1. Part 3 Module 5 The Multiplication Rule Recall the following advice from our study of counting in Part 1 Module 6: Generally: 1. “or” means “add” 2. “and” means “multiply.” We have seen, in Part 3 Modules 3 and 4, that the fact #1 above carries over to probability: P(E or F) = P(E) + P(F) for mutually exclusive events; P(E or F) = P(E) + P(F) – P(E and F) in general. We are about to see that fact #2 above also carries over to probability.

2. “and” means “multiply” In probability, just as in counting, “and” is associated with multiplication. We have the following fact that can be used to calculate the probability of the conjunction of two or more events: For any events E, F P(E and F) = P(E) × P(F, given E)

3. The Multiplication Rule This fact is called the general multiplication rule: For any events E, F P(E and F) = P(E) × P(F, given E) In words: to find the probability that two events will both occur, multiply the probability that the first event will occur, times the probability that the second event will occur, assuming that the first event did occur.

4. Example At the Wee Folks Gathering there are 4 hobbits (H) 8 gnomes (G) They will randomly select one person serve as Wolverine Groomer and a different person to serve as Cat Washer. 1. What is the probability that the Wolverine Groomer is a hobbit (H 1 ) and the Cat Washer is a gnome (G 2 )? A..1667 B..2424 C..2222 D. None of these 2. What is the probability that both selectees are gnomes (G 1 and G 2 )? 3. What is the probability that at least one selectee is a hobbit?

5. Solution At the Wee Folks Gathering there are 4 hobbits (H) 8 gnomes (G) They will randomly select one person serve as Wolverine Groomer and a different person to serve as Cat Washer. 1. What is the probability that the Wolverine Groomer is a hobbit (H 1 ) and the Cat Washer is a gnome (G 2 )? When they select the Wolverine Groomer, they have 12 people to choose from, 4 of whom are hobbits, so P(H 1 ) = 4/12. Assuming that the Wolverine Groomer was a hobbit, when they select the Cat Washer they have 11 people to choose from, 8 of whom are gnomes, so P(G 2, given H 1 ) = 8/11. Thus, P(H 1 and G 2 ) = 4/12 × 8/11 = 32/132 =.2424 2. What is the probability that both selectees are gnomes (G 1 and G 2 )? P(G 1 and G 2 ) = 8/12 × 7/11 = 56/132 =.4242

6. Solution At the Wee Folks Gathering there are 4 hobbits (H) 8 gnomes (G) They will randomly select one person serve as Wolverine Groomer and a different person to serve as Cat Washer. 3. What is the probability that at least one selectee is a hobbit? The shortest way to answer this question is to use the complements rule, applied to the answer to the previous question. Since “at least one” is the opposite (complement) of “none,” the probability that at least one selectee is a hobbit, is one minus the probability that neither selectee is a hobbit, or P(at least one selectee is a hobbit) = 1 – P(both selectees are gnomes) = 1 –.4242 =.5758

7. Example http://www.math.fsu.edu/~wooland/prob/prob22.html History indicates that when Homerina the basketball player goes to the foul line to shoot a pair of free throws, she will make the first shot 87% of the time. If she makes the first shot, then she will make the second shot 78% of the time. On the other hand, if she misses the first shot, then she will make the second shot 46% of the time. What is the probability that Homerina will miss the first shot and miss the second shot? A. 0.0598 B. 0.0939 C. 0.0909 D. 0.0702 E. 0.4698 A. B. C. D. E.

8. Solution History indicates that when Homerina the basketball player goes to the foul line to shoot a pair of free throws, she will make the first shot 87% of the time. If she makes the first shot, then she will make the second shot 78% of the time. On the other hand, if she misses the first shot, then she will make the second shot 46% of the time. What is the probability that Homerina will miss the first shot and miss the second shot? P(miss both shots) = P(miss 1 st shot) × P(miss 2 nd shot, given missed 1 st shot) The data tells use that 87% of the time she makes the first shot; this means that she will miss the first shot 13% of the time. P(miss 1 st shot) =.13 That data tell us that if she misses the first shot, then 46% she will make the second shot, so, if she misses the first shot, 54% of the time she will miss the second shot. P(miss 2 nd shot, given missed 1 st shot) =.54 So, P(miss both shots) =.13 ×.54 =.0702

9. Follow-up question History indicates that when Homerina the basketball player goes to the foul line to shoot a pair of free throws, she will make the first shot 87% of the time. If she makes the first shot, then she will make the second shot 78% of the time. On the other hand, if she misses the first shot, then she will make the second shot 46% of the time. Use the answer to the previous question to answer this question: What is the probability that she will make at least one of the two shots? Answer: Either (Make both shots) or (Make first and miss second) or (Miss first and make second).87 ×.78 +.87 ×.22 +.13 ×.46 =.9892 Alternate solution Since “At least one” is the opposite of “none,” P(Make at least one shot) = 1 – P(Miss both shots) = 1 – (.13 ×.54) = 1 –.0702 =.9892

10. Independent Events Two or more events are independent if they don’t affect or influence one another. More formally, E and F are independent events if the occurrence of E does not affect the probability of F, and the occurrence of F does not affect the probability of E. Example: suppose we have a red die and a green die. The experiment involves rolling each die. Let E be the event that when we roll the red die we get an even number, and let F be the event that when we roll the green die we get a “2.” These are independent events: the probability of one event is not affected by whether or not the other event occurs. Suppose we want to find the probability that both events occur…

11. The Multiplication Rule for Independent Events If E, F are independent events P(E and F) = P(E) × P(F) In words: to find the probability that two independent events will both occur, multiply the probability that the first event will occur, times the probability that the second event will occur. Referring to the previous question: The probability that the red die roll will produce an even number is 3/6 and the probability that the green die roll will produce a “2” is 1/6, so the probability that both events occur is 3/6 × 1/6 = 3/36 =.0833

12. Pseudo-independent events A survey a preschoolers indicates that 10% agree with the statement “broccoli tastes good.” If two preschoolers are randomly selected, what is the probability that both of them agree with the statement? We must emphasize that there is not enough information to answer this question exactly. In order to do so, we would have to know the exact size of the population (N) and exactly how many agreed with the statement (A), in which case P(Both agree) = A/N × (A–1)/(N–1) which is also the same as C(A,2)/C(N,2) In a case like this, where an experiment involves selections from a large population of unspecified size, we will approximate the answer by pretending that the selections are independent, even though, strictly speaking, they aren’t. Thus, P(both agree) = P(First person agrees) × P(Second person agrees) =.1 ×.1 =.01 Again, this answer (.01) is not the exact answer, but it is the best we can do working only with the percent information, not knowing the size of the population. For large populations, the resulting error is not significant.

13. Another example Suppose a three-digit number is randomly created using digits from this set: {1, 3, 6, 8, 9} What is the probability that the number has no repeated digits? Solution: If we want to use the multiplication rule, we must understand that what is important in this case is the following: 1.Regardless of which digit is selected as the first digit, the second digit must be different from the first digit. The probability that the second digit is different from the first digit is 4/5. 2.Regardless of which two digits were chose for the first and second digits, the third digit must be different from both of the first two digits. The probability that the third digit is different from both of the first two digits is 3/5. So, the probability that there are no repeated digits is 4/5 × 3/5 = 12/25=.48 This is the same as P(5,3)/(5×5×5×5), which is another correct way to solve the problem.

14. “At least one” is the complement of “none” New question: Suppose a three-digit number is randomly created using digits from this set: {1, 3, 6, 8, 9} What is the probability that the number has at least one repeated digit? Solution: This is a much more complicated question to deal with directly, but it is easy to answer if we realize that we can use the answer to the previous question. Since “at least one” is the opposite (complement) of “none”, we have P(“at least one repeated digit”) = 1 – P(“no repeated digits”) = 1 –.48 (.8 was the answer to the previous question) =.52

15. Yet another example A box contains a $1 bill, a $5 bill, a $10 bill, a $20 bill, a $50 bill and a $100 bill. Three bills are chosen without replace and their monetary sum is determined. What is the probability that the monetary sum will be $151. Solution #1 An outcome in this experiment is a monetary sum obtained by adding the values of the three bills, such as $16, $80, $35, or $151. Note that the monetary is determined by which three bills are selected. The number of equally-likely outcomes in this experiment is the number of ways to choose three bills from a set of six bills: C(6,3) = 20. There are twenty different, equally-likely, monetary sums. Of the twenty different monetary sums, one of them “$151.” So, P(“monetary sum = $151”) = 1/20 =.05

16. Alternative solution If you would like to solve the previous problem by using the multiplication rule instead of by solving a counting problem, here is the rationale: The only way to get a monetary sum of $151 is if we select the $1 bill and the $50 bill and the $100 bill. When we select the “first” of the three bills, the probability that it will be the $1 or the $50 or the $100 is 3/6. Assuming that one of those three is selected, when we select the second bill, the probability that it will one of the two “needed” bills that remain will be 2/5. Finally, assuming that the first two bills selected were two of our three “needed” bills, the probability that the third “needed” bill will be selected on the third draw is 1/4. 3/6 × 2/5 × 1/4 = 6/120 =.05