivision? K5 K3,3
What is a subdivision? Kuratowski Subgraphs

7 For a planar graph |V| - |E| + |F| = 2
Euler characteristic (simple form): = number of vertices – number of edges + number of faces Or in short-hand, = |V| - |E| + |F| where V = set of vertices E = set of edges F = set of faces = set of regions & the notation |X| = the number of elements in the set X. For a planar graph |V| - |E| + |F| = 2

8 Defn: A tree is a connected graph that does not contain a cycle.
A forest is a graph whose components are trees. Lemma 2.1: Any tree with n vertices has n-1 edges. χ = 8 – = χ = 8 – = χ = 8 – 9 + 3= 2

9 = |V| – |E| + |F| = 2 – = 2

10 = |V| – |E| + |F| = 3 – = 2

11 = |V| – |E| + |F| = 4 – = 2

12 = |V| – |E| + |F| = 5 – = 2

13 = |V| – |E| + |F| = 8 – = 2

14 = |V| – |E| + |F| = 8 – = 2 Not a tree.

15 = |V| – |E| + |F| = 8 – = 2 Not a tree.

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