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Chapter 10: Problem 1

$$\begin{array}{|l|c|c|c|c|} \hline & \text { Married } & \text { Never } & \text { Divorced } & \text { Widowed } & \text { Total } \\ \hline \text { Male } & 65 & 40 & 10 & 3 & 118 \\ \hline \text { Female } & 65 & 34 & 14 & 11 & 124 \\ \hline \text { Total } & 130 & 74 & 24 & 14 & 242 \\ \hline \end{array}$$ If one person is randomly selected from the population described in the table, find the probability, expressed as a simplified fraction and as a decimal to the nearest hundredth, that the person is divorced.

Short Answer

Expert verified
The probability that a randomly selected person is 'divorced' is \( \frac{12}{121} \) or 0.099 (rounded to three decimal places).

Step by step solution

01

Identify the Required Data from the Table

From the table, one can see that the total number of 'divorced' persons is 24 (from both genders combined). Also, the total population size, or the total number of people listed in the table, is 242.
02

Compute the Probability

The probability of an event is given by the ratio of the favorable outcomes to the total outcomes. In this case, the favorable outcomes are the individuals who are 'divorced' and the total outcomes are the total number of people. Hence, the required probability is \( \frac{24}{242} \).
03

Simplify the Resulting Fraction

The fraction \( \frac{24}{242} \) simplifies to \( \frac{12}{121} \). This is done by dividing both the numerator and the denominator by their greatest common divisor, which is 2.
04

Convert the Simplified Fraction to a Decimal

By dividing 12 by 121, the approximate decimal representation of the fraction is obtained, which is 0.099 (rounded to three decimal places).

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Key Concepts

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

Understanding the Probability of an Event
Probability is a fundamental concept in statistics that tells us how likely an event is to occur. When you hear the term "probability of an event," it refers to the measure of the chance that a particular outcome will happen. To find the probability, you divide the number of ways the event can occur by the total number of possible outcomes.
This gives you a ratio that can be expressed in different forms, such as fractions, decimals, or percentages. In this example, to find the probability that a randomly selected person is divorced, we look at the event where the person chosen is from the ‘divorced’ group.
Creating a Simplified Fraction
A simplified fraction makes numbers easier to work with by reducing them to their smallest form. To simplify a fraction, divide both the numerator (top number) and the denominator (bottom number) by their greatest common divisor (GCD).
In our example, the fraction for the probability that a person is divorced started as \( \frac{24}{242} \). By dividing both the numerator and denominator by their GCD, which is 2, we reduced the fraction to \( \frac{12}{121} \).
It is always helpful to simplify fractions for ease of interpretation and computation.
Interpreting Decimal Representation
Decimal representation offers another format to express probability, making it often easier to understand at a glance. After simplifying the fraction, you can convert it to a decimal by performing the division \( 12 \div 121 \).
This yields approximately 0.099. Converting probabilities into decimals is common because it provides a straightforward way to compare likelihoods. Rounding to the nearest hundredth, which in this case is 0.10, simplifies communication, but keep track of what rounding means for accuracy in interpretation.
Counting Favorable Outcomes
Favorable outcomes are the specific outcomes of an event that meet the criteria of interest. Here, the favorable outcomes are the number of 'divorced' individuals identified in the table.
From the exercise, we learned that the number of people who are divorced equals 24, encompassing both males and females. These outcomes form the numerator in our probability fraction. Identifying favorable outcomes is a fundamental skill in problem-solving, providing a clear focus on what we are measuring.
Evaluating Total Outcomes
Total outcomes represent all possible results that can occur in a given scenario. It's essential to enumerate these accurately for precise probability calculations.
In this context, the total outcomes refer to the entire population size listed in the table, which is the denominator of our probability fraction. The total count amounts to 242 when considering all marital statuses across genders. Understanding the total outcomes ensures that probabilities are computed correctly and are representative of the entire dataset.

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Most popular questions from this chapter

Among all pairs of numbers whose sum is \(24,\) find a pair whose product is as large as possible. What is the maximum product? (Section 2.2, Example 6)

Convert the equation $$ 4 x^{2}+y^{2}-24 x+6 y+9=0 $$ to standard form by completing the square on \(x\) and \(y .\) Then graph the ellipse and give the location of the foci. (Section 9.1, Example 5).

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The president of a large company with \(10,000\) employees is considering mandatory cocaine testing for every employee. The test that would be used is \(90 \%\) accurate, meaning that it will detect \(90 \%\) of the cocaine users who are tested, and that \(90 \%\) of the nonusers will test negative. This also means that the test gives \(10 \%\) false positive. Suppose that \(1 \%\) of the employees actually use cocaine. Find the probability that someone who tests positive for cocaine use is, indeed, a user. Hint: Find the following probability fraction: the number of employees who test positive and are cocaine users the number of employees who test positive This fraction is given by \(90 \%\) of \(1 \%\) of \(10,000\) the number who test positive who actually use cocaine plus the number who test positive who do not use cocaine What does this probability indicate in terms of the percentage of employees who test positive who are not actually users? Discuss these numbers in terms of the issue of mandatory drug testing. Write a paper either in favor of or against mandatory drug testing, incorporating the actual percentage accuracy for such tests.

Some statements are false for the first few positive integers, but true for some positive integer \(m\) on. In these instances, you can prove \(S_{n}\) for \(n \geq m\) by showing that \(S_{m}\) is true and that \(S_{k}\) implies \(S_{k+1}\) when \(k \geq m .\) Use this extended principle of mathematical induction to prove that each statement in is true. Prove that \(n^{2} > 2 n+1\) for \(n \geq 3 .\) Show that the formula is true for \(n=3\) and then use step 2 of mathematical induction.
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