Warm-Up

1. Warm-Up 1. What is Benford’s Law? • What two numbers do all probabilities fall between? • What does equally likely outcomes mean? • What is the formula for equally likely outcomes? • What distribution does Benford’s Law fall under? • What distribution does equally likely outcomes follow?

2. Probability: The Mathematics of Chance The Mean and Standard Deviation of a Probability Model • Mean of a Continuous Probability Model • Suppose the area under a density curve was cut out of solid material. The mean is the point at which the shape would balance. • Law of Large Numbers • As a random phenomenon is repeated a large number of times: • The proportion of trials on which each outcome occurs gets closer and closer to the probability of that outcome, and • The mean¯ of the observed values gets closer and closer to μ. (This is true for trials with numerical outcomes and a finite mean μ.) x 2

4. Experimental Probability • Observing the results of an experiment • An event which has a 0% chance of happening (i.e. impossible) is assigned a probability of 0. • An event which has a 100% chance of happening (i.e. is certain) is assigned a probability of 1. • All other events can then be assigned a probability between 0 and 1.

5. Experimental Probability Terminology • Number of Trials – the total number of times the experiment is repeated. • The outcomes – the different results possible for one trial of the experiment. • Frequency – the number of times that a particular outcome is observed. • Relative Frequency – the frequency of an outcome expressed as a fraction or percentage of the total number of trials. • **experimental probability = relative frequency**

6. Sample Space • The set of all possible outcomes of an experiment • Examples: • Tossing a coin • Rolling a die

7. Example • We roll two dice and record the up-faces in order (first die, second die) • What is the sample space S? • What is the event A: “ roll a 5”?

8. Probability Model • Example: Rolling two dice • We roll two dice and record the up-faces in order (first die, second die) • All possible outcomes • (1,1) (1,2) (1,3) (1,4) (1,5) (1,6) • (2,1) (2,2) (2,3) (2,4) (2,5) (2,6) • (3,1) (3,2) (3,3) (3,4) (3,5) (3,6) • (4,1) (4,2) (4,3) (4,4) (4,5) (4,6) • (5,1) (5,2) (5,3) (5,4) (5,5) (5,6) • (6,1) (6,2) (6,3) (6,4) (6,5) (6,6) • “Roll a 5” : {(1,4) (2,3) (3,2) (4,1)}

9. Probability Models • Give me the sample space for: Flipping two coins.

10. Experimental Probability Examples Coin Tossing & Dice Rolling Coin Toss Dice

11. 2-D Grids: • Illustrate the possible outcomes when 2 coins are tossed. • Illustrate the possible outcomes for the sum of 2 dice being rolled. 2-D Grid

12. 2-D Grids: 3. Illustrate the possible outcomes when tossing a coin and rolling a die.

13. Tree Diagrams Illustrate the possible outcomes when • tossing 2 coins • drawing 2 marbles from a bag containing red, green and yellow marbles Tree Diagrams

14. Theoretical Probability • For fair spinners, coins or die (where a particular outcome is not weighted) the outcomes are considered to have an equal likelihood. • For a fair dice, the likelihood of rolling a 3 is the same as rolling a 5… both 1 out of 6 • This is a mathematical (or theoretical) probability and is based on what we expect to occur. • A measure of the chance of that event occurring in any trial of the experiment

15. Warm-Up • Have your homework out on your desk. • Create a tree diagram for the following. • Flipping two coins • Pulling a marble out of a bag full of blue, green and yellow marbles. • How many outcomes total? • What is the probability of pulling a blue marble out of the bag? • What is the probability of flipping heads in the scenario?

16. Homework Answers

17. Theoretical Probability Examples • A ticket is randomly selected from a basket containing 3 green, 4 yellow and 5 blue tickets. Determine the probability of getting: • A green ticket • A green or yellow ticket • An orange ticket • A green, yellow or blue ticket

18. Complementary Events • An ordinary 6-sided die is rolled once. Determine the chance of: • Getting a 6 • Not getting a 6 • Getting a 1 or 2 • Not getting a 1 or 2

19. Warm-Up • Have your homework out on your desk.

20. Homework Check

21. More Grids to Find Probabilities • Use a two-dimensional grid to illustrate the sample space for tossing a coin and rolling a die simultaneously. From this grid determine the probability of: • Tossing a head • Getting a tail and a 5 • Getting tail or a 5

22. More Grids to Find Probabilities (cont.) • 2 circular spinners, each with 1 – 10 on their edges are twirled simultaneously. Draw a 2D grid of the possible outcomes and use your grid to determine the probability of getting • A 3 with each spinner • A 3 and a 1 • An even result for each spinner Spinner

23. Warm-Up Compound Events • Create a 2-D grid for the following situation. • A coin is tossed and at the same time, a die is rolled. The result for the coin will be outcome A and the die, outcome B.

24. Homework Check

25. 1. A coin is tossed three times. Find the probability that the result is at least two heads. • 1/2 B. 1/3 • C. 3/8 D. None of these

26. 2. A card is drawn from a standard deck of 52 cards. Then, a second card is drawn from the deck (without replacing the first one). Find the probability that a red card is selected first and a spade is selected second. • 1/3 B. 1/8 C. 13/102 D. None of these

27. 3. From an urn containing 16 cubes of which 5 are red, 5 are white, and 6 are black, a cube is drawn at random. Find the probability that the cube is red or black. • 11/16 B. 9/16 C. 15/128 D. 5/16

28. 4. Two events that have nothing in common are called: A. inconsistent B. mutually exclusive C. complements D. Both A and B

29. 5. A bag contains 5 white balls and 4 red balls. Two balls are selected in such a way that the first ball drawn is not replaced before the next ball is drawn. Find the probability of selecting exactly one white ball. • 12/72 B. 20/72 C. 5/9 D. 4/5

30. 6. A and B are two events such that p(A) = 0.2 and p(B) = 0.4. If , find . • 0.45 B. 0.6 • C. 0.85 D. None of these

31. Warm-Up • Create a tree diagram. When you go to a restaurant you have a choice for three course meals your 4 salad choices, 6 entrees, and 5 dessert choices. • How many possible outcomes are there?

32. Independent Events • Events where the occurrence of one of the events does not affect the occurrence of the other event. • In general, if A and B are independent events, then • P(A and B) = P(A) x P(B) • Ex: a coin and a die are tossed simultaneously. Determine the probability of getting a head and a 3 without using a grid.

33. Using Tree Diagrams

34. Examples:

35. Examples (cont.): • Carson is not having much luck lately. His car will only start 80% of the time and his moped will only start 60% of the time. • Draw a tree diagram to illustrate the situation. • 1st set of branches for the car, 2nd set of branches for the moped • Use the diagram to determine the chance that • Both will start • He has to take his car. • He has to take the bus.

36. Dependent Events • Think About It: A hat contains 5 red and 3 blue tickets. One ticket is randomly chosen and thrown out. A second ticket is randomly selected. What is the chance that it is red? • Not independent; the occurrence of one of the events affects the occurrence of the other event. • If A and B are dependent events then P(A then B) = P(A) x P(B given that A has occurred)

37. Examples: • A box contains 4 red and 2 yellow tickets. Two tickets are randomly selected one by one from the box, without replacement. Find the probability that: • Both are red • The first is red and the second is yellow

38. Examples (cont.): • A hat contains tickets with numbers 1 – 20 printed on them. If 3 tickets were drawn from the hat without replacement, determine the probability that all are prime numbers.

39. Examples (cont.): • A box contains 3 red, 2 blue and 1 yellow marble. Draw a tree diagram to represent drawing 2 marbles. • With replacement Without replacement • Find the probability of getting two different colors: • If replacement occurs • If replacement does not occur

40. Examples (cont.): • A bag contains 5 red and 3 blue marbles. Two marbles are drawn simultaneously from the bad. Determine the probability that at least one is red.

41. Z Is it a fair game? • Questions will be put up on the board • For each, you have to decide if the game is: • Fair • Not Fair • Once you decide on your answer, write it on your mini-whiteboard • Only show the you answer when asked

42. Is it a fair game? Z • Three people have boards like the one shown below. You throw a coin onto a board, if it lands on a shaded square you win • (assume the coin lands exactly in a square)

43. Is it a fair game? Z A marble is picked from the container by the teacher If its red the girls get a point, if its blue the boys get a point

44. Is it a fair game? Z Nine cards numbers 1 to 9 are used for a game A card is drawn at random If a multiple of 3 is drawn team A gets a point If a square number is drawn team B gets a point If any other number is drawn team C gets a point 1 2 3 4 5 6 7 8 9

45. Is it a fair game? Z A spinner has 5 equal sectors numbers 1 to 5, it is spun many times If the spinner stops on an even number team A gets 3 points If the spinner stops on an odd number team B gets 2 points 5 1 4 2 3

46. Warm Up • Get your homework out. • A box contains 4 red marbles, 5 blue marbles and 1 green marble. We select 2 marbles without replacement. Determine the probability of getting: • At least 1 red marble • One green and one blue marble

47. Sets & Venn Diagrams • A Venn diagram consists of a rectangle which represents the sample space and at least 1 circle within it representing particular events.

48. Examples • The Venn diagram represents a sample space of students. The event E, shows all those that have blue eyes. Determine the probability that a student • Has blue eyes

49. Examples (cont.) • Draw a Venn diagram and shade the regions to represent the following: • 1. In A but not in B 2. Neither in A nor B

50. denotes the union of the sets A and B. • A or B or both A and B. • denotes the intersection of sets A and B. • All elements common to both sets. • Disjoint sets do not have elements in common. So • A and B are said to be mutually exclusive.