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Chapter 7, Functions

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Title: CMSC 250 Author: Larry Herman Last modified by: Larry Herman Created Date: 10/2/1995 7:58:10 PM Document presentation format: Letter Paper (8.5x11 in) – PowerPoint PPT presentation

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Title: Chapter 7, Functions


1
Chapter 7, Functions
2
Function terminology
  • A relationship between elements of two sets such
    that no element of the first set is related to
    more than one element of the second set
  • Domain the set which contains the values to
    which the function is applied
  • Codomain the set which contains the possible
    values (results) of the function
  • Range (or image) the set of actual values
    produced when applying the function to the values
    of the domain

3
More function terminology
  • f X ? Y
  • f is the function name
  • X is the domain
  • Y is the co-domain
  • x ? X y ? Y f sends x to y
  • f(x) y f of x the value of f at x the
    image of x under f
  • A total function is a relationship between
    elements of the domain and elements of the
    co-domain where each and every element of the
    domain relates to one and only one value in the
    co-domain
  • A partial function does not need to map every
    element of the domain

4
Formal definitions
  • The range of f is y ? Y (?x ? X)f(x) y
  • where X is the domain and Y is the co-domain
  • The inverse image of y ? Y is
  • x ? X f(x) y
  • the set of things in the domain X that map to y
  • Arrow diagrams
  • Determining if something is a function using an
    arrow diagram
  • Equality of functions
  • (? functions f,g with the same domain X and
    codomain Y) f g iff (?x ? X)f(x) g(x)

5
Discrete StructuresCMSC 250Lecture 38
  • April 30, 2008

6
Types of functions
  • FX ? Y is a one-to-one (or injective) function
    iff
  • (?x1,x2 ? X)F(x1) F(x2) ? x1 x2, or
    alternatively
  • (?x1,x2 ? X)x1 ? x2 ? F(x1) ? F(x2)
  • F X ?Y is not a one-to-one function iff
  • (?x1,x2 ? X)(F(x1) F(x2)) (x1 ? x2)
  • F X ? Y is an onto (or surjective) function iff
  • (?y ? Y)(?x ? X)F(x) y
  • F X ? Y is not an onto function iff
  • (?y ? Y)(?x ? X)F(x) ? y

7
Proving functions one-to-one and onto
  • f R ? R f(x) 3x ? 4
  • Prove or give a counterexample that f is
    one-to-one
  • recall the definition (one of two definitions) of
    one-to-one is
  • Prove or give a counterexample that f is onto
  • recall the definition of onto is

8
One-to-one correspondence or bijection
  • F X ? Y is bijective iff F X ? Y is one-to-one
    and onto
  • If F X ? Y is bijective then it has an inverse
    function

9
Proving something is a bijection
  • F Q ? Q F(x) 5x 1/2
  • prove it is one-to-one
  • prove it is onto
  • then it is a bijection
  • so it has an inverse function
  • find F?1

10
The pigeonhole principle
  • ?? ? ?
  • ??? ? ?
  • Basic form
  • A function from one finite set to a smaller
    finite set cannot be one-to-one there must be at
    least two elements in the domain that have the
    same image in the codomain.

11
Examples
  • Using this class as the domain
  • must two people share a birth month?
  • must two people share a birthday?
  • Let A 1,2,3,4,5,6,7,8
  • if I select 5 different integers at random from
    this set, must two of the numbers sum exactly to
    9?
  • if I select 4 integers?
  • There exist two people in New York City who have
    the same number of hairs on their heads.
  • There exist two subsets of 1,,10 with three
    elements which sum to the same value.

12
Discrete StructuresCMSC 250Lecture 39
  • May 2, 2008

13
Another (more useful) form of the pigeonhole
principle
  • The generalized pigeonhole principle
  • For any function f from a finite set X to a
    finite set Y and for any positive integer k, if
    n(X) gt k n(Y), then there is some y ? Y such
    that y is the image of at least k1 distinct
    elements of X.
  • Contrapositive form
  • For any function f from a finite set X to a
    finite set Y and for any positive integer k, if
    for each y ? Y, f1(y) has at most k elements,
    then X has at most k ? n(y) elements.

14
Examples
  • Using the generalized form
  • assume 50 people in the room, how many must share
    the same birth month?
  • n(A)5 n(B)3 F P (A) ? P (B)
  • how many elements of P (A) must map to a single
    element of P (B)?

15
Composition of functions
  • f X ? Y1 and g Y ? Z where Y1 ? Y
  • g ? f X ? Z where (?x ? X)g(f(x)) g ?
    f(x)

16
Composition on finite sets- example
  • Example
  • X 1,2,3, Y1 a,b,c,d, Y a,b,c,d,e,
    Z x,y,z

f(1) c g(a) y g?f(1) g(f(1)) z
f(2) b g(b) y g?f(2) g(f(2)) y
f(3) a g(c) z g?f(3) g(f(3)) y
g(d) x
g(e) x
17
Composition for infinite sets- example
  • f Z ? Z f(n) n 1
  • g Z ? Z g(n) n2
  • g ? f(n) g(f(n)) g(n1) (n1)2
  • f ? g(n) f(g(n)) f(n2) n2 1
  • Note g ? f ? f ? g

18
Identity function
  • iX the identity function for the domain X
  • iX X ? X (?x?X) iX(x) x
  • iY the identity function for the domain Y
  • iY Y ? Y (?y?Y) iY(y) y
  • composition with the identity functions

19
Composition with inverse
  • Recall if f is a bijection then f?1 exists.
  • Let f X ? Y be a bijection.
  • What is f ? f?1?
  • What is f?1 ? f?

20
One-to-one in composition
  • If f X ? Y and g Y ? Z are both one-to-one,
    then g ? f X ? Z is one-to-one.
  • If f X ? Y and g Y ? Z are both onto, then g ?
    f X ? Z is onto.

21
Cardinality
  • Comparing the sizes of sets
  • finite sets (? or there is a positive integer n
    such that there is a bijective function from the
    set to 1,2,,n)
  • infinite sets (there is no such n such that there
    is a bijective function from the set to
    1,2,,n)
  • ? sets A,B, A and B have the same cardinality iff
    there is a one-to-one correspondence from A to B
  • In other words,
  • Cardinality(A) Cardinality(B) ?
  • (? a function f
    ) f A ? B ? f is a bijection

22
Countable sets
  • A set S is called countably infinite iff
    Cardinalit(S) Cardinality(Z).
  • A set is called countable iff it is finite or
    countably infinite.
  • A set which is not countable is called
    uncountable.

23
Discrete StructuresCMSC 250Lecture 40
  • May 5, 2008

24
Countability of sets of integers and the rationals
  • N is this a countably infinite set?
  • Z is this countably infinite set?
  • Neven is this a countably infinite set?
  • Card(Q) ? Card(Z)

25
Real numbers
  • Well take just a part of this infinite set
  • Reals between 0 and 1 (noninclusive)
  • X x ? R 0 lt x lt 1
  • All elements of X can be written as
  • 0.a1a2a3 an

26
Cantors proof
  • Assume the set X x ? R 0 lt x lt 1 is
    countable
  • Then the elements in the set can be listed
  • 0.a11a12a13a14a1n
  • 0.a21a22a23a24a2n
  • 0.a31a32a33a34a3n
  • Select the digits on the diagonal
  • Build a number d, such that d differs in its nth
    position from the nth number in the list

27
All reals
  • Cardinality(x ? R 0 lt x lt 1) Cardinality(R)
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