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\begin{tabular}{|c|c|}
\hline
\multicolumn{2}{|c|}{ Freezing Temperatures [tex]$\left( ^{\circ} \right.$[/tex] ) } \\
\hline
[tex]$F$[/tex] & [tex]$C$[/tex] \\
\hline
-13 & -25 \\
\hline
-4 & -20 \\
\hline
5 & -15 \\
\hline
14 & -10 \\
\hline
23 & -5 \\
\hline
\end{tabular}

The table shows temperatures below freezing measured in different units. Complete the equation in standard form to represent the relationship between [tex]$F$[/tex], a temperature measured in degrees Fahrenheit, and [tex]$C$[/tex], a temperature measured in degrees Celsius.

[tex]$5F + \square = \square$[/tex]

[tex]$39^{\circ} F = \square^{\circ} C$[/tex] rounded to the nearest tenth of a degree.



Answer :

GinnyAnswer
To represent the relationship between temperatures measured in degrees Fahrenheit ([tex]\(F\)[/tex]) and degrees Celsius ([tex]\(C\)[/tex]) for the given data, we need to derive an equation in the form [tex]\(5F + \square = 9C\)[/tex].

Given the data points:

[tex]\[ \begin{array}{|c|c|} \hline F & C \\ \hline -13 & -25 \\ \hline -4 & -20 \\ \hline 5 & -15 \\ \hline 14 & -10 \\ \hline 23 & -5 \\ \hline \end{array} \][/tex]

We know from the relationship between Fahrenheit and Celsius that they are linearly related. To express this relationship in the form [tex]\(5F + \square = 9C\)[/tex]:

1. We start by calculating the linear regression coefficients, which will give us the slope ([tex]\(m\)[/tex]) and the y-intercept ([tex]\(b\)[/tex]). The slope [tex]\(m\)[/tex] shows us how much [tex]\(C\)[/tex] changes for a unit change in [tex]\(F\)[/tex], and the intercept [tex]\(b\)[/tex] is the value of [tex]\(C\)[/tex] when [tex]\(F\)[/tex] is 0.

2. Using linear regression calculation for the given points, we find that the slope ([tex]\(m\)[/tex]) and the intercept ([tex]\(b\)[/tex]) are determined to be:

[tex]\[ m \approx 0.56 \quad \text{and} \quad b \approx -17.8 \][/tex]

3. Knowing that the relationship can be expressed as:
[tex]\[ C = mF + b \][/tex]

4. We want to rewrite this in the form [tex]\(5F + \square = 9C\)[/tex]. To do this, we need to multiply the entire equation [tex]\(C = 0.56F - 17.8\)[/tex] by 9 to match the coefficient of [tex]\(C\)[/tex] in [tex]\(9C\)[/tex]. This yields:

[tex]\[ 9C = 9(0.56F - 17.8) \][/tex]

5. Simplifying, we get:

[tex]\[ 9C = 5.04F - 160.2 \][/tex]

6. We compare this equation with [tex]\(5F + \square = 9C\)[/tex]:

[tex]\[ 5.04F - 160.2 = 5F + \square \][/tex]

7. To conform to the form [tex]\(5F + \square\)[/tex], we notice that [tex]\(5.04\)[/tex] can be approximated by 5 when rounding to a single decimal place. This introduces a slight adjustment for the constant term:

[tex]\[ 5F + 2.8 (\text{rounded from } -160.2 + 160.2) = 9C \][/tex]

Therefore, the completed equation in standard form to represent the relationship between [tex]\(F\)[/tex] and [tex]\(C\)[/tex] is:

[tex]\[ 5F + 2.8 = 9C \][/tex]

Hence, the values for the blanks in the equation [tex]\(5F + \square = 9C\)[/tex] are:
[tex]\[ \boxed{2.8 \text{ and } -15.0} \][/tex]

Thus:

[tex]\[ \boxed{5F + 2.8 = 9C} \][/tex]