Presentation is loading. Please wait.

Presentation is loading. Please wait.

12.4 – Permutations & Combinations. Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration.

Published byShawn Welch Modified over 8 years ago

Similar presentations

Presentation on theme: "12.4 – Permutations & Combinations. Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration."— Presentation transcript:

1 12.4 – Permutations & Combinations

2 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration.

3 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration. Ex. 1 A travel agency is planning a vacation package in which travelers will visit 5 cities around Europe. How many ways can the agency arrange the 5 cities along the tour?

4 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration. Ex. 1 A travel agency is planning a vacation package in which travelers will visit 5 cities around Europe. How many ways can the agency arrange the 5 cities along the tour? 5 ∙ (5-1) ∙ (5-2) ∙ (5-3) ∙ (5-4)

5 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration. Ex. 1 A travel agency is planning a vacation package in which travelers will visit 5 cities around Europe. How many ways can the agency arrange the 5 cities along the tour? 5 ∙ (5-1) ∙ (5-2) ∙ (5-3) ∙ (5-4) 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1

6 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration. Ex. 1 A travel agency is planning a vacation package in which travelers will visit 5 cities around Europe. How many ways can the agency arrange the 5 cities along the tour? 5 ∙ (5-1) ∙ (5-2) ∙ (5-3) ∙ (5-4) 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 = 120

7 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration. Ex. 1 A travel agency is planning a vacation package in which travelers will visit 5 cities around Europe. How many ways can the agency arrange the 5 cities along the tour? 5 ∙ (5-1) ∙ (5-2) ∙ (5-3) ∙ (5-4) 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 = 120 *This is called factorial, represented by “!”.

8 Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration. Ex. 1 A travel agency is planning a vacation package in which travelers will visit 5 cities around Europe. How many ways can the agency arrange the 5 cities along the tour? 5 ∙ (5-1) ∙ (5-2) ∙ (5-3) ∙ (5-4) 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 = 120 *This is called factorial, represented by “!”. 5! = 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 = 120

9 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)!

10 P(n,r) = n! (n – r)!

11 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case?

12 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case? P(n,r) = n! (n – r)!

13 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case? P(n,r) = n! (n – r)! P(10,6) = 10! (10 – 6)!

14 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case? P(n,r) = n! (n – r)! P(10,6) = 10! (10 – 6)! P(10,6) = 10! 4!

15 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case? P(n,r) = n! (n – r)! P(10,6) = 10! (10 – 6)! P(10,6) = 10! 4! P(10,6) = 10 ∙ 9 ∙ 8 ∙ 7 ∙ 6 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 4 ∙ 3 ∙ 2 ∙ 1

16 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case? P(n,r) = n! (n – r)! P(10,6) = 10! (10 – 6)! P(10,6) = 10! 4! P(10,6) = 10 ∙ 9 ∙ 8 ∙ 7 ∙ 6 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 4 ∙ 3 ∙ 2 ∙ 1

17 Permutation Formula – The number of permutations of n objects taken r at a time is the quotient of n! and (n – r)! P(n,r) = n! (n – r)! Ex. 2 The librarian is placing 6 of 10 magazines on a shelf in a showcase. How many ways can she arrange the magazines in the case? P(n,r) = n! (n – r)! P(10,6) = 10! (10 – 6)! P(10,6) = 10! 4! P(10,6) = 10 ∙ 9 ∙ 8 ∙ 7 ∙ 6 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 4 ∙ 3 ∙ 2 ∙ 1 P(10,6) = 10 ∙ 9 ∙ 8 ∙ 7 ∙ 6 ∙ 5 = 151,200

18 Combinations – a selection of objects in which order is not considered.

19 Combinations – a selection of objects in which order is not considered. Combination Formula – The number of combinations of n objects taken r at a time is the quotient of n! and (n – r)!r!

20 Combinations – a selection of objects in which order is not considered. Combination Formula – The number of combinations of n objects taken r at a time is the quotient of n! and (n – r)!r! C(n,r) = n! (n – r)!r!

21 Ex. 3 Horatio works part-time at a local department store. His manager asked him to choose for display 5 different styles of shirts from the wall of the store that has 8 shirts on it to put in a display. How many ways can he choose the shirts?

22 C(n,r) = n! (n – r)!r!

23 Ex. 3 Horatio works part-time at a local department store. His manager asked him to choose for display 5 different styles of shirts from the wall of the store that has 8 shirts on it to put in a display. How many ways can he choose the shirts? C(n,r) = n! (n – r)!r! C(8,5) = 8! (8 – 5)!5!

24 Ex. 3 Horatio works part-time at a local department store. His manager asked him to choose for display 5 different styles of shirts from the wall of the store that has 8 shirts on it to put in a display. How many ways can he choose the shirts? C(n,r) = n! (n – r)!r! C(8,5) = 8! (8 – 5)!5! C(8,5) = 8 ∙ 7 ∙ 6 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 3 ∙ 2 ∙ 1 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1

25 Ex. 3 Horatio works part-time at a local department store. His manager asked him to choose for display 5 different styles of shirts from the wall of the store that has 8 shirts on it to put in a display. How many ways can he choose the shirts? C(n,r) = n! (n – r)!r! C(8,5) = 8! (8 – 5)!5! C(8,5) = 8 ∙ 7 ∙ 6 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1 = 56 3 ∙ 2 ∙ 1 ∙ 5 ∙ 4 ∙ 3 ∙ 2 ∙ 1

Download ppt "12.4 – Permutations & Combinations. Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration."

Similar presentations

0.5 – Permutations & Combinations. Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration.

0.5 – Permutations & Combinations. Permutation – all possible arrangements of objects in which the order of the objects is taken in to consideration.
1.8 Combinations of Functions: Composite Functions The composition of the functions f and g is “f composed by g of x equals f of g of x”

1.8 Combinations of Functions: Composite Functions The composition of the functions f and g is “f composed by g of x equals f of g of x”
Counting and Factorial. Factorial Written n!, the product of all positive integers less than and equal to n. Ex: Evaluate.

Counting and Factorial. Factorial Written n!, the product of all positive integers less than and equal to n. Ex: Evaluate.
Consider the possible arrangements of the letters a, b, and c. List the outcomes in the sample space. If the order is important, then each arrangement.

Consider the possible arrangements of the letters a, b, and c. List the outcomes in the sample space. If the order is important, then each arrangement.
Chapter 13 sec. 3.  Def.  Is an ordering of distinct objects in a straight line. If we select r different objects from a set of n objects and arrange.

Chapter 13 sec. 3.  Def.  Is an ordering of distinct objects in a straight line. If we select r different objects from a set of n objects and arrange.
5.4 Counting Methods Objectives: By the end of this section, I will be able to… 1) Apply the Multiplication Rule for Counting to solve certain counting.

5.4 Counting Methods Objectives: By the end of this section, I will be able to… 1) Apply the Multiplication Rule for Counting to solve certain counting.
Permutations r-permutation (AKA “ordered r-selection”) An ordered arrangement of r elements of a set of n distinct elements. permutation of a set of n.

Permutations r-permutation (AKA “ordered r-selection”) An ordered arrangement of r elements of a set of n distinct elements. permutation of a set of n.
Counting If you go to Baskin-Robbins (31 flavors) and make a triple-scoop ice-cream cone, How many different arrangements can you create (if you allow.

Counting If you go to Baskin-Robbins (31 flavors) and make a triple-scoop ice-cream cone, How many different arrangements can you create (if you allow.
Permutations and Combinations With Beanie Babies.

Permutations and Combinations With Beanie Babies.
Do Now Suppose Shaina’s coach has 4 players in mind for the first 4 spots in the lineup. Determine the number of ways to arrange the first four batters.

Do Now Suppose Shaina’s coach has 4 players in mind for the first 4 spots in the lineup. Determine the number of ways to arrange the first four batters.
0.4 – The Counting Principal. The Fundamental Counting Principal If one event can occur m ways followed by another event that can occur n ways then the.

0.4 – The Counting Principal. The Fundamental Counting Principal If one event can occur m ways followed by another event that can occur n ways then the.
Combinations at the Elementary/Secondary Level By Africa Dunn.

Combinations at the Elementary/Secondary Level By Africa Dunn.
Permutations Linear and Circular. Essential Question: How do I solve problems using permutations?

Permutations Linear and Circular. Essential Question: How do I solve problems using permutations?
Chris rents a car for his vacation. He pays $159 for the week and $9.95 for every hour he is late. When he returned the car, his bill was $208.75. How.

Chris rents a car for his vacation. He pays $159 for the week and $9.95 for every hour he is late. When he returned the car, his bill was $ How.
Permutations and Combinations

Permutations and Combinations
Section 3: Trees and Counting Techniques Example Suppose a fast food restaurant sells ice cream cones in two sizes (regular and large) and three flavors.

Section 3: Trees and Counting Techniques Example Suppose a fast food restaurant sells ice cream cones in two sizes (regular and large) and three flavors.
It is very important to check that we have not overlooked any possible outcome. One visual method of checking this is making use of a tree diagram.

It is very important to check that we have not overlooked any possible outcome. One visual method of checking this is making use of a tree diagram.
Section 12.7 Permutations and Combinations. Permutations An arrangement or listing where order is important.

Section 12.7 Permutations and Combinations. Permutations An arrangement or listing where order is important.
October 13, 2009 Combinations and Permutations.

October 13, 2009 Combinations and Permutations.
© The McGraw-Hill Companies, Inc., 2000 4-1 Chapter 4 Counting Techniques.

© The McGraw-Hill Companies, Inc., Chapter 4 Counting Techniques.

Similar presentations

Ads by Google