1 / 6

Graphs and Trees

Graphs and Trees. This handout: Total degree of a graph Applications of Graphs. Graph properties. Definition : The total degree of a graph is the sum of the degrees of all its nodes. Theorem: If G is any graph, then the total degree of G equals twice the number of edges of G :

ktidwell
Download Presentation

Graphs and Trees

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Graphs and Trees • This handout: • Total degree of a graph • Applications of Graphs

  2. Graph properties • Definition: The total degree of a graph is the sum of the degrees of all its nodes. • Theorem: If G is any graph, then the total degree of G equals twice the number of edges of G: the total degree of G = 2 (the number of edges of G) • Corollary 1: The total degree of a graph is even. • Corollary 2: In any graph there are an even number of vertices of odd degree. • Application to an Acquaintance Graph: Is it possible in a group of five people for each to be friends with exactly three others?

  3. Terminology of Graph: Paths • A path between two nodes is a sequence of distinct nodes and edges connecting these nodes. Example: • Two nodes are calledconnected if there is a path between them. • Fact: For any two nodes a and b of a graph, there is an efficient way to determine whether a and b are connected or not. a b

  4. An application of graphs in solving a puzzle • From an initial position on the left bank of a river, a ferryman wants to transport a wolf, a goat, and a cabbage to the right bank. Ferryman’s boat is only big enough to transport one object at a time, other than himself. For obvious reasons, • the wolf cannot be left alone with the goat; • the goat cannot be left alone with the cabbage. • How should the ferryman proceed?

  5. An application of graphs in solving a puzzle To solve the puzzle, create the following graph: • Create a node for each allowable arrangement. E.g., ( fg | wc ) is an allowable arrangement since the ferryman and the goat are on the left bank, and the wolf and the cabbage are on the right bank. • Create an edge between two nodes if it is possible to go from the arrangement of one node to the arrangement of the other node by a single ferry trip. E.g., there is an arc between nodes ( fgw | c ) and ( w | fgc ) because the transition from the first node to the second node can be realized by a single trip of the ferryman with the goat from the left bank to the right bank.

  6. An application of graphs in solving a puzzle fwgc | fwg | c fwc | g fgc | w fg | wc The resulting graph is: To transport everything from the left bank to the right bank, we need to find a path from node ( fwgc | ) to node ( | fwgc ) in the graph. There are two this kind of paths. One of them: (fwgc | )  (wc | fg)  (fwc | g)  (w | fgc)  (fwg | c)  (g | fwc)  (fg | wc)  ( | fwgc) c | fwg | fwgc wc | fg w | fgc g | fwc

More Related