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Title: DISCRETE COMPUTATIONAL STRUCTURES


1
DISCRETE COMPUTATIONAL STRUCTURES
  • CSE 2353
  • Fall 2005

2
CSE 2353 OUTLINE
  1. Sets
  2. Logic
  3. Proof Techniques
  4. Integers and Induction
  5. Relations and Posets
  6. Functions
  7. Counting Principles
  8. Boolean Algebra

3
Learning Objectives
  • Learn about relations and their basic properties
  • Explore equivalence relations
  • Become aware of closures
  • Learn about posets
  • Explore how relations are used in the design of
    relational databases

4
Relations
  • Relations are a natural way to associate objects
    of various sets

5
Relations
  • R can be described in
  • Roster form
  • Set-builder form

6
Relations
  • Arrow Diagram
  • Write the elements of A in one column
  • Write the elements B in another column
  • Draw an arrow from an element, a, of A to an
    element, b, of B, if (a ,b) ? R
  • Here, A 2,3,5 and B 7,10,12,30 and R
    from A into B is defined as follows For all a ?
    A and b ? B, a R b if and only if a divides b
  • The symbol ? (called an arrow) represents the
    relation R

7
Relations
8
Relations
  • Directed Graph
  • Let R be a relation on a finite set A
  • Describe R pictorially as follows
  • For each element of A , draw a small or big dot
    and label the dot by the corresponding element of
    A
  • Draw an arrow from a dot labeled a , to another
    dot labeled, b , if a R b .
  • Resulting pictorial representation of R is called
    the directed graph representation of the relation
    R

9
Relations
10
Relations
  • Directed graph (Digraph) representation of R
  • Each dot is called a vertex
  • If a vertex is labeled, a, then it is also called
    vertex a
  • An arc from a vertex labeled a, to another
    vertex, b is called a directed edge, or directed
    arc from a to b
  • The ordered pair (A , R) a directed graph, or
    digraph, of the relation R, where each element of
    A is a called a vertex of the digraph

11
Relations
  • Directed graph (Digraph) representation of R
    (Continued)
  • For vertices a and b , if a R b, a is adjacent to
    b and b is adjacent from a
  • Because (a, a) ? R, an arc from a to a is drawn
    because (a, b) ? R, an arc is drawn from a to b.
    Similarly, arcs are drawn from b to b, b to c , b
    to a, b to d, and c to d
  • For an element a ? A such that (a, a) ? R, a
    directed edge is drawn from a to a. Such a
    directed edge is called a loop at vertex a

12
Relations
  • Directed graph (Digraph) representation of R
    (Continued)
  • Position of each vertex is not important
  • In the digraph of a relation R, there is a
    directed edge or arc from a vertex a to a vertex
    b if and only if a R b
  • Let A a ,b ,c ,d and let R be the relation
    defined by the following set
  • R (a ,a ), (a ,b ), (b ,b ), (b ,c ), (b
    ,a ), (b ,d ), (c ,d )

13
Relations
  • Domain and Range of the Relation
  • Let R be a relation from a set A into a set B.
    Then R ? A x B. The elements of the relation R
    tell which element of A is R-related to which
    element of B

14
Relations
15
Relations
16
Relations
17
Relations
  • Let A 1, 2, 3, 4 and B p, q, r. Let R
    (1, q), (2, r ), (3, q), (4, p). Then R-1
    (q, 1), (r , 2), (q, 3), (p, 4)
  • To find R-1, just reverse the directions of the
    arrows
  • D(R) 1, 2, 3, 4 Im(R-1), Im(R) p, q, r
    D(R-1)

18
Relations
19
Relations
20
Relations
  • Constructing New Relations from Existing
    Relations

21
Relations
22
Relations
  • Example
  • Consider the relations R and S as given in Figure
    3.7.
  • The composition S ? R is given by Figure 3.8.

23
Relations
24
Relations
25
Relations
26
Relations
27
Relations
28
Relations
29
Relations
Example 3.1.26 continued
30
Relations
31
Relations
  • Example 3.1.27 continued

32
Relations
33
Relations
  • Example 3.1.31 continued

34
Relations
35
Relations
  • Example 3.1.32 continued

36
Relations
37
Relations
38
Relations
  • Consider the relation R (1, 1), (2, 2), (3,
    3), (4, 4), (5, 5), (1, 4), (4, 1), (2, 3), (3,
    2) on the set S 1, 2, 3, 4, 5.
  • The digraph is divided into three distinct
    blocks. From these blocks the subsets 1, 4, 2,
    3, and 5 are formed. These subsets are
    pairwise disjoint, and their union is S.
  • A partition of a nonempty set S is a division of
    S into nonintersecting nonempty subsets.

39
Relations
40
Relations
  • Example Let A denote the set of the lowercase
    English alphabet. Let B be the set of lowercase
    consonants and C be the set of lowercase vowels.
    Then B and C are nonempty, B n C ?, and A B ?
    C. Thus, B, C is a partition of A.
  • Let A be a set and let A1, A2, A3, A4, A5 be a
    partition of A. Corresponding to this partition,
    a Venn diagram, can be drawn, Figure 3.13

41
Relations
42
Relations
43
Relations
44
Relations
45
Relations
46
Relations
  • Let A a, b, c , d, e , f , g , h, i, j . Let
    R be a relation on A such that the digraph of R
    is as shown in Figure 3.14.
  • Then a, b, c , d, e , f , c , g is a directed
    walk in R as a R b,b R c,c R d,d R e, e R f , f R
    c, c R g. Similarly, a, b, c , g is also a
    directed walk in R. In the walk a, b, c , d, e ,
    f , c , g , the internal vertices are b, c , d, e
    , f , and c , which are not distinct as c
    repeats.
  • this walk is not a path. In the walk a, b, c , g
    , the internal vertices are b and c , which are
    distinct. Therefore, the walk a, b, c, g is a
    path.

47
Relations
48
Partially Ordered Sets
49
Partially Ordered Sets
50
Partially Ordered Sets
51
Partially Ordered Sets
52
Partially Ordered Sets
53
Partially Ordered Sets
54
Partially Ordered Sets
55
Partially Ordered Sets
  • Digraphs of Posets
  • Because any partial order is also a relation, a
    digraph representation of partial order may be
    given.
  • Example On the set S a, b, c, consider the
    relation R (a, a),
    (b, b), (c , c ), (a, b).
  • From the directed graph it follows that the given
    relation is reflexive and transitive.
  • This relation is also antisymmetric because there
    is a directed edge from a to b, but there is no
    directed edge from b to a. Again, in the graph
    there are two distinct vertices a and c such that
    there are no directed edges from a to c and from
    c to a.

56
Partially Ordered Sets
  • Digraphs of Posets
  • Let S 1, 2, 3, 4, 6, 12. Consider the
    divisibility relation on S, which is a partial
    order
  • A digraph of this poset is as shown in Figure 3.20

57
Partially Ordered Sets
58
Partially Ordered Sets
  • Closed Path
  • On the set S a, b, c consider the relation
    R (a, a), (b, b), (c , c ),
    (a, b), (b, c ), (c , a)
  • The digraph of this relation is given in Figure
    3.21
  • In this digraph, a, b, c , a form a closed path.
    Hence, the given relation is not a partial order
    relation

59
Partially Ordered Sets
60
Partially Ordered Sets
  • Hasse Diagram
  • Let S 1, 2, 3. Then P(S) ?, 1, 2, 3,
    1, 2, 2, 3, 1, 3, S
  • Now (P(S),) is a poset, where denotes the set
    inclusion relation. The poset diagram of (P(S),)
    is shown in Figure 3.22

61
Partially Ordered Sets
62
Partially Ordered Sets
  • Hasse Diagram
  • Let S 1, 2, 3. Then P(S) ?, 1, 2, 3,
    1, 2, 2, 3, 1, 3, S
  • (P(S),) is a poset, where denotes the set
    inclusion relation
  • Draw the digraph of this inclusion relation (see
    Figure 3.23). Place the vertex A above vertex B
    if B ? A. Now follow steps (2), (3), and (4)

63
Partially Ordered Sets
64
Partially Ordered Sets
  • Hasse Diagram
  • Consider the poset (S,), where S 2, 4, 5, 10,
    15, 20 and the partial order is the
    divisibility relation
  • In this poset, there is no element b ? S such
    that b ? 5 and b divides 5. (That is, 5 is not
    divisible by any other element of S except 5).
    Hence, 5 is a minimal element. Similarly, 2 is a
    minimal element

65
Partially Ordered Sets
  • Hasse Diagram
  • 10 is not a minimal element because 2 ? S and 2
    divides 10. That is, there exists an element b ?
    S such that b lt 10. Similarly, 4, 15, and 20 are
    not minimal elements
  • 2 and 5 are the only minimal elements of this
    poset. Notice that 2 does not divide 5.
    Therefore, it is not true that 2 b, for all b ?
    S, and so 2 is not a least element in (S,).
    Similarly, 5 is not a least element. This poset
    has no least element

66
Partially Ordered Sets
Figure 3.24
  • Hasse Diagram
  • There is no element b ? S such that b ?15, b gt
    15, and 15 divides b. That is, there is no
    element b ? S such that 15 lt b. Thus, 15 is a
    maximal element. Similarly, 20 is a maximal
    element.
  • 10 is not a maximal element because 20 ? S and 10
    divides 20. That is, there exists an element b ?
    S such that 10 lt b. Similarly, 4 is not a maximal
    element.

67
Partially Ordered Sets
Figure 3.24
  • Hasse Diagram
  • 20 and 15 are the only maximal elements of this
    poset
  • 10 does not divide 15, hence it is not true that
    b 15, for all b ? S, and so 15 is not a
    greatest element in (S,)
  • This poset has no greatest element

68
Partially Ordered Sets
69
Partially Ordered Sets
70
Partially Ordered Sets
71
Partially Ordered Sets
72
Partially Ordered Sets
73
Partially Ordered Sets
74
Partially Ordered Sets
75
Partially Ordered Sets
76
Partially Ordered Sets
  • Non-distributive Lattice
  • Because a ? (b ? c ) a ? 1 a 0 0 ? 0
    (a ? b) ? (a ? c ), this is not a distributive
    lattice

77
Partially Ordered Sets
78
Partially Ordered Sets
  • Complement
  • Let D30 denote the set of all positive divisors
    of 30. Then D30 1, 2, 3, 5, 6, 10, 15, 30.
  • (D30,) is a poset where a b if and only if a
    divides b ( is the divisibility relation)
  • D30,) is a poset where a b if and only if a
    divides b ( is the divisibility relation).
    Because 1 divides all elements of D30, it follows
    that 1 m, for all m ? D30. Therefore, 1 is the
    least element of this poset.

79
Partially Ordered Sets
  • Complement
  • Let a, b ? D30. Let d gcda, b and m lcma,
    b. Now d a and d b. Hence, d a and d b.
  • This shows that d is a lower bound of a, b. Let
    c ? D30 and c a, c b.
  • This shows that d is a lower bound of a, b. Let
    c ? D30 and c a, c b. Then, c a and c b
    and because d gcda, b, it follows that c d,
    so c d. Thus, d glba, b.

80
Partially Ordered Sets
  • Complement
  • Because all the positive divisors of a, b are
    also divisors of 30, d ? D30, so d a ? b
  • It can be shown that m ? D30 and m a ? b
  • Hence, (D30,) is a lattice with the least
    element integer 1 and the greatest element 30

81
Partially Ordered Sets
  • Complement
  • For any element a ? D30, (30/a) ? D30
  • Using the properties of gcd and lcm, it can be
    shown that a ? (30/a) 1 and a ? (30/a) 30
  • 10 ? (30/10) gcd10, 3 1 and 10 ? (30/10)
    lcm10, 3 30
  • Hence, 3 is a complement of 10 in this lattice

82
Partially Ordered Sets
83
Application Relational Database
  • A database is a shared and integrated computer
    structure that stores
  • End-user data i.e., raw facts that are of
    interest to the end user
  • Metadata, i.e., data about data through which
    data are integrated
  • A database can be thought of as a well-organized
    electronic file cabinet whose contents are
    managed by software known as a database
    management system that is, a collection of
    programs to manage the data and control the
    accessibility of the data

84
Application Relational Database
  • In a relational database system, tables are
    considered as relations
  • A table is an n-ary relation, where n is the
    number of columns in the tables
  • The headings of the columns of a table are called
    attributes, or fields, and each row is called a
    record
  • The domain of a field is the set of all
    (possible) elements in that column

85
Application Relational Database
  • Each entry in the ID column uniquely identifies
    the row containing that ID
  • Such a field is called a primary key
  • Sometimes, a primary key may consist of more than
    one field

86
Application Relational Database
  • Structured Query Language (SQL)
  • Information from a database is retrieved via a
    query, which is a request to the database for
    some information
  • A relational database management system provides
    a standard language, called structured query
    language (SQL)
  • A relational database management system provides
    a standard language, called structured query
    language (SQL)

87
Application Relational Database
  • Structured Query Language (SQL)
  • An SQL contains commands to create tables, insert
    data into tables, update tables, delete tables,
    etc.
  • Once the tables are created, commands can be used
    to manipulate data into those tables.
  • The most commonly used command for this purpose
    is the select command. The select command allows
    the user to do the following
  • Specify what information is to be retrieved and
    from which tables.
  • Specify conditions to retrieve the data in a
    specific form.
  • Specify how the retrieved data are to be
    displayed.

88
CSE 2353 OUTLINE
  1. Sets
  2. Logic
  3. Proof Techniques
  4. Integers and Induction
  5. Relations and Posets
  6. Functions
  7. Counting Principles
  8. Boolean Algebra

89
Learning Objectives
  • Learn about functions
  • Explore various properties of functions
  • Learn about sequences and strings
  • Become familiar with the representation of
    strings in computer memory
  • Learn about binary operations

90
Functions
91
Functions
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Functions
  • Every function is a relation
  • Therefore, functions on finite sets can be
    described by arrow diagrams. In the case of
    functions, the arrow diagram may be drawn
    slightly differently.
  • If f A ? B is a function from a finite set A
    into a finite set B, then in the arrow diagram,
    the elements of A are enclosed in ellipses rather
    than individual boxes.

98
Functions
  • To determine from its arrow diagram whether a
    relation f from a set A into a set B is a
    function, two things are checked
  • Check to see if there is an arrow from each
    element of A to an element of B
  • This would ensure that the domain of f is the set
    A, i.e., D(f) A
  • Check to see that there is only one arrow from
    each element of A to an element of B
  • This would ensure that f is well defined

99
Functions
  • Let A 1,2,3,4 and B a, b, c , d be sets
  • The arrow diagram in Figure 5.6 represents the
    relation f from A into B
  • Every element of A has some image in B
  • An element of A is related to only one element of
    B i.e., for each a ? A there exists a unique
    element b ? B such that f (a) b

100
Functions
  • Therefore, f is a function from A into B
  • The image of f is the set Im(f) a, b, d
  • There is an arrow originating from each element
    of A to an element of B
  • D(f) A
  • There is only one arrow from each element of A to
    an element of B
  • f is well defined

101
Functions
  • The arrow diagram in Figure 5.7 represents the
    relation g from A into B
  • Every element of A has some image in B
  • D(g ) A
  • For each a ? A, there exists a unique element b ?
    B such that g(a) b
  • g is a function from A into B

102
Functions
  • The image of g is Im(g) a, b, c , d B
  • There is only one arrow from each element of A to
    an element of B
  • g is well defined

103
Functions
  • Let h be the relation described by the arrow
    diagram in Figure 5.8
  • Every element of A has some image in B i.e.,
    there is an arrow originating from each element
    of A to an element of B. Therefore,
  • D(h) A
  • However,element 1 has two images in B i.e.,
    there are two arrows originating from 1, one
    going to a and another going to b, so h is not
    well defined. Thus, the first condition of
    Definition 5.1.1 is satisfied,but the second one
    is not.
  • Therefore, h is not a function

104
Functions
  • The arrow diagram in Figure 5.9 represents a
    relation from A into B
  • Not every element of A has an image in B. For
    example, the element 4 has no image in B. In
    other words, there is no arrow originating from 4
  • Therefore, 4 ? D(k), so D(k) ? A
  • This implies that k is not a function from A into
    B

105
Functions
  • Numeric Functions
  • If the domain and the range of a function are
    numbers, then the function is typically defined
    by means of an algebraic formula
  • Such functions are called numeric functions
  • Numeric functions can also be defined in such a
    way so that different expressions are used to
    find the image of an element

106
Functions
107
Functions
108
Functions
Example 5.1.16
  • Let A 1,2,3,4 and B a, b, c , d. Let f
    A ? B be a function such that the arrow diagram
    of f is as shown in Figure 5.10
  • The arrows from a distinct element of A go to a
    distinct element of B. That is, every element of
    B has at most one arrow coming to it.
  • If a1, a2 ? A and a1 a2, then f(a1) f(a2).
    Hence, f is one-one.
  • Each element of B has an arrow coming to it. That
    is, each element of B has a preimage.
  • Im(f) B. Hence, f is onto B. It also follows
    that f is a one-to-one correspondence.

109
Functions
Example 5.1.18
  • Let A 1,2,3,4 and B a, b,
    c , d, e
  • f 1 ? a, 2 ? a, 3 ? a, 4 ? a
  • For this function the images of distinct elements
    of the domain are not distinct. For example 1 ?
    2, but f(1) a f(2) .
  • Im(f) a ? B. Hence, f is neither one-one nor
    onto B.

110
Functions
  • Let A 1,2,3,4 and B a, b,
    c , d, e
  • f 1 ? a, 2 ? b, 3 ? d, 4 ? e
  • For this function, the images of distinct
    elements of the domain are distinct. Thus, f is
    one-one. In this function, for the element c of
    B, the codomain, there is no element x in the
    domain such that f(x) c i.e., c has no
    preimage. Hence, f is not onto B.

111
Functions
112
Functions
  • Let A 1,2,3,4, B a, b, c , d, e,and C
    7,8,9. Consider the functions f A ? B, g B
    ? C as defined by the arrow diagrams in Figure
    5.14.
  • The arrow diagram in Figure 5.15 describes the
    function h g ? f A ? C.

113
Functions
114
Functions
115
Special Functions and Cardinality of a Set
116
Special Functions and Cardinality of a Set
117
Special Functions and Cardinality of a Set
118
Special Functions and Cardinality of a Set
119
Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
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Special Functions and Cardinality of a Set
133
Sequences and Strings
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  • m is the lower limit of the sum, n the upper
    limit of the sum, and ai the general term of
    the sum

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  • m is the lower limit of the sum, n the upper
    limit of the sum, and ai the general term of the
    product.

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Sequences and Strings
  • Representing Strings into Computer Memory
  • A convenient way of storing a string into
    computer memory is to use an array.
  • Programming languages such as C and Java
    provide a data type to manipulate strings.
  • This data type includes algorithms to implement
    operations such as concatenation, finding the
    length of a string,determining whether a string
    is a substring in another string, and finding a
    substring into another string.

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Binary Operations
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Binary Operations
  • Let A be an alphabet. Let A be the set of all
    nonempty strings on the alphabet A. If u, v ?
    A,i.e., u and v are two nonempty strings on
    A,then the concatenation of u and v, uv ? A.
    Thus, the concatenation of strings is a binary
    operation on A. Also, by Theorem 5.3.23(ii), the
    concatenation operation is associative.
  • Hence, A becomes a semigroup with respect to the
    concatenation operation.
  • Called a free semigroup generated by A.

154
Binary Operations
  • Let A denote the set of all words including
    empty word ?. By Theorem 5.3.23(i), for all s ?
    A, ?s s s?. Thus, A becomes a
    monoid with identity 1 ?.
  • This monoid is called a free monoid generated by
    A.
  • If A contains more than one element, then A is a
    noncommutative monoid.
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