Equivalence Tests

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In a test of equivalence, a treatment mean and a reference mean are compared to each other. Equivalence is taken to be the alternative hypothesis, and the null hypothesis is nonequivalence. The model assumed may be additive or multiplicative. In the additive model (Phillips 1990), the focus is on the difference between the treatment mean and the reference mean, while in the multiplicative model (Diletti, Hauschke, and Steinijans 1991), the focus is on the ratio of the treatment mean to the reference mean.

In the additive model, the null hypothesis is that the difference between the treatment mean and the reference mean is not near zero. That is, the difference is less than the lower equivalence bound or greater than the upper equivalence bound and thus nonequivalent.

The alternative is that the difference is between the equivalence bounds; therefore, the two means are considered to be equivalent.

In the multiplicative model, the null hypothesis is that the ratio of the treatment mean to the reference mean is not near one. That is, the ratio is below the lower equivalence bound or above the upper equivalence bound, and thus the two means are not equivalent. The alternative is that the ratio is between the bounds; thus, the two means are considered to be equivalent.

The power of a test is the probability of rejecting the null hypothesis when the alternative is true. In this case, the power is the probability of accepting equivalence when the treatments are in fact equivalent, that is, the treatment difference or ratio is within the prespecified boundaries.

Often, the null difference is specified to be 0; the null hypothesis is that the treatment difference is less than the lower bound or greater than the upper bound, and the alternative is that the difference is not outside the bounds specified. However, in a case where you suspect that the treatments differ slightly (for example, μ1 = 6, μ2 = 5, μ1 - μ2 = 1), but you want to rule out a larger difference (for example, |μ1 - μ2| > 2) with probability equal to the power you select, you would specify the null difference to be 1 and the lower and upper bounds to be -2 and 2, respectively. Note that the null difference must lie within the bounds you specify.

Requesting Sample Sizes for One Sample In Equivalence

As an example of computing sample sizes for an equivalence test, consider determining sample sizes for an additive model. The coefficient of variation is 0.2, and the null differences of interest are 0, 0.05, 0.10, and 0.15. The significance level under investigation is 0.05, and the power of interest in 0.80. The lower and upper equivalence bounds are -0.2 and 0.2, respectively.

To perform this computation, select

Statistics Sample Size One-Sample Equivalence...

Figure 12.10 displays the resulting dialog. For this analysis, you need to input the model type, null difference, coefficient of variation, and the usual alpha level. In addition, you need to specify the equivalence bounds.

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Figure 12.10: Sample Size Dialog for One-Sample Equivalence

These bounds should be chosen to be the minimum difference so that, if the treatments differed by at least this amount, you would consider them to be different. For the multiplicative model, enter the bioequivalence lower and upper limits. For the additive model, enter the bioequivalence lower and upper limits as percentages of the reference mean and

For the null difference or ratio, specify one or more values for the null hypothesis difference between the treatment and reference means (additive model) or the ratio of means (multiplicative model). The null difference/ratio value must lie within the equivalence bounds you specify. For the additive model, specify the null difference as a percentage of the reference mean , where μT is the hypothesized treatment mean, and μR is the hypothesized reference mean. For the multiplicative model, calculate the null ratio as .

You must also input one or more values for the coefficient of variation (c.v.). For the additive model, enter this as a percentage of the reference mean , which can be estimated by . For the multiplicative model, the coefficient of variation is defined as . You can estimate σ by , where is the residual variance of the logarithmically transformed observations. That is, σ can be estimated by from the ANOVA of the transformed observations.

To produce sample size computations for the preceding problem, follow these steps:

  1. Select N.

  2. Select Additive.

  3. Enter 0, 0.05, 0.10, and 0.15 as values for Null difference:

  4. Enter 0.20 for Coeff of variation:

  5. Enter 0.05 as the Alpha:

  6. Enter 0.80 as the Power:

  7. Enter -0.2 and 0.2 as the values for Lower: and Upper:, respectively, for the Equivalence bounds.

  8. Click OK to perform the analysis.

Figure 12.11 displays the completed dialog.

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Figure 12.11: Sample Size Dialog for One-Sample Equivalence

The results are displayed in Figure 12.12.

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Figure 12.12: Results for One-Sample Equivalence

The results consist of the sample sizes for a power of 0.80 for the values of the null difference, as displayed in Figure 12.12. These results are for the alpha level of 0.05. For a null difference of 0.10, the sample size is 27. For a null difference of 0.15, the sample size jumps to 101.



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SAS Institute - The Analyst Application
The Analyst Application, Second Edition
ISBN: 158025991X
EAN: 2147483647
Year: 2003
Pages: 116

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