Hw 6.3

A roulette wheel has 38​ numbers, with 18 odd numbers​ (black) and 18 even numbers​ (red), as well as 0 and 00​ (which are​ green). If you bet $18 that the outcome is an odd​ number, the probability of losing the $18 is 20/38 and the probability of winning $36 (for a net gain of only $18​, given you already paid $18​) is 18/38. a. If a player bets $18 that the outcome is an odd​ number, what is the​ player's expected​ value? b. Is the best option to bet $18 on odd or to not​ bet? Why?

a. -0.95 b. Not betting is best because it has the highest expected value.

If you bet $10 in a Pick 4 lottery​ game, you either lose $10 or gain $8,990. (The winning prize is $9,000​, but your $10 bet is not​ returned, so the net gain is $8,990​.) The game is played by selecting a​ four-digit number between 0000 and 9999. a. What is the probability of​ winning? b. If you bet $10 on​ 1234, what is the expected value of your gain or​ loss?

a. 1 / 10,000 b. -9.10

What is an expected value and how is it​ computed? Should we always expect to get the expected​ value? Why or why​ not?

a. Expected value is the estimated gain or loss of partaking in an event many times. EV= (event 1) x (event 1 probability) + (event 2 value) x (event 2 probability) b. We should not always expect to get the expected value because expected value is calculated with the assumption that the law of large numbers will come into play.

Suppose you toss a fair coin 100​ times, getting 38 heads and 62​ tails, which is 24 more tails than heads. a. Explain​ why, on your next​ toss, the difference between the numbers of heads and tails is as likely to grow to 25 as it is to shrink to 23. b. Extend your explanation from part​ (a) to explain​ why, if you toss the coin 1000 more​ times, the final difference between the numbers of heads and tails is as likely to be larger than 24 as it is to be smaller than 24. c. Suppose that you continue tossing the coin. Explain why the following statement is​ true: If you stop at any random​ time, you always are more likely to have fewer heads than​ tails, in total. d. Suppose you are betting on heads with each coin toss. After the first 100​ tosses, you are well on the losing side. Explain​ why, if you continue to​ bet, you will most likely remain on the losing side. How is this answer related to the​ gambler's fallacy?

a. On every​ toss, it is just as likely to land on heads as it is to land on tails. If you toss a​ head, the difference becomes 23. If you toss a​ tail, the difference becomes 25 b. On each​ toss, the difference in heads and tails is equally likely to increase or decrease. After 1000​ tosses, the difference is equally likely to be greater than 24 or less than 24. c. Once you have 24 more tails than​ heads, the difference is as likely to increase as to​ decrease; thus, the number of tails is likely to remain greater than the number of heads. d. Once you have fewer heads than​ tails, the deficit of heads is likely to remain. A streak of bad luck does not mean that a person is due for a streak of good luck.

a. What is the law of large​ numbers? b. Can it be applied to a single observation or​ experiment? Explain.

a. The law of large numbers states that if a process is repeated through many​ trials, the proportion of the trials in which event A occurs will be close to the probability​ P(A). b. It does not apply to a single trial​ (observation or​ experiment), or even to small numbers of​ trials, but only to a large number of trials.