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Chapter 3: Q19E (page 170)

USDA chicken inspection. The U.S. Department of Agriculture (USDA) reports that one in every 100 slaughtered chickens passes inspection with fecal contamination under its standard inspection system.

a. If a slaughtered chicken is selected at random, what is the probability of passing inspection with fecal contamination?

b. The probability of part a was based on a USDA study that found that 306 of 32,075 chicken carcasses passed inspection with fecal contamination. Do you agree with the USDA's statement about the likelihood of a slaughtered chicken passing inspection with fecal contamination?

Short Answer

Expert verified

  1. 0.1


  2. No

Step by step solution

01

Step-by-Step SolutionStep 1: The probability that it will pass fecal contamination inspection

Probability refers to the chance of a random event's outcome. This term refers to determining the likelihood of a given occurrence occurring.

Here,

Fecal contamination is detected in one out of every 100 slaughtered chickens.

Therefore,

P(Randomlyselectedchickenpassesinspectionwithfecalcontamination)=1100=0.01

Hence, the probability is 0.1.

02

The USDA's statement that a slaughtered chicken with fecal contamination is unlikely to pass inspection

No, it's difficult to agree with the USDA's statement regarding the possibility of a slaughtered chicken passing inspection with fecal contamination. According to this research, just 1% of slaughtered chickens pass fecal contamination inspection, implying an extremely low success rate.

It means that 99% of the chickens slaughtered are infected, an unusually high proportion.

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Most popular questions from this chapter

The three-dice gambling problem. According toSignificance(December 2015), the 16th-century mathematician Jerome Cardan was addicted to a gambling game involving tossing three fair dice. One outcome of interest鈥 which Cardan called a 鈥淔ratilli鈥濃攊s when any subset of the three dice sums to 3. For example, the outcome {1, 1, 1} results in 3 when you sum all three dice. Another possible outcome that results in a 鈥淔ratilli鈥 is {1, 2, 5}, since the first two dice sum to 3. Likewise, {2, 3, 6} is a 鈥淔ratilli,鈥 since the second die is a 3. Cardan was an excellent mathematician but calculated the probability of a 鈥淔ratilli鈥 incorrectly as 115/216 = .532.

a. Show that the denominator of Cardan鈥檚 calculation, 216, is correct. [Hint: Knowing that there are 6 possible outcomes for each die, show that the total number of possible outcomes from tossing three fair dice is 216.]

b. One way to obtain a 鈥淔ratilli鈥 is with the outcome {1,1, 1}. How many possible ways can this outcome be obtained?

c. Another way to obtain a 鈥淔ratilli鈥 is with an outcome that includes at least one die with a 3. First, find the number of outcomes that do not result in a 3 on any of the dice. [Hint: If none of the dice can result in a 3, then there are only 5 possible outcomes for each die.] Now subtract this result from 216 to find the number of outcomes that include at least one 3.

d. A third way to obtain a 鈥淔ratilli鈥 is with the outcome {1, 2, 1}, where the order of the individual die outcomes does not matter. How many possible ways can this outcome be obtained?

e. A fourth way to obtain a 鈥淔ratilli鈥 is with the outcome {1, 2, 2}, where the order of the individual die outcomes does not matter. How many possible ways can this outcome be obtained?

f. A fifth way to obtain a 鈥淔ratilli鈥 is with the outcome {1, 2, 4}, where the order of the individual die outcomes does not matter. How many possible ways can this outcome be obtained? [Hint:There are 3 choices for the first die, 2 for the second, and only 1 for the third.]

g. A sixth way to obtain a 鈥淔ratilli鈥 is with the outcome {1, 2, 5}, where the order of the individual die outcomes does not matter. How many possible ways can this outcome be obtained? [See Hintfor part f.]

h. A final way to obtain a 鈥淔ratilli鈥 is with the outcome {1, 2, 6}, where the order of the individual die outcomes does not matter. How many possible ways can this outcome be obtained? [See Hintfor part f.]

i. Sum the results for parts b鈥揾 to obtain the total number of possible 鈥淔ratilli鈥 outcomes.

j. Compute the probability of obtaining a 鈥淔ratilli鈥 outcome. Compare your answer with Cardan鈥檚.

New car crash tests.Refer to the National Highway TrafficSafety Administration (NHTSA) crash tests of new car models, Exercise 2.153 (p. 143). Recall that the NHTSA has developed a 鈥渟tar鈥 scoring system, with results ranging from one star (*) to five stars (). The more stars in the rating, the better the level of crash protection in a head-on collision. A summary of the driver-side star ratings for 98 cars is reproduced in the accompanying Minitab

Printout. Assume that one of the 98 cars is selected at random. State whether each of the following is true or false.

a.The probability that the car has a rating of two stars is 4.

b.The probability that the car has a rating of four or five stars is .7857.

c.The probability that the car has a rating of one star is 0.

d.The car has a better chance of having a two-star rating than of having a five-star rating.

Two fair coins are tossed, and the following events are defined:

A: [Observe one head and one tail.]

B: [Observe at least one head.]

a. Define the possible sample points and assign probabilities to each.

b. Draw a Venn diagram for the experiment, showing the sample points and events A and B.

c. Find P(A), P(B) andP(AB).

d. Use the formula for conditional probability to find P (A/B)and P (B/A). Verify your answer by inspecting the Venn diagram and using the concept of reduced sample spaces.

Two fair dice are tossed, and the following events are defined:

A: {Sum of the numbers showing is odd.}

B: {Sum of the numbers showing is 9, 11, or 12.}

Are events A and B independent? Why?

For two events, A and B, P(A)=.4 , P(B)= .2, and P(A/B)= .6:

a. Find P (AB).

b. Find P(B/A).
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