In: Statistics and Probability
Engineers concerned about a tower's stability have done extensive studies of its increasing tilt. Measurements of the lean of the tower over time provide much useful information. The following table gives measurements for the years 1975 to 1987. The variable "lean" represents the difference between where a point on the tower would be if the tower were straight and where it actually is. The data are coded as tenths of a millimeter in excess of 2.9 meters, so that the 1975 lean, which was 2.9648 meters, appears in the table as 648.
Only the last two digits of the year were entered into the computer.
Year 75 76 77 78 79 80 81 82 83 84 85 86 87
Lean 648 649 661 673 678 693 702 704 718 723 731 747 763
(a) Plot the data. Consider whether or not the trend in lean over time appears to be linear. (Do this on paper. Your instructor may ask you to turn in this graph.)
(b) What is the equation of the least-squares line? (Round your answers to three decimal places.) y = + x What percent of the variation in lean is explained by this line? (Round your answer to one decimal place.) %
(c) Give a 99% confidence interval for the average rate of change (tenths of a millimeter per year) of the lean. (Round your answers to two decimal places.) ( , )
Independent variable, X: Year
Dependent variable, Y: Lean
(a)
Following is the scatter plot of the data:
Scatter plot shows that there is a strong linear positive relationship between the variables.
(b)
Following is the output of regression analysis:
The equation of the least-squares line is:
y' = -57.808+9.346*x
The percent of the variation in lean is explained by this line, the r-square, is
0.989 or 98.8%
(c)
A 99% confidence interval for the average rate of change (tenths of a millimeter per year) of the lean is
(8.38, 10.31)