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2357.90 2349.17 8.73 2256.70 2219.13 37.57 2165.20 2144.83 20.37 2399.55 2488.50 −88.95 1799.80 1698.98 80.82 2336.75 2265.58 71.17 1765.30 1810.44 −45.14 2053.50 1959.06 94.44 2414.40 2404.90 9.50 2200.50 2163.40 37.10 2654.20 2553.52 100.68 1753.70 1829.02 −75.32 in17-2 in17-3 in17-4

      The least-squares fit is

ueqn17-1

      We may interpret the slope −37.15 as the average weekly decrease in propellant shear strength due to the age of the propellant. Since the lower limit of the x’s is near the origin, the intercept 2627.82 represents the shear strength in a batch of propellant immediately following manufacture. Table 2.2 displays the observed values yi, the fitted values in17-5, and the residuals.

      After obtaining the least-squares fit, a number of interesting questions come to mind:

      1 How well does this equation fit the data?

      2 Is the model likely to be useful as a predictor?

      3 Are any of the basic assumptions (such as constant variance and uncorrelated errors) violated, and if so, how serious is this?

       TABLE 2.3 Minitab Regression Output for Example 2.1

Regression Analysis
The regression equation is
Strength = 2628- 37.2 Age
Predictor Coef StDev T P
Constant 2627.82 44.18 59.47 0.000
Age -37.154 2.889 -12.86 0.000
S = 96.11 R-Sq = 90.2% R-Sq(adj) = 89.6%
Analysis of Variance
Source DF SS MS F P
Regression 1 1527483 1527483 165.38 0.000
Error 18 166255 9236
Total 19 1693738

       Computer Output

      Computer software packages are used extensively in fitting regression models. Regression routines are found in both network and PC-based statistical software, as well as in many popular spreadsheet packages. Table 2.3 presents the output from Minitab, a widely used PC-based statistics package, for the rocket propellant data in

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