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Chapter 5: Problem 79

An online store offers two methods of shipping-regular ground service and an expedited 2 -day shipping. Customers may also choose whether or not to have a purchase gift wrapped. Suppose that the events \(E=\) event that the customer chooses expedited shipping \(G=\) event that the customer chooses gift wrap are independent with \(P(E)=0.26\) and \(P(G)=0.12\). a. Construct a "hypothetical 1000 " table with columns corresponding to whether or not expedited shipping is chosen and rows corresponding to whether or not gift wrap is selected. b. Use the table to calculate \(P(E \cup G)\). Give a long-run relative frequency interpretation of this probability.

Short Answer

Expert verified
The probability of a customer choosing expedited shipping or gift wrap, or both, denoted by \(P(E \cup G)\) is approximately 0.3568 or 35.68%. This means that if we were to simulate this scenario with 1000 customers many times, on average about 357 customers would choose either expedited shipping or gift wrap or both in each simulation.

Step by step solution

01

Understanding the Problem

It's understood that customers can either choose or not to choose expedited shipping and gift wrapping. These two events are termed as 'E' and 'G' respectively. The problem also provides the probability for each event, and states these events are independent - meaning that the occurrence of one event does not affect the occurrence of the other.
02

Constructing a 'Hypothetical 1000' Table

Based on the given probabilities, the number of customers who will choose expedited shipping out of 1000 will be \(0.26 \times 1000 = 260\). Those who will choose gift wrapping will be \(0.12 \times 1000 = 120\). Because these two events are independent, the number of customers who will choose both expedited shipping and gift wrapping will be the product of their individual probabilities, which is \(0.26 \times 0.12 \times 1000 = 31.2\). The table will be like: \n\n\n| Choice | Expedited Shipping | No Expedited Shipping | TOTAL |\n| ------------- | ----------------: | --------------------: | ----: |\n| Gift wrap | 31.2 | 88.8 | 120 |\n| No Gift wrap | 228.8 | 651.2 | 880 |\n| TOTAL | 260 | 740 | 1000 |
03

Calculating \(P(E \cup G)\)

The union of two events E and G, denoted E U G, refers to either E, or G, or both happening at the same time. The probability of the union of two independent events is given by the sum of the probabilities of each event, minus the probability of the intersection of the two events. Therefore, \(P(E \cup G) = P(E) + P(G) - P(E)P(G) = 0.26 + 0.12 - 0.26 \times 0.12 = 0.3568\).
04

Providing Long-run Relative Frequency Interpretation

A long-run relative frequency interpretation of this probability means that in the long run, out of 1000 customers, approximately 357 will either choose expedited shipping or gift wrap or both.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Independent Events Probability
When we talk about independent events in probability, we are referring to the scenario where the outcome of one event does not influence the occurrence of another. In other words, knowing whether one event has happened does not change the likelihood of the other event happening.

For instance, in the exercise provided, the decision to choose expedited shipping (Event E) is independent from the decision to choose gift wrapping (Event G). This is an important concept in probability because it simplifies the calculation of the likelihood of both events occurring together. To determine the probability that both independent events happen, we simply multiply their individual probabilities:
\[ P(E \text{ and } G) = P(E) \cdot P(G) \].

In practical terms, if a customer's decision to expedite shipping has no impact on their choice to have their items gift wrapped, each choice is made without regard to the other. This characteristic of independence is pivotal to understanding how different probabilities can interact within a statistical context.
Hypothetical 1000 Table
A 'hypothetical 1000' table is a powerful illustration tool used in statistics to envision the outcomes of events based on their probabilities. By scaling up to 1000 cases, it becomes easier to conceptualize the probabilities as tangible counts, aiding in understanding and calculation.

In this exercise, constructing the table involved multiplying the probability of each event by 1000. This provides an estimate of how many times we would expect each event to occur if we repeated the situation 1000 times. The table is divided into categories—such as with or without expedited shipping and with or without gift wrapping—and the numbers filled in each cell reflect the expected frequency. This visual representation simplifies the calculation of joint and union probabilities and makes the abstract concept of probability more concrete.

For example, to determine the number of customers who might choose both expedited shipping and gift wrap, we use the independent probabilities of E and G. By the independence property, we multiply these together and then by 1000, which yields an estimate that serves to populate the corresponding cell of our table.
Long-run Relative Frequency Interpretation
The long-run relative frequency interpretation of probability is the idea that if an experiment were repeated many times, the proportion of a particular outcome would approach a certain value. This is the 'long-run' probability of the event. It is a practical approach, especially when discussing independent events, because it considers the outcomes of multiple trials.

In the given problem, when we talk about the probability of customers choosing either expedited shipping or gift wrapping or both, we calculate the long-run relative frequency as the measure of likelihood. The calculation of \(P(E \cup G)\) gives us a way to predict and interpret the outcomes over an infinite number of trials or customers, though we often illustrate it with a large but finite number like 1000. So, the long-run relative frequency tells us that if we observe 1000 customers, approximately 357 of them will either choose expedited shipping or gift wrapping or both. This interpretation is helpful because it transforms abstract probability into real-world expectations that can inform decisions and predictions.

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Most popular questions from this chapter

The report "Twitter in Higher Education: Usage Habits and Trends of Today's College Faculty" (Magna Publications, September 2009) describes a survey of nearly 2,000 college faculty. The report indicates the following: \- \(30.7 \%\) reported that they use Twitter, and \(69.3 \%\) said that they do not use Twitter. \- Of those who use Twitter, \(39.9 \%\) said they sometimes use Twitter to communicate with students. \- Of those who use Twitter, \(27.5 \%\) said that they sometimes use Twitter as a learning tool in the classroom. Consider the chance experiment that selects one of the study participants at random. a. Two of the percentages given in the problem specify unconditional probabilities, and the other two percentages specify conditional probabilities. Which are conditional probabilities, and how can you tell? b. Suppose the following events are defined: \(T=\) event that selected faculty member uses Twitter \(C=\) event that selected faculty member sometimes uses Twitter to communicate with students \(L=\) event that selected faculty member sometimes uses Twitter as a learning tool in the classroom Use the given information to determine the following probabilities: i. \(P(T)\) iii. \(P(C \mid T)\) ii. \(P\left(T^{C}\right)\) iv. \(P(L \mid T)\) c. Construct a "hypothetical 1000 " table using the given probabilities and use it to calculate \(P(C),\) the probability that the selected study participant sometimes uses Twitter to communicate with students. d. Construct a "hypothetical 1000 " table using the given probabilities and use it to calculate the probability that the selected study participant sometimes uses Twitter as a learning tool in the classroom.

An airline reports that for a particular flight operating daily between Phoenix and Atlanta, the probability of an on-time arrival is \(0.86 .\) Give a relative frequency interpretation of this probability.

The paper "Action Bias among Elite Soccer Goalkeepers: The Case of Penalty Kicks" ( Journal of Economic Psychology [2007]: \(606-621\) ) presents an interesting analysis of 286 penalty kicks in televised championship soccer games from around the world. In a penalty kick, the only players involved are the kicker and the goalkeeper from the opposing team. The kicker tries to kick a ball into the goal from a point located 11 meters away. The goalkeeper tries to block the ball from entering the goal. For each penalty kick analyzed, the researchers recorded the direction that the goalkeeper moved (jumped to the left, stayed in the center, or jumped to the right) and whether or not the penalty kick was successfully blocked. Consider the following events: \(L=\) the event that the goalkeeper jumps to the left \(C=\) the event that the goalkeeper stays in the center \(R=\) the event that the goalkeeper jumps to the right \(B=\) the event that the penalty kick is blocked Based on their analysis of the penalty kicks, the authors of the paper gave the following probability estimates: $$ \begin{array}{rrr} P(L)=0.493 & P(C)=0.063 & P(R)=0.444 \\ P(B \mid L)=0.142 & P(B \mid C)=0.333 & P(B \mid R)=0.126 \end{array} $$ a. For each of the given probabilities, write a sentence giving an interpretation of the probability in the context of this problem. b. Use the given probabilities to construct a "hypothetical 1000" table with columns corresponding to whether or not a penalty kick was blocked and rows corresponding to whether the goalkeeper jumped left, stayed in the center, or jumped right. (Hint: See Example 5.14) c. Use the table to calculate the probability that a penalty kick is blocked. d. Based on the given probabilities and the probability calculated in Part (c), what would you recommend to a goalkeeper as the best strategy when trying to defend against a penalty kick? How does this compare to what goalkeepers actually do when defending against a penalty kick?

Suppose you want to estimate the probability that a patient will develop an infection while hospitalized at a particular hospital. In the past year, this hospital had 6,450 patients, and 712 of them developed an infection. What is the estimated probability that a patient at this hospital will develop an infection?

The Australian newspaper The Mercury (May 30,1995\()\) reported that based on a survey of 600 reformed and current smokers, \(11.3 \%\) of those who had attempted to quit smoking in the previous 2 years had used a nicotine aid (such as a nicotine patch). It also reported that \(62 \%\) of those who had quit smoking without a nicotine aid began smoking again within 2 weeks and \(60 \%\) of those who had used a nicotine aid began smoking again within 2 weeks. If a smoker who is trying to quit smoking is selected at random, are the events selected smoker who is trying to quit uses a nicotine aid and selected smoker who has attempted to quit begins smoking again within 2 weeks independent or dependent events? Justify your answer using the given information.
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