CHAPTER 3 PROBABILITY TOPICS

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CHAPTER 3 PROBABILITY TOPICS 1. Terminology In this chapter, we are interested in the probability of a particular event occurring when we conduct an experiment. The sample space of an experiment is the set of all possible outcomes of the experiment. An event is one or more outcomes of the experiment. A single outcome is called a simple event. Notation: S = sample space A, B, C,... = event P (A) = probability of event A Example 1. Terminology. Rolling a fair die is an experiment. The sample space of this experiment is S = {1, 2, 3, 4, 5, 6}. (Use set notation to list the outcomes of an event.) A = rolling an even number is an example of an event consisting of three outcomes from the sample space: A = {2, 4, 6}. B = rolling a 3 is an example of a simple event: B = {3}. Probabilities are numbers between zero and one. P (A) = 1 if event A is certain to occur. P (B) = 0 if event B can never happen. If all of the simple events in a sample space are equally likely to occur, P (A) = number of outcomes in A number of outcomes in S. The following are various ways of combining events: A OR B = A B (union): Every outcome in A along with every outcome in B, including outcomes that are in both events. A AND B = A B (intersection): Only outcomes that are in both A and B. A (complement): Every outcome in S that is NOT in A. A given B = A B (conditional event): The event that A happens assuming that B has happened. This has the effect of reducing the sample space from S to B. So, P (A B) = P (A AND B) P (B) = number of outcomes in A AND B. number of outcomes in B 1

2 PROBABILITY TOPICS Example 2. Probability notation. The students at an elementary school have various characteristics that may be of interest to the school administration. Consider the following events: S = the event that a student eats school lunch L = the event that a student brings a lunch box B = the event that a student rides the bus W = the event that a student walks to school Write the symbols for the following probabilities. You may use OR and AND or and. (1) the probability that a student does not bring a lunch box (2) the probability that a student rides the bus or eats school lunch (3) the probability that a student brings a lunch box and walks to school (4) the probablity that a student who rides the bus brings a lunch box Example 3. Simple probabilities. A bowl contains 6 red jelly beans, 8 white jelly beans, 3 yellow jelly beans, and 5 green jellybeans. Randomly select a single jelly bean from the bowl. Consider the following defined events: R = the event that the selected jelly bean is red W = the event that the selected jelly bean is white Y = the event that the selected jelly bean is yellow G = the event that the selected jelly bean is green. Calculate the following probabilities (1) P (R) (2) P (R ) (3) P (Y OR G) (4) P (W AND Y ) (5) P (R G) 2. Independent and Mutually Exclusive Events Two events A and B are independent if the knowledge that one occurs does not affect the probability that the other occurs. Events A and B are independent if any of the following are true (we need check only one): P (A B) = P (A) P (B A) = P (B) P (A AND B) = P (A)P (B) Example 4. Identify independent events intuitively. Identify each pair of events as independent or dependent.

3 the outcomes of two consecutive rolls of a fair die the gender of the first child born to each of two couples taking swim lessons and learning to swim when sampling with replacement, two consecutive draws from a deck of cards when sampling without replacement, two consecutive draws from a deck of cards Example 5. Identify independent events by verifying equation. Let event A = learning Spanish. Let event B = learning German. Then A AND B = learning Spanish and German. Suppose P (A) = 0.4 and P (B) = 0.2. P (A AND B) = 0.08. Are A and B independent? You need only check one equation, but this time check all three. TryIt 3.8. Events A and B are mutually exclusive if they can not both happen at the same time. If one happens, then the other cannot happen. Events A and B are mutually exclusive if and only if P (A AND B) = 0. Example 6. Tree diagram; identify mutually exclusive and independent events. Consider the experiment of flipping a fair coin two times. Record heads (H) or tails (T) for each flip. (1) Draw a tree diagram of the experiment. (2) Use the tree diagram to list the sample space of the experiment. (3) For each event, list the outcomes and find the probability. (a) A = at least one head (b) B = only tails (c) C = only heads (4) Find P (A AND B), P (A AND C), and P (B AND C). (5) Which pairs of events are mutually exclusive? (6) Find P (C A). (7) Are events C and A independent? Variation on Example 3.9. Example 7. Identify independent and mutually exclusive events. A student goes to the library. Let events B = the student checks out a book and D = the student checks out a DVD. Suppose that P (B) = 0.40, P (D) = 0.30, and P (B AND D) = 0.20. (1) Find P (B D). (2) Find P (D B). (3) Are B and D independent? (4) Are B and D mutually exclusive? TryIt 3.10.

4 PROBABILITY TOPICS 3. Two Basic Rules of Probability The multiplication rule states that for events A and B defined on a sample space, P (A AND B) = P (A)P (B A). If A and B are independent events, then P (B A) = P (B) and the rule simpifies to P (A AND B) = P (A)P (B). Notice that the multiplication rule is a rearrangement of the formula for the conditional probability P (B A). Example 8. Helen plays basketball. For free throws, she makes the shot 75% of the time. Helen must now attempt two free throws. C = the event that she makes the first shot; P(C) = 0.75 D = the event that Helen makes the second shot; P(D) = 0.75 However, Helen is more likely to make the second shot if she has made the first: the probability that Helen makes the second free throw given that she made the first is 0.85. What is the probability that Helen makes both free throws? TryIt 3.15. The addition rule states that for events A and B defined on a sample space, P (A OR B) = P (A) + P (B) P (A AND B). If A and B are mutually exclusive events, then P (A AND B) = 0 and the rule simplifies to P (A OR B) = P (A) + P (B). Example 9. Continuing Example 8, find the probability that Helen makes the first or the second free throw (or both). Example 10. A school has 200 seniors of whom 140 will be going to college (C) next year. Forty will be going directly to work (W). The remainder are taking a gap (G) year. Fifty of the seniors going to college play sports (S). Thirty of the seniors going to directly to work play sports. Five of the seniors taking a gap year play sports. (1) What is the probability that a senior is going to college or directly to work? (Classify these events: independent? mutually exclusive?) (2) What is the probability that a senior plays sports? (3) What is the probability that a senior is going to college and plays sports? (Classify these events: independent? mutually exclusive?) (4) What is the probability that a senior is going to college or plays sports? Adapted from TryIt 3.16 and TryIt 3.18. Example 11. A student goes to the library. Let events B = the student checks out a book; and D = the student checks out a DVD.

5 Suppose that P (B) = 0.40, P (D) = 0.30, and P (D B) = 0.5 Describe and find the following probabilities: (1) P (B ) (2) P (D AND B) (3) P (B D) (4) P (D AND B ) (5) P (D B ) TryIt 3.19. The solutions to parts c and e in the book are incorrect. 4. Contingency Tables A contingency table displays frequencies of data relative to two different variables. We will see contingency tables again in Chapter 11. Example 12. Contingency table. Make a two-way contingency table for the information in Example 10. List row and column totals. A school has 200 seniors of whom 140 will be going to college (C) next year. Forty will be going directly to work (W). The remainder are taking a gap (G) year. Fifty of the seniors going to college play sports (S). Thirty of the seniors going to directly to work play sports. Five of the seniors taking a gap year play sports. Use your frequency table to find the following probabilities. (1) P (C) (2) P (C OR G) (3) P (G AND S) (4) P (S W ) (5) P (W S) Adapted from TryIt 3.16. 5. Tree and Venn Diagrams A tree diagram is a special type of graph that helps to determine the outcomes of experiments and to visualize and calculate probabilities. Example 13. Tree diagram; independent events. Roll a die and flip a coin. Draw a tree diagram to show all the possible outcomes. Label the edges with probabilites. Let the numbers 1, 2, 3, 4, 5, and 6, represent the event of landing on that number. Let E be the event of rolling an even number. Let H and T represent landing on heads and tails, respectively. Use the tree diagram to find the following probabilites. (1) P (5 AND H) (2) P (E) (3) P (E AND T ) (4) P (H E) (5) P (5 )

6 PROBABILITY TOPICS Probabilities on the edges of a tree diagram are particularly useful when the events are dependent. Note that when the events are dependent, every level after the first level has conditional probabilities on the edges. Example 14. Tree diagram; dependent events. Suppose there are four green balls and 9 yellow balls in a box. Three balls are drawn from the box without replacement. Draw a tree diagram representing the experiment using probabilities on the edges. Use the tree diagram to find the probabilities of the following events. (1) all three balls are green (2) at least one ball is yellow (3) one ball of each color is selected Similar to Example 3.25 A Venn diagram is another way to organize the outcomes of an experiment graphically. Example 15. Venn diagram. In a certain game, a fair 12-sided die is rolled. A player earns 2 points by landing on an even number (E) and 3 points by landing on a multiple of three (T). (1) Draw a Venn diagram representing the sample space of the die roll. (2) Express each of the following events in terms of E and T, then use the Venn diagram to find the probability of each. (a) Winning 5 points on a single roll (b) Winning at least 2 points on a single roll (c) Going scoreless on a single roll Example 16. Venn diagram; probabilities. In a bookstore, the probability that a customer buys a novel is 0.5, and the probability that the customer buys a non-fiction book is 0.3. Suppose that the probability that the customer buys both is 0.2. (1) Draw a Venn diagram representing the situation. Use probabilities instead of outcome in each space. (2) Find each of the following probabilities. (a) A customer buys either a novel or a non-fiction book (b) A customer does not buy a novel (c) Customers who buy novels are entered into a drawing to win tickets to a book signing by a famous author. Add a circle to the Venn diagram representing the winners of the tickets. Variation on TryIt 3.30.

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