The accompanying table gives the distance from a particular city to seven other cities (in thousands of miles) and gives the time for one randomly chosen, commercial airplane to make that flight. D a complete regression analysis that includes a scatterplot with the line, interprets the slope and intercept, and predicts how much time a nonstop flight from this city would take to another city that is located 3000 miles away.. Click the icon to view the distances and flight times. Draw a scatterplot for the round-trip flight data. Be sure that distance is the x-variable and time is the y-variable, because time is being predicted from distance. Graph the best-fit line using technology. Choose the correct scatterplot below. OA. Time (hours) ○ C. B. Q G 0- 0 3.5 Distance (1000s of mi) 3.5 Distance (1000s of mi) Does it seem that the trend is linear, or is there a noticeable curve? The linear model is appropriate because there is a linear trend in the data. Time (hours) 0 3.5 Distance (1000s of mi) රරත O D. Q Time (hours) Q G 3.5 Flight Data Find the equation for predicting time (in hours) from miles (in thousands). City Distance Time (1000s of miles) (hours) Predicted Time=0.83+ (1.86) Thousand Miles 1 1.119 2.88 (Round to two decimal places as needed.) 2 2.972 6.09 3 3.299 7.24 Interpret the slope in the context of the problem. Select the correct choice below and fill in the answer box to complete your choice. (Round to two decimal places as needed.) 4 1.711 4.38 5 2.399 5.13 OA. For every additional hour, on average, the number of miles goes up by thousand. 6 1.826 4.13 7 0.196 1.16 B Caravans additional thousand miles onvern the time non un bu 100 hum g The accompanying table gives the distance from a particular city to seven other cities (in thousands of miles) and gives the time for one randomly chosen, commercial airplane to make that m a complete regression analysis that includes a scatterplot with the line, interprets the slope and intercept, and predicts how much time a nonstop flight from this city would take to another city located 3000 miles away.. Click the icon to view the distances and flight times. 0 3.5 Distance (1000s of mi) 3.5 Distance (1000s of mi) Does it seem that the trend is linear, or is there a noticeable curve? The linear model is appropriate because there is a linear trend in the data. 0 3.5 Distance (1000s of mi) 0 3.5 Distance (1000s of mi) Find the equation for predicting time (in hours) from miles (in thousands). Predicted Time=0.83 + (1.86) Thousand Miles (Round to two decimal places as needed.) Interpret the slope in the context of the problem. Select the correct choice below and fill in the answer box to complete your choice. (Round to two decimal places as needed.) OA. For every additional hour, on average, the number of miles goes up by thousand. B. For every additional thousand miles, on average, the time goes up by 1.86 hours. Interpret the intercept in the context of the problem. Although there are no flights with a distance of zero, try to explain what might cause the added time that the intercept represents. (Round to two decimal places as needed.) OA. A trip of zero hours would be about B. A trip of zero miles would take about thousand miles. However, a trip would never take exactly zero hours, so these extra miles might account for when the plane taxis the runway. hours. However, a trip would never be exactly zero miles, so this time might account for delays in taking off and landing.
The accompanying table gives the distance from a particular city to seven other cities (in thousands of miles) and gives the time for one randomly chosen, commercial airplane to make that flight. D a complete regression analysis that includes a scatterplot with the line, interprets the slope and intercept, and predicts how much time a nonstop flight from this city would take to another city that is located 3000 miles away.. Click the icon to view the distances and flight times. Draw a scatterplot for the round-trip flight data. Be sure that distance is the x-variable and time is the y-variable, because time is being predicted from distance. Graph the best-fit line using technology. Choose the correct scatterplot below. OA. Time (hours) ○ C. B. Q G 0- 0 3.5 Distance (1000s of mi) 3.5 Distance (1000s of mi) Does it seem that the trend is linear, or is there a noticeable curve? The linear model is appropriate because there is a linear trend in the data. Time (hours) 0 3.5 Distance (1000s of mi) රරත O D. Q Time (hours) Q G 3.5 Flight Data Find the equation for predicting time (in hours) from miles (in thousands). City Distance Time (1000s of miles) (hours) Predicted Time=0.83+ (1.86) Thousand Miles 1 1.119 2.88 (Round to two decimal places as needed.) 2 2.972 6.09 3 3.299 7.24 Interpret the slope in the context of the problem. Select the correct choice below and fill in the answer box to complete your choice. (Round to two decimal places as needed.) 4 1.711 4.38 5 2.399 5.13 OA. For every additional hour, on average, the number of miles goes up by thousand. 6 1.826 4.13 7 0.196 1.16 B Caravans additional thousand miles onvern the time non un bu 100 hum g The accompanying table gives the distance from a particular city to seven other cities (in thousands of miles) and gives the time for one randomly chosen, commercial airplane to make that m a complete regression analysis that includes a scatterplot with the line, interprets the slope and intercept, and predicts how much time a nonstop flight from this city would take to another city located 3000 miles away.. Click the icon to view the distances and flight times. 0 3.5 Distance (1000s of mi) 3.5 Distance (1000s of mi) Does it seem that the trend is linear, or is there a noticeable curve? The linear model is appropriate because there is a linear trend in the data. 0 3.5 Distance (1000s of mi) 0 3.5 Distance (1000s of mi) Find the equation for predicting time (in hours) from miles (in thousands). Predicted Time=0.83 + (1.86) Thousand Miles (Round to two decimal places as needed.) Interpret the slope in the context of the problem. Select the correct choice below and fill in the answer box to complete your choice. (Round to two decimal places as needed.) OA. For every additional hour, on average, the number of miles goes up by thousand. B. For every additional thousand miles, on average, the time goes up by 1.86 hours. Interpret the intercept in the context of the problem. Although there are no flights with a distance of zero, try to explain what might cause the added time that the intercept represents. (Round to two decimal places as needed.) OA. A trip of zero hours would be about B. A trip of zero miles would take about thousand miles. However, a trip would never take exactly zero hours, so these extra miles might account for when the plane taxis the runway. hours. However, a trip would never be exactly zero miles, so this time might account for delays in taking off and landing.
Glencoe Algebra 1, Student Edition, 9780079039897, 0079039898, 2018
18th Edition
ISBN:9780079039897
Author:Carter
Publisher:Carter
Chapter10: Statistics
Section10.2: Representing Data
Problem 2BGP
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Interpret the intercept in the context of the problem. Although there are no flights with a distance of zero, try to explain what might cause added time that the intercept represents.
Last part of question I need help.
Transcribed Image Text:The accompanying table gives the distance from a particular city to seven other cities (in thousands of miles) and gives the time for one randomly chosen, commercial airplane to make that flight. D
a complete regression analysis that includes a scatterplot with the line, interprets the slope and intercept, and predicts how much time a nonstop flight from this city would take to another city that is
located 3000 miles away..
Click the icon to view the distances and flight times.
Draw a scatterplot for the round-trip flight data. Be sure that distance is the x-variable and time is the y-variable, because time is being predicted from distance. Graph the best-fit line using
technology. Choose the correct scatterplot below.
OA.
Time (hours)
○ C.
B.
Q
G
0-
0
3.5
Distance (1000s of mi)
3.5
Distance (1000s of mi)
Does it seem that the trend is linear, or is there a noticeable curve?
The linear model
is
appropriate because there is a
linear
trend in the data.
Time (hours)
0
3.5
Distance (1000s of mi)
රරත
O D.
Q
Time (hours)
Q
G
3.5
Flight Data
Find the equation for predicting time (in hours) from miles (in thousands).
City
Distance
Time
(1000s of miles)
(hours)
Predicted Time=0.83+ (1.86) Thousand Miles
1
1.119
2.88
(Round to two decimal places as needed.)
2
2.972
6.09
3
3.299
7.24
Interpret the slope in the context of the problem. Select the correct choice below and fill in the answer box to complete your choice.
(Round to two decimal places as needed.)
4
1.711
4.38
5
2.399
5.13
OA. For every additional hour, on average, the number of miles goes up by
thousand.
6
1.826
4.13
7
0.196
1.16
B
Caravans additional thousand miles
onvern the time non un bu 100 hum
g
Transcribed Image Text:The accompanying table gives the distance from a particular city to seven other cities (in thousands of miles) and gives the time for one randomly chosen, commercial airplane to make that m
a complete regression analysis that includes a scatterplot with the line, interprets the slope and intercept, and predicts how much time a nonstop flight from this city would take to another city
located 3000 miles away..
Click the icon to view the distances and flight times.
0
3.5
Distance (1000s of mi)
3.5
Distance (1000s of mi)
Does it seem that the trend is linear, or is there a noticeable curve?
The linear model is appropriate because there is a linear
trend in the data.
0
3.5
Distance (1000s of mi)
0
3.5
Distance (1000s of mi)
Find the equation for predicting time (in hours) from miles (in thousands).
Predicted Time=0.83 + (1.86) Thousand Miles
(Round to two decimal places as needed.)
Interpret the slope in the context of the problem. Select the correct choice below and fill in the answer box to complete your choice.
(Round to two decimal places as needed.)
OA. For every additional hour, on average, the number of miles goes up by thousand.
B. For every additional thousand miles, on average, the time goes up by 1.86 hours.
Interpret the intercept in the context of the problem. Although there are no flights with a distance of zero, try to explain what might cause the added time that the intercept represents.
(Round to two decimal places as needed.)
OA. A trip of zero hours would be about
B. A trip of zero miles would take about
thousand miles. However, a trip would never take exactly zero hours, so these extra miles might account for when the plane taxis the runway.
hours. However, a trip would never be exactly zero miles, so this time might account for delays in taking off and landing.
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