Presentation is loading. Please wait.

Presentation is loading. Please wait.

Part B Set Theory What is a set? A set is a collection of objects. Can you give me some examples?

Published byGriffin Wheeler Modified over 9 years ago

Similar presentations

Presentation on theme: "Part B Set Theory What is a set? A set is a collection of objects. Can you give me some examples?"— Presentation transcript:

1 Part B Set Theory What is a set? A set is a collection of objects. Can you give me some examples?

2 Section 6 Concept and Notation of Sets Tabular Form N={1, 2, 3, 4, … } Z={0, -1, 1, 2, -2, … } Q=? R=? C=? S={1, 2, 3, 4} T={fish, fly, a, 4}  ={ } ( is called the empty set) Set-Builder Form N={n: n is a natural number} Z={m: m is an integer} Q={p/q: p and q are integers and q  0} R={r: r is a real number} C={a+bi: a and b are real and i 2 =-1}

3 Elements of a Set 4  N means that: 4 is an element of N; 4 is a member of N; 4 belongs to N; 4 is contained in N; N contains 4.

4 Section 7 Subsets Definition 7.1 Let A and B be two sets. A is a subset of B iff every element of A is an element of B. Symbolically, A  B iff (  x)(x  A  x  B) Can you give me some examples? N  Z  Q  R  C

5 Important subsets of R Let a, b be two real numbers with a  b (a, b) = { x: x  R and a < x < b} Open interval [a, b] = { x: x  R and a  x  b} Closed interval (a, b] = { x: x  R and a < x  b} Half-open and half- closed interval [a, b) = { x: x  R and a  x < b} Half-closed and half- open interval (a, +  ) = {x : x  R and x > a} [a, +  ) = {x : x  R and x  a} (- , a) = {x : x  R and x < a} (- , a] = {x : x  R and x  a} (- , +  ) = R

6 Important Facts on Subsets A  A  A A  B and B  C  A  C Can you give proofs to them?

7 Equal Sets and Proper Subsets A = B iff A  B and B  A iff (  x)(x  A  x  B) Let A, B be two sets. A is a proper subsets of B, denoted by A B

8 Section 8 Intersection and Union of Sets Definition 8.1 Let A and B be sets.The intersection of A and B is the set A  B ={x: x  A and x  B}. A B A  B

9 Union of sets Definition 8.2 Let A and B be sets.The union of A and B is the set A  B ={x: x  A or x  B}. A B A  B

10 B\A Section 9 Complements Definition 9.1,2 Let A and B be sets. The complement of A in B is defined as the set B\A={x: x  B and x  A } B A

11 Example 9.2 Given that E={1, 2, 3, 4, 5, 6, 7, 8, 9, 10}, A = {1, 2, 3, 4, 5}, B = { 4, 5, 6, 7} and C = { 8, 9, 10} A  B = A  B = C  B = A\B = B\A= A  B  C = {1, 2, 3, 4, 5, 6, 7} {4, 5}  (B and C are disjoint) {1, 2, 3} {6, 7} E Ex.2.3 1-9

12 Exercise (1, 5)  (3, 8) (1, 5)  (3, 8) (-10, 1]  [1, 4] (-10, 1]  [1, 4] (- , 3)  (-1, +  ) (- , 3)  (7, 100) R\Q R\(1, 5) (1,5 )\(3, 7) (3, 8)\[2, 9] (5, +  )\(1, 3] =(3, 5) =(1. 8) ={1} =(-10, 4] =R=R == =Set of all irrational numbers =(- , 1]  [5, +  ) =(1, 3] =  =(5, +  )

13 Section 10 Functions Definition f: A  B is a function from a set A to a set B iff f assigns every object in A a unique image in B. 12341234 abcdeabcde f A B Domain = A Range = B Codomain={a, b, c}

14 Group discussion Refer to Ex.2.4 Q.5, discuss on which are graphs of functions and state their domains, ranges and codomains. Determine which of the following are functions: 1.f: R  R is defined by f(x) = logx 2.g:R  R is defined by g(x)=  x 3.h:N  N is defined by h(x) = x/2 4.p:R  R is defined by p(x) = cosx 5.q: [-2, 3]  R is defined by q(x) =  (x 2 -2x – 3) Ex.2.4, Q.6

15 State the differences between the following functions f: Z  Z defined by f(x) = x 2 g:N  N defined by g(x)=x 2

16 Injective functions A function f: A  B is called an injection (injective function or one-to-one function) iff it doesn ’ t assign two distinct objects to the same image. Symbolically, (  x 1, x 2 )(x 1  x 2  f(x 1 )  f(x 2 ))  (  x 1, x 2 ) (f(x 1 ) = f(x 2 )  x 1 = x 2 )

17 Examples 1. Is the function f: N  N defined by f(x) = 2x injective? How to prove it? Proof: f(x 1 ) = f(x 2 )  2x 1 = 2x 2  x 1 = x 2  f is injective

18 2. Let a, b, c, d be real numbers and c  0. f: R\{-d/c}  R be a function defined by f(x)=(ax+b)/(cx+d). Show that if ad-bc  0, then f is injective. Proof: Let x 1, x 2  R\{-d/c}, and suppose that f(x 1 )=f(x 2 ), then (ax 1 +b)/(cx 1 +d)= (ax 2 +b)/(cx 2 +d)  (ad-bc)(x 1 -x 2 ) = 0  x 1 =x 2 (Since ad-bc  0)  f is injective.

19 3. Let f:C  C be a function satisfying f(az 1 +bz 2 )=af(z 1 )+bf(z 2 ) for any real numbers a and b and any z 1, z 2  C. (a)Show that f(0) = 0 (b)f is injective iff when f(z)=0 we have z=0. Proof: f(0)= f(0z 1 +0z 2 ) = 0f(z 1 )+0f(z 2 ) = 0 Proof: (  ) when f(z)=0, then f(0)=0=f(z)  z=0 since f is injective. (  ) If f(z 1 ) = f(z 2 ), then f(z 1 ) - f(z 2 )= 0  f(z 1 -z 2 ) = 0  z 1 -z 2 = 0  z 1 = z 2. Thus f is injective.

20 Which of the following functions are injective? Give proofs. 1. g(x) = x 2 + 1 2. f(x) = x/(1-x) 3. h(x) = (x + 1)/(x – 1) 4. k(x) = x 3 + 9x 2 +27x + 4 Ex. 2.4 Q.10

21 State the difference between the following functions h: Z  Z defined by h(x) = x + 1 and k: N  N defined by k(x) = x + 1

22 Surjective Functions A function f: A  B is called an surjection (surjective function or onto function) iff every element of B is an image of an element in A. Symbolically, (  b  B)(  a  A)(f(a) = b)

23 Examples Prove that f: R  R defined by f(x) = 3x + 2 is surjective. Proof: For any real number y, there exists a real number x = (y – 2)/3 such that f(x) = 3((y – 2)/3) + 2 = y Therefore f is surjective. ???? 5y5y f Group Discussion on Ex.2.4 Q.10 (  b  B)(  a  A)(f(a) = b)

24 2. Show that the function f: R  (0, 1] defined by f(x) = 1/(x 2 +1) is surjective. Proof: For any y  (0, 1], then there exists x=  ((1-y)/y)  R such that f(x)=1/((1-y)/y+1)=y. Therefore f is surjective. Ex.2.4 Q.10

25 Bijective Functions and their inverse functions Let f: A  B be a funcition. f is called a bijective function(or bijection) iff f is both injective and surjective. The inverse function f -1 : B  A of the function f is defined as f -1 = { (b, a) : (a, b)  f } Ex.2.4 Q.10

26 Example 1 12341234 a bcda bcd f AB 12341234 a bcda bcd f -1 B A

27 Example 2 Let f: R  R be a function defined by f(x) = 2x – 1. Then f is bijective. Since y = 2x – 1  x = (y + 1)/2 f -1 (x) = (x + 1)/2

28 Example 3 Let f: R +  R be a function defined by f(x) = log 10 x Then f is bijective. Since y = log 10 x  x = 10 y f -1 (x) = 10 x

29 Example 4 Let f: [0, +  )  [0, +  ) be a function defined by f(x) = x 2 Then f is bijective. Since y = x 2  x =  +  y, f -1 (x) = +  x

30 Graphs of a function & its inverse y=f(x) y=f -1 (x) x y y=x

31 Composite functions of f(x)and f -1 (x) f(f -1 (x))= f -1 (f (x))= X X Ex.2.4 Q.11 Ex.2.5 1-3 Ex.2.4 Q.11 Ex.2.5 1-3

Download ppt "Part B Set Theory What is a set? A set is a collection of objects. Can you give me some examples?"

Similar presentations

1.6 Functions. Chapter 1, section 6 Functions notation: f: A B x in A, y in B, f(x) = y. concepts: –domain of f, –codomain of f, –range of f, –f maps.

1.6 Functions. Chapter 1, section 6 Functions notation: f: A B x in A, y in B, f(x) = y. concepts: –domain of f, –codomain of f, –range of f, –f maps.
More Functions and Sets

More Functions and Sets
Functions Section 2.3 of Rosen Fall 2008

Functions Section 2.3 of Rosen Fall 2008
Lecture 3 Set Operations & Set Functions. Recap Set: unordered collection of objects Equal sets have the same elements Subset: elements in A are also.

Lecture 3 Set Operations & Set Functions. Recap Set: unordered collection of objects Equal sets have the same elements Subset: elements in A are also.
modified from UCI ICS/Math 6D, Fall 2007 2-Sets+Functions-1 Sets “Set”=Unordered collection of Objects “Set Elements”

modified from UCI ICS/Math 6D, Fall Sets+Functions-1 Sets “Set”=Unordered collection of Objects “Set Elements”
Functions Goals Introduce the concept of function Introduce injective, surjective, & bijective functions.

Functions Goals Introduce the concept of function Introduce injective, surjective, & bijective functions.
1 Section 1.8 Functions. 2 Loose Definition Mapping of each element of one set onto some element of another set –each element of 1st set must map to something,

1 Section 1.8 Functions. 2 Loose Definition Mapping of each element of one set onto some element of another set –each element of 1st set must map to something,
1 Set Theory. Notation S={a, b, c} refers to the set whose elements are a, b and c. a  S means “a is an element of set S”. d  S means “d is not an element.

1 Set Theory. Notation S={a, b, c} refers to the set whose elements are a, b and c. a  S means “a is an element of set S”. d  S means “d is not an element.
1 Set Theory. Notation S={a, b, c} refers to the set whose elements are a, b and c. a  S means “a is an element of set S”. d  S means “d is not an element.

1 Set Theory. Notation S={a, b, c} refers to the set whose elements are a, b and c. a  S means “a is an element of set S”. d  S means “d is not an element.
CS 2210 (22C:019) Discrete Structures Sets and Functions Spring 2015 Sukumar Ghosh.

CS 2210 (22C:019) Discrete Structures Sets and Functions Spring 2015 Sukumar Ghosh.
Functions.

Functions.
1 CMSC 250 Chapter 7, Functions. 2 CMSC 250 Function terminology l A relationship between elements of two sets such that no element of the first set is.

1 CMSC 250 Chapter 7, Functions. 2 CMSC 250 Function terminology l A relationship between elements of two sets such that no element of the first set is.
Section 1.8: Functions A function is a mapping from one set to another that satisfies certain properties. We will first introduce the notion of a mapping.

Section 1.8: Functions A function is a mapping from one set to another that satisfies certain properties. We will first introduce the notion of a mapping.
Basic Structures: Sets, Functions, Sequences, Sums, and Matrices

Basic Structures: Sets, Functions, Sequences, Sums, and Matrices
Sets Set Operations Functions. 1. Sets 1.1 Introduction and Notation 1.2 Cardinality 1.3 Power Set 1.4 Cartesian Products.

Sets Set Operations Functions. 1. Sets 1.1 Introduction and Notation 1.2 Cardinality 1.3 Power Set 1.4 Cartesian Products.
2.1 Sets 2.2 Set Operations 2.3 Functions ‒Functions ‒ Injections, Surjections and Bijections ‒ Inverse Functions ‒Composition 2.4 Sequences and Summations.

2.1 Sets 2.2 Set Operations 2.3 Functions ‒Functions ‒ Injections, Surjections and Bijections ‒ Inverse Functions ‒Composition 2.4 Sequences and Summations.
Foundations of Discrete Mathematics Chapter 3 By Dr. Dalia M. Gil, Ph.D.

Foundations of Discrete Mathematics Chapter 3 By Dr. Dalia M. Gil, Ph.D.
Functions. Copyright © Peter Cappello2 Definition Let D and C be nonempty sets. A function f from D to C, for each element d  D, assigns exactly 1 element.

Functions. Copyright © Peter Cappello2 Definition Let D and C be nonempty sets. A function f from D to C, for each element d  D, assigns exactly 1 element.
Discrete Mathematics and Its Applications Sixth Edition By Kenneth Rosen Copyright  The McGraw-Hill Companies, Inc. Permission required for reproduction.

Discrete Mathematics and Its Applications Sixth Edition By Kenneth Rosen Copyright  The McGraw-Hill Companies, Inc. Permission required for reproduction.
1 Annoucement n Skills you need: (1) (In Thinking) You think and move by Logic Definitions Mathematical properties (Basic algebra etc.) (2) (In Exploration)

1 Annoucement n Skills you need: (1) (In Thinking) You think and move by Logic Definitions Mathematical properties (Basic algebra etc.) (2) (In Exploration)

Similar presentations

Ads by Google