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CMSC 203 / 0201 Fall 2002

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CMSC 203 / 0201 Fall 2002 Week #13 18/20/22 November 2002 Prof. Marie desJardins MON 11/18 EQUIVALENCE RELATIONS (6.5) Concepts/Vocabulary Equivalence relation ... – PowerPoint PPT presentation

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Title: CMSC 203 / 0201 Fall 2002


1
CMSC 203 / 0201Fall 2002
  • Week 13 18/20/22 November 2002
  • Prof. Marie desJardins

2
MON 11/18 EQUIVALENCE RELATIONS (6.5)
3
Concepts/Vocabulary
  • Equivalence relation Relation that is reflexive,
    symmetric, and transitive (e.g., people born on
    the same day, strings that are the same length)
  • Equivalence class Set of all elements
    equivalent to a given element x (i.e., x
    y (x,y) ? R).
  • Partition disjoint nonempty subsets of S that
    have S as their union
  • The equivalence classes of a set form a partition
    of the set

4
Examples
  • Exercise 6.5.4 Define three equivalence
    relations on the set of students in this class.
  • Exercise 6.5.27-28 A partition P1 is a
    refinement of a partition P2 if every set in P1
    is a subset of some set in P2.
  • (27) Show that the partition formed from the
    congruence classes modulo 6 is a refinement of
    the partition formed from the congruence classes
    modulo 3.
  • (28) Suppose that R1 and R2 are equivalence
    relations on a set A. Let P1 and P2 be the
    partitions that correspond to R1 and R2,
    respectively. Show that R1? R2 iff P1 is a
    refinement of P2.

5
Examples II
  • Exercise 6.5.33 Consider the set of all
    colorings of the 2x2 chessboard where each of the
    four squares is colored either red or blue.
    Define the relation R on this set such that (C1,
    C2) is in R iff C2 can be obtained from C1 either
    by rotating the chessboard or by rotating it and
    then reflecting it.
  • (a) Show that R is an equivalence relation.
  • (b) What are the equivalence classes of R?

6
WED 11/20GRAPHS (7.1-7.2)
7
Concepts / Vocabulary 7.1
  • Simple graph G (V, E) vertices V, edges E
  • A multigraph can have multiple edges between the
    same pair of vertices
  • A pseudograph can also have loops (from a vertex
    to itself)
  • In an undirected graph, the edges are unordered
    pairs
  • In a directed graph, the edges are ordered pairs
  • You should be familiar with all of these types of
    graphs, but for problem solving, you will only be
    using simple directed and undirected graphs

8
Concepts/Vocabulary 6.2
  • Adjacent, neighbors, connected, endpoints,
    incident
  • Degree of a vertex (number of edges), in-degree,
    out-degree isolated, pendant vertices
  • Complete graph Kn
  • Cycle Cn (can also say that a graph contains a
    cycle)
  • Bipartite graphs, complete bipartite graphs Km, n
  • Wheels, n-Cubes (dont need to know these)
  • Subgraph, union

9
Examples
  • Exercise 7.1.2 What kind of graph can be used to
    model a highway system between major cities where
  • (a) there is an edge between the vertices
    representing cities if there is an interstate
    highway between them?
  • (b) there is an edge between the vertices
    representing cities for each interstate highway
    between them?
  • (c) there is an edge between the vertices
    representing cities for each interstate highway
    between them, and there is a loop at the vertex
    representing a city if there is an interstate
    highway that circles this city?

10
Examples II
  • Exercise 7.1.11 The intersection graph of a
    collection of sets A1, A2, , An has a vertex for
    each set, and an edge connecting two vertices if
    the corresponding sets have a nonempty
    intersection. Construct the intersection graph
    for these sets
  • (a) A1 0, 2, 4, 6, 8, A2 0, 1, 2, 3, 4,
    A3 1, 3, 5, 7, 9, A4 5, 6, 7, 8, 9, A5
    0, 1, 8, 9
  • (b) A1 , -4, -3, -2, -1, 0, A2 , -2, -1,
    0, 1, 2, , A3 , -6, -4, -2, 0, 2, 4, 6, ,
    A4 , -5, -3, -1, 1, 3, 5, , A5 , -6,
    -3, 0, 3, 6,

11
Examples III
  • Exercise 7.2.19 How many vertices and how many
    edges do the following graphs have?
  • (a) Kn
  • (b) Cn
  • (d) Km, n
  • Exercise 7.2.20 How many edges does a graph have
    if it has vertices of degree 4, 3, 3, 2, 2?
  • Exercise 7.2.23 How many subgraphs with at least
    one vertex does K3 have?

12
FRI 11/22GRAPH STRUCTURE (7.3-7.5)
13
Concepts/Vocabulary
  • Adjacency list, adjacency matrix, incidence
    matrix
  • Isomorphism, invariant properties
  • Paths, path length, circuits/cycles, simple
    paths/circuits
  • Connected graphs, connected components
  • Strong connectivity, weak connectivity
  • Cut vertices, cut edges
  • Euler circuit, Euler path
  • Hamilton path, Hamilton circuit
  • For this section (7.5), need to know terminology
    but not proofs

14
Examples
  • Exercise 7.3.1/5/26 Represent the given graph
    with an adjacency list, an adjacency matrix, and
    an incidence matrix.

A
B
C
D
15
Examples II
  • Exercise 7.3.34/38/41 Determine whether the
    given pairs of graphs are isomorphic.
  • A simple graph G is called self-complementary if
    G and ?G are isomorphic.
  • Exercise 7.3.50 Show that the following graph is
    self-complementary.

A
B
C
D
16
Examples III
  • Exercise 7.3.57(a), 7.3.58(a) Are the simple
    graphs with the given adjacency matrices /
    incidence matrices isomorphic?
  • Exercise 7.4.1 Is the list of vertices a path in
    the graph? Which paths are circuits? What are
    the lengths of those that are paths?
  • Exercise 7.4.15-17 Find all of the cut vertices
    of the given graphs.
  • Exercise 7.5.2 Does the graph have an Euler
    circuit?
  • Exercise 7.5.16 Can you cross all the bridges
    exactly once and reurn to the starting point?
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