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501 lines
20 KiB
Plaintext
501 lines
20 KiB
Plaintext
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[section:cs_eg Chi Squared Distribution Examples]
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[section:chi_sq_intervals Confidence Intervals on the Standard Deviation]
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Once you have calculated the standard deviation for your data, a legitimate
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question to ask is "How reliable is the calculated standard deviation?".
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For this situation the Chi Squared distribution can be used to calculate
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confidence intervals for the standard deviation.
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The full example code & sample output is in
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[@../../example/chi_square_std_dev_test.cpp chi_square_std_dev_test.cpp].
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We'll begin by defining the procedure that will calculate and print out the
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confidence intervals:
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void confidence_limits_on_std_deviation(
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double Sd, // Sample Standard Deviation
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unsigned N) // Sample size
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{
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We'll begin by printing out some general information:
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cout <<
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"________________________________________________\n"
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"2-Sided Confidence Limits For Standard Deviation\n"
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"________________________________________________\n\n";
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cout << setprecision(7);
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cout << setw(40) << left << "Number of Observations" << "= " << N << "\n";
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cout << setw(40) << left << "Standard Deviation" << "= " << Sd << "\n";
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and then define a table of significance levels for which we'll calculate
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intervals:
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double alpha[] = { 0.5, 0.25, 0.1, 0.05, 0.01, 0.001, 0.0001, 0.00001 };
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The distribution we'll need to calculate the confidence intervals is a
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Chi Squared distribution, with N-1 degrees of freedom:
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chi_squared dist(N - 1);
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For each value of alpha, the formula for the confidence interval is given by:
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[equation chi_squ_tut1]
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Where [equation chi_squ_tut2] is the upper critical value, and
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[equation chi_squ_tut3] is the lower critical value of the
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Chi Squared distribution.
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In code we begin by printing out a table header:
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cout << "\n\n"
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"_____________________________________________\n"
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"Confidence Lower Upper\n"
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" Value (%) Limit Limit\n"
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"_____________________________________________\n";
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and then loop over the values of alpha and calculate the intervals
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for each: remember that the lower critical value is the same as the
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quantile, and the upper critical value is the same as the quantile
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from the complement of the probability:
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for(unsigned i = 0; i < sizeof(alpha)/sizeof(alpha[0]); ++i)
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{
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// Confidence value:
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cout << fixed << setprecision(3) << setw(10) << right << 100 * (1-alpha[i]);
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// Calculate limits:
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double lower_limit = sqrt((N - 1) * Sd * Sd / quantile(complement(dist, alpha[i] / 2)));
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double upper_limit = sqrt((N - 1) * Sd * Sd / quantile(dist, alpha[i] / 2));
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// Print Limits:
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cout << fixed << setprecision(5) << setw(15) << right << lower_limit;
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cout << fixed << setprecision(5) << setw(15) << right << upper_limit << endl;
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}
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cout << endl;
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To see some example output we'll use the
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[@http://www.itl.nist.gov/div898/handbook/eda/section3/eda3581.htm
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gear data] from the __handbook.
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The data represents measurements of gear diameter from a manufacturing
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process.
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[pre'''
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________________________________________________
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2-Sided Confidence Limits For Standard Deviation
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________________________________________________
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Number of Observations = 100
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Standard Deviation = 0.006278908
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_____________________________________________
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Confidence Lower Upper
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Value (%) Limit Limit
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_____________________________________________
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50.000 0.00601 0.00662
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75.000 0.00582 0.00685
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90.000 0.00563 0.00712
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95.000 0.00551 0.00729
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99.000 0.00530 0.00766
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99.900 0.00507 0.00812
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99.990 0.00489 0.00855
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99.999 0.00474 0.00895
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''']
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So at the 95% confidence level we conclude that the standard deviation
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is between 0.00551 and 0.00729.
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[h4 Confidence intervals as a function of the number of observations]
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Similarly, we can also list the confidence intervals for the standard deviation
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for the common confidence levels 95%, for increasing numbers of observations.
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The standard deviation used to compute these values is unity,
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so the limits listed are *multipliers* for any particular standard deviation.
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For example, given a standard deviation of 0.0062789 as in the example
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above; for 100 observations the multiplier is 0.8780
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giving the lower confidence limit of 0.8780 * 0.006728 = 0.00551.
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[pre'''
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____________________________________________________
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Confidence level (two-sided) = 0.0500000
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Standard Deviation = 1.0000000
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________________________________________
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Observations Lower Upper
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Limit Limit
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________________________________________
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2 0.4461 31.9102
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3 0.5207 6.2847
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4 0.5665 3.7285
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5 0.5991 2.8736
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6 0.6242 2.4526
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7 0.6444 2.2021
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8 0.6612 2.0353
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9 0.6755 1.9158
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10 0.6878 1.8256
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15 0.7321 1.5771
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20 0.7605 1.4606
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30 0.7964 1.3443
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40 0.8192 1.2840
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50 0.8353 1.2461
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60 0.8476 1.2197
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100 0.8780 1.1617
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120 0.8875 1.1454
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1000 0.9580 1.0459
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10000 0.9863 1.0141
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50000 0.9938 1.0062
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100000 0.9956 1.0044
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1000000 0.9986 1.0014
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''']
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With just 2 observations the limits are from *0.445* up to to *31.9*,
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so the standard deviation might be about *half*
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the observed value up to [*30 times] the observed value!
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Estimating a standard deviation with just a handful of values leaves a very great uncertainty,
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especially the upper limit.
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Note especially how far the upper limit is skewed from the most likely standard deviation.
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Even for 10 observations, normally considered a reasonable number,
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the range is still from 0.69 to 1.8, about a range of 0.7 to 2,
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and is still highly skewed with an upper limit *twice* the median.
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When we have 1000 observations, the estimate of the standard deviation is starting to look convincing,
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with a range from 0.95 to 1.05 - now near symmetrical, but still about + or - 5%.
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Only when we have 10000 or more repeated observations can we start to be reasonably confident
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(provided we are sure that other factors like drift are not creeping in).
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For 10000 observations, the interval is 0.99 to 1.1 - finally a really convincing + or -1% confidence.
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[endsect] [/section:chi_sq_intervals Confidence Intervals on the Standard Deviation]
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[section:chi_sq_test Chi-Square Test for the Standard Deviation]
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We use this test to determine whether the standard deviation of a sample
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differs from a specified value. Typically this occurs in process change
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situations where we wish to compare the standard deviation of a new
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process to an established one.
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The code for this example is contained in
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[@../../example/chi_square_std_dev_test.cpp chi_square_std_dev_test.cpp], and
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we'll begin by defining the procedure that will print out the test
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statistics:
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void chi_squared_test(
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double Sd, // Sample std deviation
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double D, // True std deviation
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unsigned N, // Sample size
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double alpha) // Significance level
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{
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The procedure begins by printing a summary of the input data:
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using namespace std;
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using namespace boost::math;
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// Print header:
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cout <<
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"______________________________________________\n"
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"Chi Squared test for sample standard deviation\n"
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"______________________________________________\n\n";
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cout << setprecision(5);
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cout << setw(55) << left << "Number of Observations" << "= " << N << "\n";
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cout << setw(55) << left << "Sample Standard Deviation" << "= " << Sd << "\n";
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cout << setw(55) << left << "Expected True Standard Deviation" << "= " << D << "\n\n";
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The test statistic (T) is simply the ratio of the sample and "true" standard
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deviations squared, multiplied by the number of degrees of freedom (the
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sample size less one):
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double t_stat = (N - 1) * (Sd / D) * (Sd / D);
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cout << setw(55) << left << "Test Statistic" << "= " << t_stat << "\n";
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The distribution we need to use, is a Chi Squared distribution with N-1
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degrees of freedom:
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chi_squared dist(N - 1);
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The various hypothesis that can be tested are summarised in the following table:
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[table
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[[Hypothesis][Test]]
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[[The null-hypothesis: there is no difference in standard deviation from the specified value]
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[ Reject if T < [chi][super 2][sub (1-alpha/2; N-1)] or T > [chi][super 2][sub (alpha/2; N-1)] ]]
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[[The alternative hypothesis: there is a difference in standard deviation from the specified value]
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[ Reject if [chi][super 2][sub (1-alpha/2; N-1)] >= T >= [chi][super 2][sub (alpha/2; N-1)] ]]
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[[The alternative hypothesis: the standard deviation is less than the specified value]
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[ Reject if [chi][super 2][sub (1-alpha; N-1)] <= T ]]
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[[The alternative hypothesis: the standard deviation is greater than the specified value]
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[ Reject if [chi][super 2][sub (alpha; N-1)] >= T ]]
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]
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Where [chi][super 2][sub (alpha; N-1)] is the upper critical value of the
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Chi Squared distribution, and [chi][super 2][sub (1-alpha; N-1)] is the
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lower critical value.
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Recall that the lower critical value is the same
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as the quantile, and the upper critical value is the same as the quantile
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from the complement of the probability, that gives us the following code
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to calculate the critical values:
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double ucv = quantile(complement(dist, alpha));
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double ucv2 = quantile(complement(dist, alpha / 2));
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double lcv = quantile(dist, alpha);
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double lcv2 = quantile(dist, alpha / 2);
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cout << setw(55) << left << "Upper Critical Value at alpha: " << "= "
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<< setprecision(3) << scientific << ucv << "\n";
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cout << setw(55) << left << "Upper Critical Value at alpha/2: " << "= "
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<< setprecision(3) << scientific << ucv2 << "\n";
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cout << setw(55) << left << "Lower Critical Value at alpha: " << "= "
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<< setprecision(3) << scientific << lcv << "\n";
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cout << setw(55) << left << "Lower Critical Value at alpha/2: " << "= "
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<< setprecision(3) << scientific << lcv2 << "\n\n";
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Now that we have the critical values, we can compare these to our test
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statistic, and print out the result of each hypothesis and test:
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cout << setw(55) << left <<
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"Results for Alternative Hypothesis and alpha" << "= "
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<< setprecision(4) << fixed << alpha << "\n\n";
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cout << "Alternative Hypothesis Conclusion\n";
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cout << "Standard Deviation != " << setprecision(3) << fixed << D << " ";
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if((ucv2 < t_stat) || (lcv2 > t_stat))
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cout << "ACCEPTED\n";
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else
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cout << "REJECTED\n";
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cout << "Standard Deviation < " << setprecision(3) << fixed << D << " ";
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if(lcv > t_stat)
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cout << "ACCEPTED\n";
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else
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cout << "REJECTED\n";
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cout << "Standard Deviation > " << setprecision(3) << fixed << D << " ";
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if(ucv < t_stat)
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cout << "ACCEPTED\n";
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else
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cout << "REJECTED\n";
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cout << endl << endl;
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To see some example output we'll use the
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[@http://www.itl.nist.gov/div898/handbook/eda/section3/eda3581.htm
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gear data] from the __handbook.
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The data represents measurements of gear diameter from a manufacturing
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process. The program output is deliberately designed to mirror
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the DATAPLOT output shown in the
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[@http://www.itl.nist.gov/div898/handbook/eda/section3/eda358.htm
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NIST Handbook Example].
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[pre'''
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______________________________________________
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Chi Squared test for sample standard deviation
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______________________________________________
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Number of Observations = 100
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Sample Standard Deviation = 0.00628
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Expected True Standard Deviation = 0.10000
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Test Statistic = 0.39030
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CDF of test statistic: = 1.438e-099
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Upper Critical Value at alpha: = 1.232e+002
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Upper Critical Value at alpha/2: = 1.284e+002
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Lower Critical Value at alpha: = 7.705e+001
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Lower Critical Value at alpha/2: = 7.336e+001
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Results for Alternative Hypothesis and alpha = 0.0500
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Alternative Hypothesis Conclusion'''
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Standard Deviation != 0.100 ACCEPTED
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Standard Deviation < 0.100 ACCEPTED
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Standard Deviation > 0.100 REJECTED
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]
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In this case we are testing whether the sample standard deviation is 0.1,
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and the null-hypothesis is rejected, so we conclude that the standard
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deviation ['is not] 0.1.
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For an alternative example, consider the
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[@http://www.itl.nist.gov/div898/handbook/prc/section2/prc23.htm
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silicon wafer data] again from the __handbook.
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In this scenario a supplier of 100 ohm.cm silicon wafers claims
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that his fabrication process can produce wafers with sufficient
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consistency so that the standard deviation of resistivity for
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the lot does not exceed 10 ohm.cm. A sample of N = 10 wafers taken
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from the lot has a standard deviation of 13.97 ohm.cm, and the question
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we ask ourselves is "Is the suppliers claim correct?".
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The program output now looks like this:
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[pre'''
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______________________________________________
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Chi Squared test for sample standard deviation
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______________________________________________
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Number of Observations = 10
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Sample Standard Deviation = 13.97000
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Expected True Standard Deviation = 10.00000
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Test Statistic = 17.56448
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CDF of test statistic: = 9.594e-001
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Upper Critical Value at alpha: = 1.692e+001
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Upper Critical Value at alpha/2: = 1.902e+001
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Lower Critical Value at alpha: = 3.325e+000
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Lower Critical Value at alpha/2: = 2.700e+000
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Results for Alternative Hypothesis and alpha = 0.0500
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Alternative Hypothesis Conclusion'''
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Standard Deviation != 10.000 REJECTED
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Standard Deviation < 10.000 REJECTED
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Standard Deviation > 10.000 ACCEPTED
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]
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In this case, our null-hypothesis is that the standard deviation of
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the sample is less than 10: this hypothesis is rejected in the analysis
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above, and so we reject the manufacturers claim.
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[endsect] [/section:chi_sq_test Chi-Square Test for the Standard Deviation]
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[section:chi_sq_size Estimating the Required Sample Sizes for a Chi-Square Test for the Standard Deviation]
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Suppose we conduct a Chi Squared test for standard deviation and the result
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is borderline, a legitimate question to ask is "How large would the sample size
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have to be in order to produce a definitive result?"
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The class template [link math_toolkit.dist_ref.dists.chi_squared_dist
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chi_squared_distribution] has a static method
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`find_degrees_of_freedom` that will calculate this value for
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some acceptable risk of type I failure /alpha/, type II failure
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/beta/, and difference from the standard deviation /diff/. Please
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note that the method used works on variance, and not standard deviation
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as is usual for the Chi Squared Test.
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The code for this example is located in
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[@../../example/chi_square_std_dev_test.cpp chi_square_std_dev_test.cpp].
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We begin by defining a procedure to print out the sample sizes required
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for various risk levels:
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void chi_squared_sample_sized(
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double diff, // difference from variance to detect
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double variance) // true variance
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{
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The procedure begins by printing out the input data:
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using namespace std;
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using namespace boost::math;
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// Print out general info:
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cout <<
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"_____________________________________________________________\n"
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"Estimated sample sizes required for various confidence levels\n"
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"_____________________________________________________________\n\n";
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cout << setprecision(5);
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cout << setw(40) << left << "True Variance" << "= " << variance << "\n";
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cout << setw(40) << left << "Difference to detect" << "= " << diff << "\n";
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And defines a table of significance levels for which we'll calculate sample sizes:
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double alpha[] = { 0.5, 0.25, 0.1, 0.05, 0.01, 0.001, 0.0001, 0.00001 };
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For each value of alpha we can calculate two sample sizes: one where the
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sample variance is less than the true value by /diff/ and one
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where it is greater than the true value by /diff/. Thanks to the
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asymmetric nature of the Chi Squared distribution these two values will
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not be the same, the difference in their calculation differs only in the
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sign of /diff/ that's passed to `find_degrees_of_freedom`. Finally
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in this example we'll simply things, and let risk level /beta/ be the
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same as /alpha/:
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cout << "\n\n"
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"_______________________________________________________________\n"
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"Confidence Estimated Estimated\n"
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" Value (%) Sample Size Sample Size\n"
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" (lower one (upper one\n"
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" sided test) sided test)\n"
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"_______________________________________________________________\n";
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//
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// Now print out the data for the table rows.
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//
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for(unsigned i = 0; i < sizeof(alpha)/sizeof(alpha[0]); ++i)
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{
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// Confidence value:
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cout << fixed << setprecision(3) << setw(10) << right << 100 * (1-alpha[i]);
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// calculate df for a lower single sided test:
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double df = chi_squared::find_degrees_of_freedom(
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-diff, alpha[i], alpha[i], variance);
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// convert to sample size:
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double size = ceil(df) + 1;
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// Print size:
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cout << fixed << setprecision(0) << setw(16) << right << size;
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// calculate df for an upper single sided test:
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df = chi_squared::find_degrees_of_freedom(
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diff, alpha[i], alpha[i], variance);
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// convert to sample size:
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size = ceil(df) + 1;
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// Print size:
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cout << fixed << setprecision(0) << setw(16) << right << size << endl;
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}
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cout << endl;
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For some example output, consider the
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[@http://www.itl.nist.gov/div898/handbook/prc/section2/prc23.htm
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silicon wafer data] from the __handbook.
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In this scenario a supplier of 100 ohm.cm silicon wafers claims
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that his fabrication process can produce wafers with sufficient
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consistency so that the standard deviation of resistivity for
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the lot does not exceed 10 ohm.cm. A sample of N = 10 wafers taken
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from the lot has a standard deviation of 13.97 ohm.cm, and the question
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we ask ourselves is "How large would our sample have to be to reliably
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detect this difference?".
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To use our procedure above, we have to convert the
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standard deviations to variance (square them),
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after which the program output looks like this:
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[pre'''
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_____________________________________________________________
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Estimated sample sizes required for various confidence levels
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_____________________________________________________________
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True Variance = 100.00000
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Difference to detect = 95.16090
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_______________________________________________________________
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Confidence Estimated Estimated
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Value (%) Sample Size Sample Size
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(lower one (upper one
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sided test) sided test)
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_______________________________________________________________
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50.000 2 2
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75.000 2 10
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90.000 4 32
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95.000 5 51
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99.000 7 99
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99.900 11 174
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99.990 15 251
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99.999 20 330'''
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]
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In this case we are interested in a upper single sided test.
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So for example, if the maximum acceptable risk of falsely rejecting
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the null-hypothesis is 0.05 (Type I error), and the maximum acceptable
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risk of failing to reject the null-hypothesis is also 0.05
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(Type II error), we estimate that we would need a sample size of 51.
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[endsect] [/section:chi_sq_size Estimating the Required Sample Sizes for a Chi-Square Test for the Standard Deviation]
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[endsect] [/section:cs_eg Chi Squared Distribution]
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[/
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Copyright 2006, 2013 John Maddock and Paul A. Bristow.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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|