csnb 143 discrete mathematical structures
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CSNB 143 Discrete Mathematical Structures. Chapter 2 - Sets. Sets. OBJECTIVES Student should be able to identify sets and its important components. Students should be able to apply set in daily lives. Students should know how to use set in its operations. What, which, where, when. - PowerPoint PPT PresentationTRANSCRIPT
Chapter 2 - Sets
CSNB 143 Discrete Mathematical
Structures
SetsOBJECTIVESStudent should be able to identify sets and
its important components.Students should be able to apply set in
daily lives.Students should know how to use set in its
operations.
What, which, where, when1. Basics of set (Clear / Not
Clear )2.Terms used in setEqual sets (Clear / Not Clear)Empty (Clear / Not Clear)
Disjoint / Joint (Clear / Not Clear)Finite / Infinite (Clear / Not Clear)Cardinality (Clear / Not Clear)Subset (Clear / Not Clear)Power set (Clear / Not Clear)
3. Operations on setsUnion (Clear / Not Clear)Intersection (Clear / Not
Clear)Complement (Clear / Not Clear)Symmetric Difference (Clear / Not Clear)
4. Venn DiagramInformation Searching (Clear / Not
Clear)
SETA collection of data or objects.Each entity is called element or member,
defined by symbol .Order is not important.Repeated element is not important. One way to describe set is to listing all the
elements, in curly bracket.
Ex 1:A = {1, 2, 3, 4, 5} B = {2, 3, 1, 4,
5)C = {1, 2, 1, 3, 4, 5}Thus we said, sets A and B are equal. A =
B 1 A, 2 A, but 7 A
How about A and C? How about B and C?
Ex 2:P = {p, q, r} Q = {p, q, r, s}R = {q, r, s}
So, p P, q P, r P,
q Q, r R
Other way to describe set:A = {x| 1 x 5}A = {x| x is an integer from 1 to 5, both
included}A = {x| x + 1 ; 0 x < 5}
If the set has no element, it is called the empty set, denoted by {} or .
Let D = {6, 7, 8} So, A and D are called Disjoint Sets. Why?
What is the example of joined set?
A set A is called finite if it has n distinct elements, where n N (nonnegative number).
Ex 3: A = {x| 1 x 5}
The number of its elements, n is called the cardinality of A, denoted by |A|= 5.
A set that is not finite is called infinite. Ex 4: A = {x| x ≥ 1}
SubsetIf every element of A is also an element of B,
that is, if whatever x A then x B, we say that A is a subset of B or that A is contained in B, written as A B (some books use symbol ).
Sets that all its elements are part or overall of other set.
Ex 5:A = {1, 2, 3, 4, 5}B = {1, 3, 5}C = {1, 2, 4, 6}, Thus,B A, but C AB A but A B
Consider Ex 1. A = {1, 2, 3, 4, 5} B = {2, 3, 1, 4,
5)C = {1, 2, 1, 3, 4, 5}
Is A B? Is B A? Is A C? Is B C?
Power SetIf A is a set, then the set of all subsets of A
is called the power set of A, denoted by P (A).
A set that contains all its subset as its element. Ex 6: A = {1, 2}
P (A) = {{1}, {2}, {1, 2}, } |P (A)| = 4
Operation on setsUnion Let say A and B are sets. Their union is a set
consisting of all elements that belong to A OR B and denoted by A B.
A B = {x|x A or x B}
IntersectionsLet say A and B are sets. Their intersection is
a set consisting of all elements that belong to both A AND B and denoted by A B.
A B = {x|x A and x B}
Operation on setsComplementLet say set U is a universal set. U – A is called
the complement of A, denoted by A’ (some book use A)A’ = { x|x A}
If A and B are two sets, the complement of B with respect to A is a set that contain all elements that belong to A but not to B, denoted by A – B. Try Ex 5. Find A – B, A – C, C – A, C – B.
Symmetric DifferenceLet say A and B are two sets. Their
symmetric difference is a set that contain all elements that belong to A OR B but not to both A and B, denoted by A B.
A B = {x|(x A and x B) or (x B and x A)}Try Ex 2. Find P R.
Venn DiagramExercise : A BA BA B CA B CA – B B – AA B
TheoremsCommutativeA B = B A A B = B
AAssociativeA (B C) = (A B) CA (B C) = (A B) CDistributiveA (B C) = (A B) (A C)A (B C) = (A B) (A C)IdempotentA A = A A A = A
ComplementA’’ = A A A’ = UA A’ = ’ = U U’ = (A B)’ = A’ B’(A B)’ = A’ B’Universal SetA U = U A U = AEmpty SetA = A A =
2 disjoint sets|A B| = |A| + |B|2 joint sets|A B| = |A| + |B| - |A B|3 disjoint sets|A B C| = |A| + |B| + |C|3 joint sets|A B C| = |A| + |B| +|C| - |A B| - |A
C| - |B C| + |A B C|