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333 lines
13 KiB
Plaintext
333 lines
13 KiB
Plaintext
[section:binom_eg Binomial Distribution Examples]
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See also the reference documentation for the __binomial_distrib.
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[section:binomial_coinflip_example Binomial Coin-Flipping Example]
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[import ../../example/binomial_coinflip_example.cpp]
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[binomial_coinflip_example1]
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See [@../../example/binomial_coinflip_example.cpp binomial_coinflip_example.cpp]
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for full source code, the program output looks like this:
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[binomial_coinflip_example_output]
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[endsect] [/section:binomial_coinflip_example Binomial coinflip example]
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[section:binomial_quiz_example Binomial Quiz Example]
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[import ../../example/binomial_quiz_example.cpp]
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[binomial_quiz_example1]
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[binomial_quiz_example2]
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[discrete_quantile_real]
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See [@../../example/binomial_quiz_example.cpp binomial_quiz_example.cpp]
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for full source code and output.
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[endsect] [/section:binomial_coinflip_quiz Binomial Coin-Flipping example]
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[section:binom_conf Calculating Confidence Limits on the Frequency of Occurrence for a Binomial Distribution]
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Imagine you have a process that follows a binomial distribution: for each
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trial conducted, an event either occurs or does it does not, referred
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to as "successes" and "failures". If, by experiment, you want to measure the
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frequency with which successes occur, the best estimate is given simply
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by /k/ \/ /N/, for /k/ successes out of /N/ trials. However our confidence in that
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estimate will be shaped by how many trials were conducted, and how many successes
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were observed. The static member functions
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`binomial_distribution<>::find_lower_bound_on_p` and
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`binomial_distribution<>::find_upper_bound_on_p` allow you to calculate
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the confidence intervals for your estimate of the occurrence frequency.
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The sample program [@../../example/binomial_confidence_limits.cpp
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binomial_confidence_limits.cpp] illustrates their use. It begins by defining
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a procedure that will print a table of confidence limits for various degrees
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of certainty:
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#include <iostream>
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#include <iomanip>
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#include <boost/math/distributions/binomial.hpp>
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void confidence_limits_on_frequency(unsigned trials, unsigned successes)
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{
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//
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// trials = Total number of trials.
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// successes = Total number of observed successes.
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//
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// Calculate confidence limits for an observed
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// frequency of occurrence that follows a binomial
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// distribution.
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//
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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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"2-Sided Confidence Limits For Success Ratio\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" << "= " << trials << "\n";
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cout << setw(40) << left << "Number of successes" << "= " << successes << "\n";
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cout << setw(40) << left << "Sample frequency of occurrence" << "= " << double(successes) / trials << "\n";
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The procedure now defines a table of significance levels: these are the
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probabilities that the true occurrence frequency lies outside the calculated
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interval:
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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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Some pretty printing of the table header follows:
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cout << "\n\n"
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"_______________________________________________________________________\n"
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"Confidence Lower CP Upper CP Lower JP Upper JP\n"
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" Value (%) Limit Limit Limit Limit\n"
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"_______________________________________________________________________\n";
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And now for the important part - the intervals themselves - for each
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value of /alpha/, we call `find_lower_bound_on_p` and
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`find_lower_upper_on_p` to obtain lower and upper bounds
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respectively. Note that since we are calculating a two-sided interval,
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we must divide the value of alpha in two.
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Please note that calculating two separate /single sided bounds/, each with risk
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level [alpha][space]is not the same thing as calculating a two sided interval.
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Had we calculate two single-sided intervals each with a risk
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that the true value is outside the interval of [alpha], then:
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* The risk that it is less than the lower bound is [alpha].
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and
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* The risk that it is greater than the upper bound is also [alpha].
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So the risk it is outside *upper or lower bound*, is *twice* alpha, and the
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probability that it is inside the bounds is therefore not nearly as high as
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one might have thought. This is why [alpha]/2 must be used in
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the calculations below.
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In contrast, had we been calculating a
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single-sided interval, for example: ['"Calculate a lower bound so that we are P%
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sure that the true occurrence frequency is greater than some value"]
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then we would *not* have divided by two.
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Finally note that `binomial_distribution` provides a choice of two
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methods for the calculation, we print out the results from both
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methods in this example:
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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 Clopper Pearson bounds:
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double l = binomial_distribution<>::find_lower_bound_on_p(
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trials, successes, alpha[i]/2);
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double u = binomial_distribution<>::find_upper_bound_on_p(
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trials, successes, alpha[i]/2);
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// Print Clopper Pearson Limits:
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cout << fixed << setprecision(5) << setw(15) << right << l;
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cout << fixed << setprecision(5) << setw(15) << right << u;
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// Calculate Jeffreys Prior Bounds:
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l = binomial_distribution<>::find_lower_bound_on_p(
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trials, successes, alpha[i]/2,
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binomial_distribution<>::jeffreys_prior_interval);
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u = binomial_distribution<>::find_upper_bound_on_p(
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trials, successes, alpha[i]/2,
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binomial_distribution<>::jeffreys_prior_interval);
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// Print Jeffreys Prior Limits:
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cout << fixed << setprecision(5) << setw(15) << right << l;
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cout << fixed << setprecision(5) << setw(15) << right << u << std::endl;
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}
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cout << endl;
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}
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And that's all there is to it. Let's see some sample output for a 2 in 10
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success ratio, first for 20 trials:
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[pre'''___________________________________________
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2-Sided Confidence Limits For Success Ratio
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___________________________________________
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Number of Observations = 20
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Number of successes = 4
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Sample frequency of occurrence = 0.2
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_______________________________________________________________________
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Confidence Lower CP Upper CP Lower JP Upper JP
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Value (%) Limit Limit Limit Limit
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_______________________________________________________________________
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50.000 0.12840 0.29588 0.14974 0.26916
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75.000 0.09775 0.34633 0.11653 0.31861
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90.000 0.07135 0.40103 0.08734 0.37274
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95.000 0.05733 0.43661 0.07152 0.40823
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99.000 0.03576 0.50661 0.04655 0.47859
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99.900 0.01905 0.58632 0.02634 0.55960
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99.990 0.01042 0.64997 0.01530 0.62495
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99.999 0.00577 0.70216 0.00901 0.67897
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''']
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As you can see, even at the 95% confidence level the bounds are
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really quite wide (this example is chosen to be easily compared to the one
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in the __handbook
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[@http://www.itl.nist.gov/div898/handbook/prc/section2/prc241.htm
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here]). Note also that the Clopper-Pearson calculation method (CP above)
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produces quite noticeably more pessimistic estimates than the Jeffreys Prior
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method (JP above).
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Compare that with the program output for
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2000 trials:
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[pre'''___________________________________________
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2-Sided Confidence Limits For Success Ratio
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___________________________________________
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Number of Observations = 2000
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Number of successes = 400
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Sample frequency of occurrence = 0.2000000
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_______________________________________________________________________
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Confidence Lower CP Upper CP Lower JP Upper JP
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Value (%) Limit Limit Limit Limit
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_______________________________________________________________________
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50.000 0.19382 0.20638 0.19406 0.20613
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75.000 0.18965 0.21072 0.18990 0.21047
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90.000 0.18537 0.21528 0.18561 0.21503
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95.000 0.18267 0.21821 0.18291 0.21796
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99.000 0.17745 0.22400 0.17769 0.22374
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99.900 0.17150 0.23079 0.17173 0.23053
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99.990 0.16658 0.23657 0.16681 0.23631
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99.999 0.16233 0.24169 0.16256 0.24143
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''']
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Now even when the confidence level is very high, the limits are really
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quite close to the experimentally calculated value of 0.2. Furthermore
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the difference between the two calculation methods is now really quite small.
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[endsect]
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[section:binom_size_eg Estimating Sample Sizes for a Binomial Distribution.]
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Imagine you have a critical component that you know will fail in 1 in
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N "uses" (for some suitable definition of "use"). You may want to schedule
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routine replacement of the component so that its chance of failure between
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routine replacements is less than P%. If the failures follow a binomial
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distribution (each time the component is "used" it either fails or does not)
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then the static member function `binomial_distibution<>::find_maximum_number_of_trials`
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can be used to estimate the maximum number of "uses" of that component for some
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acceptable risk level /alpha/.
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The example program
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[@../../example/binomial_sample_sizes.cpp binomial_sample_sizes.cpp]
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demonstrates its usage. It centres on a routine that prints out
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a table of maximum sample sizes for various probability thresholds:
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void find_max_sample_size(
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double p, // success ratio.
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unsigned successes) // Total number of observed successes permitted.
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{
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The routine then declares a table of probability thresholds: these are the
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maximum acceptable probability that /successes/ or fewer events will be
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observed. In our example, /successes/ will be always zero, since we want
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no component failures, but in other situations non-zero values may well
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make sense.
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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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Much of the rest of the program is pretty-printing, the important part
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is in the calculation of maximum number of permitted trials for each
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value of alpha:
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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 trials:
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double t = binomial::find_maximum_number_of_trials(
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successes, p, alpha[i]);
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t = floor(t);
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// Print Trials:
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cout << fixed << setprecision(5) << setw(15) << right << t << endl;
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}
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Note that since we're
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calculating the maximum number of trials permitted, we'll err on the safe
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side and take the floor of the result. Had we been calculating the
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/minimum/ number of trials required to observe a certain number of /successes/
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using `find_minimum_number_of_trials` we would have taken the ceiling instead.
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We'll finish off by looking at some sample output, firstly for
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a 1 in 1000 chance of component failure with each use:
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[pre
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'''________________________
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Maximum Number of Trials
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________________________
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Success ratio = 0.001
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Maximum Number of "successes" permitted = 0
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____________________________
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Confidence Max Number
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Value (%) Of Trials
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____________________________
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50.000 692
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75.000 287
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90.000 105
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95.000 51
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99.000 10
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99.900 0
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99.990 0
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99.999 0'''
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]
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So 51 "uses" of the component would yield a 95% chance that no
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component failures would be observed.
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Compare that with a 1 in 1 million chance of component failure:
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[pre'''
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________________________
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Maximum Number of Trials
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________________________
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Success ratio = 0.0000010
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Maximum Number of "successes" permitted = 0
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____________________________
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Confidence Max Number
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Value (%) Of Trials
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____________________________
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50.000 693146
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75.000 287681
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90.000 105360
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95.000 51293
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99.000 10050
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99.900 1000
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99.990 100
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99.999 10'''
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]
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In this case, even 1000 uses of the component would still yield a
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less than 1 in 1000 chance of observing a component failure
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(i.e. a 99.9% chance of no failure).
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[endsect] [/section:binom_size_eg Estimating Sample Sizes for a Binomial Distribution.]
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[endsect][/section:binom_eg Binomial Distribution]
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[/
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Copyright 2006 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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