Probability and Statistics for Engineering and the Sciences
Probability and Statistics for Engineering and the Sciences
9th Edition
ISBN: 9781305251809
Author: Jay L. Devore
Publisher: Cengage Learning
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Chapter 10, Problem 37SE

Numerous factors contribute to the smooth running of an electric motor (“Increasing Market Share Through Improved Product and Process Design: An Experimental Approach,” Quality Engineering, 1991: 361–369). In particular, it is desirable to keep motor noise and vibration to a minimum. To study the effect that the brand of bearing has on motor vibration, five different motor bearing brands were examined by installing each type of bearing on different random samples of six motors. The amount of motor vibration (measured in microns) was recorded when each of the 30 motors was running. The data for this study follows. State and test the relevant hypotheses at significance level .05, and then carry out a multiple comparisons analysis if appropriate.

Expert Solution & Answer
Check Mark
To determine

State the relevant hypotheses and test the same at level of significance 0.05.

Perform a multiple comparisons analysis, if appropriate.

Answer to Problem 37SE

The relevant hypotheses are:

Null hypothesis:

 H0:μ1=μ2=μ3=μ4=μ5=0

Alternative hypothesis:

 Ha:μi0, for at least one i=1,2,3,4,5.

The F test at level α=0.05 suggests that the true average motor vibrations differ between at least two of the five brands.

A multiple comparison Tukey’s test reveals that the brands 5, 3 and 1 are similar, brands 5, 3 and 1 are similar, the brands 1 and 4 are similar and the brands 4 and 2 are similar, in terms of motor vibrations. There is significant difference of brand 5 with brands 4 and 2, and also significant difference of brand 3 with brand 2.

Explanation of Solution

Given info:

The data relates to 6 observations on running motor vibration (microns), corresponding to 5 different motor bearing brands. The sample means are also provided for each brand, where X¯1.=13.68, X¯2.=15.95, X¯3.=13.67, X¯4.=14.73 and X¯5.=13.08.

Calculation:

Suppose there are I treatments and J observations corresponding to each treatment in a designed experiment, resulting in a total of IJ observations. Then, the following properties hold true:

  • Degrees of freedom (df): The treatment df is I1, the total df is IJ1. The error df is the difference between these, that is, I(J1).
  • Sum of squares: The total sum of squares (SST), treatment sum of squares (SSTr) and error sum of squares (SSE) are related as: SST=SSTr+SSE.
  • Mean of squares: The mean of squares is the ratio of the sum of squares to the corresponding df. The mean square error (MSE) is, MSE=SSEI(J1). The mean square treatment (MSTr) is, MSTr=SSTrI1.
  • The F-statistic: The F- statistic is the ratio of MSTr and MSE, that is, F=MSTrMSE.

Here, each motor bearing brand is a treatment.

Denote Xij as the jth observation corresponding to the ith treatment, for j=1,2,...,J(=6), corresponding to each i=1,2,...,I(=5).

State the test hypotheses.

Null hypothesis:

 H0:μ1=μ2=μ3=μ4=μ5=0

That is, the effects of all the treatments are similar.

Alternative hypothesis:

 Ha:μi0, for at least one i=1,2,3,4,5.

That is, the effects of all the treatments are not similar.

Test statistic:

The suitable test statistic is the F- statistic, which is the ratio of the mean square treatment (MSTr) and the mean square error (MSE), that is,

F=MSTrMSE.

Degrees of freedom:

In this case, number of treatments (types of boxes) is I=5. Thus, the treatment df is:

I1=51=4.

The number of observations corresponding to each treatment is J=6.

The total df is:

IJ1=(5×6)1=301=29.

The error df is:

I(J1)=5×(61)=5×5=25.

The numerator degrees of freedom is:

ν1=I1=4.

The denominator degrees of freedom is:

ν2=I(J1)=25.

Calculation for test statistic:

The sample total corresponding to the ith treatment is:

Xi.=j=1JiXij, i=1,2,...,I.

The sample means are X¯1.=13.68, X¯2.=15.95, X¯3.=13.67, X¯4.=14.73, X¯5.=13.08.

Thus, the corresponding sample totals are:

X1.=JiX¯1.=6×13.68=82.1.

X2.=JiX¯1.=6×15.95=95.7.

X3.=JiX¯1.=6×13.67=82.0.

X4.=JiX¯1.=6×14.73=88.4.

X5.=JiX¯1.=6×13.08=78.5.

The grand total is:

X=i=1IXi.=82.1+95.7+82.0+88.4+78.5=426.7..

Thus, the grand mean is:

X¯..=1IJi=1Ij=1JXij=1IJi=1IXi.=1IJX..=426.730

=14.22.

The mean square of treatments, MSTr is:

MSTr=SSTrI1=JI1i=1I(X¯i.X¯..)2=64[(13.6814.22)2+(15.9514.22)2+(13.6714.22)2+(14.7314.22)2+(13.0814.22)2]=32[0.2916+2.9929+0.3025+0.2601+1.2996]

=7.72.

Thus, the sum of squares of treatment is:

SSTr=MSTr×(I1)=7.72×4=30.88.

The total sum of squares, SST is:

SST=i=1Ij=1JXij21IJX2

The calculation for j=1JXij2 is shown in the following table:

Brand 1X1j13.1151414.41411.6
X21j171.61225196207.36196134.56j=1JX1j2=1,130.53
Brand 2X2j16.315.717.214.914.417.2
X22j265.69246.49295.84222.01207.36295.84j=1JX2j2=1,533.23
Brand 3X3j13.713.912.413.814.913.3
X23j187.69193.21153.76190.44222.01176.89j=1JX3j2=1,124.00
Brand 4X4j15.713.714.41613.914.7
X24j246.49187.69207.36256193.21216.09j=1JX4j2=1,306.84
Brand 5X5j13.513.413.212.713.412.3
X25j182.25179.56174.24161.29179.56151.29j=1JX5j2=1,028.19

Thus,

SST=i=1Ij=1JXij21IJX2=(1,130.53+1,533.23+1,124.00+1,306.84+1,028.19)(426.7)230=6,122.79182,072.930=6,122.796,069.096

=53.6937.

Now,

SST=SSTr+SSE.

Thus,

SSE=SSTSSTr=53.693730.88=22.8137.

As a result,

MSE=SSEI(J1)=22.813725=0.91.

Thus, the F-statistic is:

F=MSTrMSE=7.720.91=8.48.

Level of significance:

The level of significance here is α=0.05.

Critical value:

The critical value for the Fν1,ν2 distribution at level of significance α is Fα;ν1,ν2, which is the value of the Fν1,ν2-distribution, the probability above which is α.

Here, the critical value would be F0.05;4,25. From the Table A.9, “Critical Values for F Distributions”, F0.05;4,25=2.76.

P-value:

The P-value is the area to the right of the F-statistic value f, under the Fν1,ν2 distribution curve, that is, P-value=P(Fν1,ν2>f)

Hence, the P-value is P-value=P(F4,25>8.48).

Here, the test statistic value, f=8.48, which is greater than the value 6.49, corresponding to F0.001;4,25, thus, evidently, greater than F0.05;4,25=2.76.

That is, f(=8.48)>F0.001;4,25(=6.49)>F0.05;4,25(=2.76).

Rejection rule:

If the P-value is less than the level of significance α, such that P-value<α, then reject the null hypothesis at level α.

Conclusion:

Here, the P-value is less than 0.001, which is less than the significance level 0.05.

That is, P-value<0.001<0.05.

Thus, the decision is “reject the null hypothesis”.

Therefore, the data provide sufficient evidence to conclude that the effects of all the treatments are not similar.

Thus, the F test reveals at α=0.05 that there is significant difference between the effects of at least two of the hormones on plant growth .

Hence, it is appropriate to use a multiple comparisons method, in order to investigate the differences amongst the means.

Multiple comparisons method- Tukey’s procedure:

For Tukey’s test, first find the value of w=Qα,I,I(J1)MSEJ.

The level of significance is 0.05.

From Table A.10 “Critical Values for Studentized Range Distribution”, the value of Q0.05;5,25 is unavailable. Consider the value Q0.05;5,24=4.17 and Q0.05;5,30=4.10.

It can be observed that at level of significance 0.05, for a particular value of first df, I, the critical value reduces by 0.07(=4.174.10) for increase in the second df, I(J1).

Assuming that the change is approximately uniform over the interval of the two consecutive second df values, 24 and 30, the unitary method gives that for unit increase in the second df from 24 to 25 reduces the critical value by approximately 0.011.

Hence, Q0.05;5,254.158.

The value of w is,

w=4.1580.916=4.158×0.3891.62.

The averages for the brands are arranged in ascending order and their corresponding differences are calculated as:

Brand53142
Mean xi¯13.0813.6713.6814.7315.95
Difference0.590.011.051.22

The difference between means for each pair of consecutive brands is less than w=1.62. Thus, each consecutive pair forms a group.

It is evident the difference between the means for brands 5 and 1 is 0.60(=0.59+0.01) , which is less than w. Thus, brands 5, 3 and 1 form a group.

Now, the difference between the means for brands 5 and 4 is 1.65(=0.59+0.01+1.05) which is greater than w. Evidently, brands 5 and 1 are significantly different. The brand 5 must also be significantly different from the brands with higher means, such as brands 4 and 2.

The difference between brands 3 and 4 is 1.06(=0.01+1.05), which is less than w. Thus, brands 3, 1 and 4 form a group.

The difference between the means for brands 3 and 2 is 2.28(=0.01+1.05+1.22) which is greater than w. Evidently, brands 3 and 2 are significantly different.

Now, the between brands 1 and 2 is 2.27(=1.05+1.22), which is greater than w. Evidently, brands 1 and 2 are significantly different.

Join the consecutive means, whose differences are less than w by a line segment. Discontinue the line segment wherever the difference exceeds w and repeat.

Thus, the following arrangement is found:

    5             3            1            4               213.08      13.67     13.68_      14.73       15.95                                                     _¯                                                                                     ¯

The brands 5, 3 and 1 have similar motor vibrations, brands 5, 3 and 1 have similar motor vibrations, the brands 1 and 4 have similar motor vibrations and the brands 4 and 2 have similar motor vibrations. There is significant difference of brand 5 with brands 4 and 2, and also significant difference between brands 3 and 2.

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