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Title: Chapter 5 Section 5


1
Chapter 5Section 5
  • Counting
  • Techniques

2
Chapter 5 Section 5
  • Learning objectives
  • Solving counting problems using the
    Multiplication Rule
  • Solving counting problems using permutations
  • Solving counting problems using combinations
  • Solving counting problems involving
    permutations with nondistinct items
  • Compute probabilities involving permutations
    and combinations

3
Chapter 5 Section 5
  • Learning objectives
  • Solving counting problems using the
    Multiplication Rule
  • Solving counting problems using permutations
  • Solving counting problems using combinations
  • Solving counting problems involving
    permutations with nondistinct items
  • Compute probabilities involving permutations
    and combinations

4
Chapter 5 Section 5
  • The classical method, when all outcomes are
    equally likely, involves counting the number of
    ways something can occur
  • This section includes techniques for counting the
    number of results in a series of choices, under
    several different scenarios

5
Chapter 5 Section 5
  • Example
  • If there are 3 different colors of paint (red,
    blue, green) that can be used to paint 2
    different types of toy cars (race car, police
    car), then how many different toys can there be?
  • 3 colors 2 cars 3 2 6 different toys
  • This can be shown in a table or in a tree diagram

6
Chapter 5 Section 5
  • A table of the different possibilities
  • This is a rectangle with 2 rows and 3 columns 2
    3 6 entries

Red Blue Green
Race Car RedRace Car BlueRace Car Green Race Car
Police Car Red Police Car Blue Police Car Green Police Car
7
Chapter 5 Section 5
  • A tree diagram of the different possibilities
  • This also shows that there are 6 possibilities

Paint
Car
8
Chapter 5 Section 5
  • The Multiplication Counting Rule multiply the
    number of different tasks
  • Example 3 colors of paint for 2 types of race
    cars.
  • Example 4 colors of paint for 3 types of race
    cars with 6 choices of tires.
  • Example How many meals are possible with 4
    appetizers, 5 entrees, and 3 desserts?

9
Chapter 5 Section 5
  • Example Part A
  • A child is coloring a picture of a shirt and
    pants
  • There are 5 different colors of markers
  • How many ways can this be colored?
  • By the multiplication rule
  • 5 5 25

10
Chapter 5 Section 5
  • Example Part B
  • A child is coloring a picture of a shirt and
    pants
  • There are 5 different colors of markers
  • The child wants to use 2 different colors
  • How many ways can this be colored?
  • By the multiplication rule
  • 5 4 20

11
Chapter 5 Section 5
  • Allowing the same marker to be used twice
  • 5 5 25
  • Requiring that there be two different markers
  • 5 4 20
  • There are 5 selections for the first choice for
    both Part A and Part B of this example
  • But they differ for the second choice there are
    only 4 selections for Part B

12
Chapter 5 Section 5
  • Example continued
  • Part A, allowing the same marker to be used
    twice, is called counting with repetition and has
    formulas such as
  • 5 5 5
  • Part B, requiring that there be two different
    markers, is called counting without repetition
    and has formulas such as
  • 5 4 3

13
Chapter 5 Section 5
  • Factorial symbol n!
  • n! n (n-1) (n-2) 2 1
  • We start off by saying that
  • 0! 1 and 1! 1
  • For example
  • 5! 5 4 3 2 1 120
  • Notice how 5! looks like the 5 4 3 from the
    previous example

14
Chapter 5 Section 5
  • Learning objectives
  • Solving counting problems using the
    Multiplication Rule
  • Solving counting problems using permutations
  • Solving counting problems using combinations
  • Solving counting problems involving
    permutations with nondistinct items
  • Compute probabilities involving permutations
    and combinations

15
Chapter 5 Section 5
  • The problem of choosing one marker out of 5 and
    then choosing a second marker out of the 4
    remaining is an example of a permutation
  • A permutation is an ordered arrangement
  • Ex. Write out all the arrangements of the
    letters in USA
  • The number of ways is written nPr

16
Chapter 5 Section 5
  • The number of ways of choosing one marker out of
    5 and then choosing a second marker out of the 4
    remaining is 5P2 20

17
Chapter 5 Section 5
  • Stop

18
Chapter 5 Section 5
  • Learning objectives
  • Solving counting problems using the
    Multiplication Rule
  • Solving counting problems using permutations
  • Solving counting problems using combinations
  • Solving counting problems involving
    permutations with nondistinct items
  • Compute probabilities involving permutations
    and combinations

19
Chapter 5 Section 5
  • For some problems, the order of choice does not
    matter
  • Order matters example
  • Choosing one person to be the president of a club
    and another to be the vice-president
  • Two different roles
  • Order does not matter example
  • Choosing two people to go to a meeting
  • The same role

20
Chapter 5 Section 5
  • When order does not matter, this is called a
    combination
  • A combination is an
  • unordered arrangement, in which
  • r different objects are chosen out of
  • n different objects with
  • repetition not allowed
  • The number of ways is written nCr

21
Chapter 5 Section 5
  • Comparing the description of a permutation with
    the description of a combination
  • The only difference is whether order matters

Permutation Combination
Order matters Order does not matter
Choose r objects Choose r objects
Out of n objects Out of n objects
No repetition No repetition
22
Chapter 5 Section 5
  • Example
  • If there are 8 researchers and 3 of them are to
    be chosen to go to a meeting permutations or
    combinations?
  • A combination since order does not matter
  • There are 56 different ways that this can be done

23
Chapter 5 Section 5
  • Is a problem a permutation or a combination?
  • One way to tell
  • Write down one possible solution (i.e. Roger,
    Rick, Randy)
  • Switch the order of two of the elements (i.e.
    Rick, Roger, Randy)
  • Is this the same result?
  • If no this is a permutation order matters
  • If yes this is a combination order does not
    matter

24
Chapter 5 Section 5
  • Learning objectives
  • Solving counting problems using the
    Multiplication Rule
  • Solving counting problems using permutations
  • Solving counting problems using combinations
  • Solving counting problems involving
    permutations with nondistinct items
  • Compute probabilities involving permutations
    and combinations

25
Chapter 5 Section 5
  • Our permutation and combination problems so far
    assume that all n total items are different
  • Sometimes we have a permutations but not all of
    the n items are different
  • This is a more complicated problem
  • How many ways are there?

26
Chapter 5 Section 5
  • Example
  • How many ways to put 3 As, 2 Ns, and 2 Ts to
    try to make a seven letter sequence?
  • ____ ____ ____ ____ ____ ____ ____
  • Each of the blanks can be filled in with either
    an A or a N or a T
  • The three As are the same the two Ns are the
    same the two Ts are the same

27
Chapter 5 Section 5
  • Example continued
  • Where can the As go?
  • ____ ____ ____ ____ ____ ____ ____
  • There are 7 possible places
  • Any 3 of them are possible
  • Order does not matter
  • So 7C3 different ways to put in the As
  • What about the Ns and Ts?
  • 4C2 different ways to put in the Ns
  • 2C2 different ways to put in the Ts

28
Chapter 5 Section 5
  • Example continued
  • Altogether there are
  • 7C3 4C2 2C2
  • different ways
  • This is
  • Notice that the denominator is 3, 2, 2 the
    numbers of each letter

29
Chapter 5 Section 5
  • The general formula for the number of
    permutations of
  • n total objects where there are
  • n1 of the first kind
  • n2 objects of the second kind
  • and
  • nk of the kth kind is

30
Chapter 5 Section 5
  • Learning objectives
  • Solving counting problems using the
    Multiplication Rule
  • Solving counting problems using permutations
  • Solving counting problems using combinations
  • Solving counting problems involving
    permutations with nondistinct items
  • Compute probabilities involving permutations
    and combinations

31
Chapter 5 Section 5
  • A permutation example
  • In a horse racing Trifecta, a gambler must pick
    which horse comes in first, which second, and
    which third
  • If there are 8 horses in the race, and every
    order of finish is equally likely, what is the
    chance that any ticket is a winning ticket?
  • Order matters, so this is a permutations problem
  • There are 8P3 permutations of the order of finish
    of the horses
  • The probability that any one ticket is a winning
    ticket is 1 out of 8P3, or 1 out of 336

32
Chapter 5 Section 5
  • A combination example
  • The Powerball lottery consists of choosing 5
    numbers out of 55 and then 1 number out of 42
  • The grand prize is given out when all 6 numbers
    are correct
  • What is the chance of getting the grand prize?
  • Order doesnt matter (combinations problem)
  • There are 55C5 combinations of the 5 numbers
  • There are 42C1 combinations of the last number
  • 1/( 55C5 x 42C1 )

33
Summary Chapter 5 Section 5
  • The Multiplication Rule counts the number of
    possible sequences of items
  • Permutations and combinations count the number of
    ways of arranging items, with permutations when
    the order matters and combinations when the order
    does not matter
  • Permutations and combinations are used to compute
    probabilities in the classical method
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