WSJT-X/boost/libs/math/example/neg_binom_confidence_limits.cpp

// neg_binomial_confidence_limits.cpp

// Copyright John Maddock 2006
// Copyright Paul A. Bristow 2007, 2010
// Use, modification and distribution are subject to the
// Boost Software License, Version 1.0.
// (See accompanying file LICENSE_1_0.txt
// or copy at http://www.boost.org/LICENSE_1_0.txt)

// Caution: this file contains quickbook markup as well as code
// and comments, don't change any of the special comment markups!

//[neg_binomial_confidence_limits

/*`

First we need some includes to access the negative binomial distribution
(and some basic std output of course).

*/

#include <boost/math/distributions/negative_binomial.hpp>
using boost::math::negative_binomial;

#include <iostream>
using std::cout; using std::endl;
#include <iomanip>
using std::setprecision;
using std::setw; using std::left; using std::fixed; using std::right;

/*`
First define a table of significance levels: these are the 
probabilities that the true occurrence frequency lies outside the calculated
interval:
*/

  double alpha[] = { 0.5, 0.25, 0.1, 0.05, 0.01, 0.001, 0.0001, 0.00001 };

/*`
Confidence value as % is (1 - alpha) * 100, so alpha 0.05 == 95% confidence
that the true occurrence frequency lies *inside* the calculated interval.

We need a function to calculate and print confidence limits
for an observed frequency of occurrence 
that follows a negative binomial distribution.

*/

void confidence_limits_on_frequency(unsigned trials, unsigned successes)
{
   // trials = Total number of trials.
   // successes = Total number of observed successes.
   // failures = trials - successes.
   // success_fraction = successes /trials.
   // Print out general info:
   cout <<
      "______________________________________________\n"
      "2-Sided Confidence Limits For Success Fraction\n"
      "______________________________________________\n\n";
   cout << setprecision(7);
   cout << setw(40) << left << "Number of trials" << " =  " << trials << "\n";
   cout << setw(40) << left << "Number of successes" << " =  " << successes << "\n";
   cout << setw(40) << left << "Number of failures" << " =  " << trials - successes << "\n";
   cout << setw(40) << left << "Observed frequency of occurrence" << " =  " << double(successes) / trials << "\n";

   // Print table header:
   cout << "\n\n"
           "___________________________________________\n"
           "Confidence        Lower          Upper\n"
           " Value (%)        Limit          Limit\n"
           "___________________________________________\n";


/*`
And now for the important part - the bounds themselves.
For each value of /alpha/, we call `find_lower_bound_on_p` and 
`find_upper_bound_on_p` to obtain lower and upper bounds respectively. 
Note that since we are calculating a two-sided interval,
we must divide the value of alpha in two.  Had we been calculating a 
single-sided interval, for example: ['"Calculate a lower bound so that we are P%
sure that the true occurrence frequency is greater than some value"]
then we would *not* have divided by two.
*/

   // Now print out the upper and lower limits for the alpha table values.
   for(unsigned i = 0; i < sizeof(alpha)/sizeof(alpha[0]); ++i)
   {
      // Confidence value:
      cout << fixed << setprecision(3) << setw(10) << right << 100 * (1-alpha[i]);
      // Calculate bounds:
      double lower = negative_binomial::find_lower_bound_on_p(trials, successes, alpha[i]/2);
      double upper = negative_binomial::find_upper_bound_on_p(trials, successes, alpha[i]/2);
      // Print limits:
      cout << fixed << setprecision(5) << setw(15) << right << lower;
      cout << fixed << setprecision(5) << setw(15) << right << upper << endl;
   }
   cout << endl;
} // void confidence_limits_on_frequency(unsigned trials, unsigned successes)

/*`

And then call confidence_limits_on_frequency with increasing numbers of trials,
but always the same success fraction 0.1, or 1 in 10.

*/

int main()
{
  confidence_limits_on_frequency(20, 2); // 20 trials, 2 successes, 2 in 20, = 1 in 10 = 0.1 success fraction.
  confidence_limits_on_frequency(200, 20); // More trials, but same 0.1 success fraction.
  confidence_limits_on_frequency(2000, 200); // Many more trials, but same 0.1 success fraction.

  return 0;
} // int main()

//] [/negative_binomial_confidence_limits_eg end of Quickbook in C++ markup]

/*

______________________________________________
2-Sided Confidence Limits For Success Fraction
______________________________________________
Number of trials                         =  20
Number of successes                      =  2
Number of failures                       =  18
Observed frequency of occurrence         =  0.1
___________________________________________
Confidence        Lower          Upper
 Value (%)        Limit          Limit
___________________________________________
    50.000        0.04812        0.13554
    75.000        0.03078        0.17727
    90.000        0.01807        0.22637
    95.000        0.01235        0.26028
    99.000        0.00530        0.33111
    99.900        0.00164        0.41802
    99.990        0.00051        0.49202
    99.999        0.00016        0.55574
______________________________________________
2-Sided Confidence Limits For Success Fraction
______________________________________________
Number of trials                         =  200
Number of successes                      =  20
Number of failures                       =  180
Observed frequency of occurrence         =  0.1000000
___________________________________________
Confidence        Lower          Upper
 Value (%)        Limit          Limit
___________________________________________
    50.000        0.08462        0.11350
    75.000        0.07580        0.12469
    90.000        0.06726        0.13695
    95.000        0.06216        0.14508
    99.000        0.05293        0.16170
    99.900        0.04343        0.18212
    99.990        0.03641        0.20017
    99.999        0.03095        0.21664
______________________________________________
2-Sided Confidence Limits For Success Fraction
______________________________________________
Number of trials                         =  2000
Number of successes                      =  200
Number of failures                       =  1800
Observed frequency of occurrence         =  0.1000000
___________________________________________
Confidence        Lower          Upper
 Value (%)        Limit          Limit
___________________________________________
    50.000        0.09536        0.10445
    75.000        0.09228        0.10776
    90.000        0.08916        0.11125
    95.000        0.08720        0.11352
    99.000        0.08344        0.11802
    99.900        0.07921        0.12336
    99.990        0.07577        0.12795
    99.999        0.07282        0.13206
*/
Squashed 'boost/' content from commit b4feb19f2 git-subtree-dir: boost git-subtree-split: b4feb19f287ee92d87a9624b5d36b7cf46aeadeb 2018-06-09 16:48:32 -04:00			`// neg_binomial_confidence_limits.cpp`

			`// Copyright John Maddock 2006`
			`// Copyright Paul A. Bristow 2007, 2010`
			`// Use, modification and distribution are subject to the`
			`// Boost Software License, Version 1.0.`
			`// (See accompanying file LICENSE_1_0.txt`
			`// or copy at http://www.boost.org/LICENSE_1_0.txt)`

			`// Caution: this file contains quickbook markup as well as code`
			`// and comments, don't change any of the special comment markups!`

			`//[neg_binomial_confidence_limits`

			/*`

			`First we need some includes to access the negative binomial distribution`
			`(and some basic std output of course).`

			`*/`

			`#include <boost/math/distributions/negative_binomial.hpp>`
			`using boost::math::negative_binomial;`

			`#include <iostream>`
			`using std::cout; using std::endl;`
			`#include <iomanip>`
			`using std::setprecision;`
			`using std::setw; using std::left; using std::fixed; using std::right;`

			/*`
			`First define a table of significance levels: these are the`
			`probabilities that the true occurrence frequency lies outside the calculated`
			`interval:`
			`*/`

			`double alpha[] = { 0.5, 0.25, 0.1, 0.05, 0.01, 0.001, 0.0001, 0.00001 };`

			/*`
			`Confidence value as % is (1 - alpha) * 100, so alpha 0.05 == 95% confidence`
			`that the true occurrence frequency lies inside the calculated interval.`

			`We need a function to calculate and print confidence limits`
			`for an observed frequency of occurrence`
			`that follows a negative binomial distribution.`

			`*/`

			`void confidence_limits_on_frequency(unsigned trials, unsigned successes)`
			`{`
			`// trials = Total number of trials.`
			`// successes = Total number of observed successes.`
			`// failures = trials - successes.`
			`// success_fraction = successes /trials.`
			`// Print out general info:`
			`cout <<`
			`"______________________________________________\n"`
			`"2-Sided Confidence Limits For Success Fraction\n"`
			`"______________________________________________\n\n";`
			`cout << setprecision(7);`
			`cout << setw(40) << left << "Number of trials" << " = " << trials << "\n";`
			`cout << setw(40) << left << "Number of successes" << " = " << successes << "\n";`
			`cout << setw(40) << left << "Number of failures" << " = " << trials - successes << "\n";`
			`cout << setw(40) << left << "Observed frequency of occurrence" << " = " << double(successes) / trials << "\n";`

			`// Print table header:`
			`cout << "\n\n"`
			`"___________________________________________\n"`
			`"Confidence Lower Upper\n"`
			`" Value (%) Limit Limit\n"`
			`"___________________________________________\n";`


			/*`
			`And now for the important part - the bounds themselves.`
			For each value of /alpha/, we call `find_lower_bound_on_p` and
			`find_upper_bound_on_p` to obtain lower and upper bounds respectively.
			`Note that since we are calculating a two-sided interval,`
			`we must divide the value of alpha in two. Had we been calculating a`
			`single-sided interval, for example: ['"Calculate a lower bound so that we are P%`
			`sure that the true occurrence frequency is greater than some value"]`
			`then we would not have divided by two.`
			`*/`

			`// Now print out the upper and lower limits for the alpha table values.`
			`for(unsigned i = 0; i < sizeof(alpha)/sizeof(alpha[0]); ++i)`
			`{`
			`// Confidence value:`
			`cout << fixed << setprecision(3) << setw(10) << right << 100 * (1-alpha[i]);`
			`// Calculate bounds:`
			`double lower = negative_binomial::find_lower_bound_on_p(trials, successes, alpha[i]/2);`
			`double upper = negative_binomial::find_upper_bound_on_p(trials, successes, alpha[i]/2);`
			`// Print limits:`
			`cout << fixed << setprecision(5) << setw(15) << right << lower;`
			`cout << fixed << setprecision(5) << setw(15) << right << upper << endl;`
			`}`
			`cout << endl;`
			`} // void confidence_limits_on_frequency(unsigned trials, unsigned successes)`

			/*`

			`And then call confidence_limits_on_frequency with increasing numbers of trials,`
			`but always the same success fraction 0.1, or 1 in 10.`

			`*/`

			`int main()`
			`{`
			`confidence_limits_on_frequency(20, 2); // 20 trials, 2 successes, 2 in 20, = 1 in 10 = 0.1 success fraction.`
			`confidence_limits_on_frequency(200, 20); // More trials, but same 0.1 success fraction.`
			`confidence_limits_on_frequency(2000, 200); // Many more trials, but same 0.1 success fraction.`

			`return 0;`
			`} // int main()`

			`//] [/negative_binomial_confidence_limits_eg end of Quickbook in C++ markup]`

			`/*`

			`______________________________________________`
			`2-Sided Confidence Limits For Success Fraction`
			`______________________________________________`
			`Number of trials = 20`
			`Number of successes = 2`
			`Number of failures = 18`
			`Observed frequency of occurrence = 0.1`
			`___________________________________________`
			`Confidence Lower Upper`
			`Value (%) Limit Limit`
			`___________________________________________`
			`50.000 0.04812 0.13554`
			`75.000 0.03078 0.17727`
			`90.000 0.01807 0.22637`
			`95.000 0.01235 0.26028`
			`99.000 0.00530 0.33111`
			`99.900 0.00164 0.41802`
			`99.990 0.00051 0.49202`
			`99.999 0.00016 0.55574`
			`______________________________________________`
			`2-Sided Confidence Limits For Success Fraction`
			`______________________________________________`
			`Number of trials = 200`
			`Number of successes = 20`
			`Number of failures = 180`
			`Observed frequency of occurrence = 0.1000000`
			`___________________________________________`
			`Confidence Lower Upper`
			`Value (%) Limit Limit`
			`___________________________________________`
			`50.000 0.08462 0.11350`
			`75.000 0.07580 0.12469`
			`90.000 0.06726 0.13695`
			`95.000 0.06216 0.14508`
			`99.000 0.05293 0.16170`
			`99.900 0.04343 0.18212`
			`99.990 0.03641 0.20017`
			`99.999 0.03095 0.21664`
			`______________________________________________`
			`2-Sided Confidence Limits For Success Fraction`
			`______________________________________________`
			`Number of trials = 2000`
			`Number of successes = 200`
			`Number of failures = 1800`
			`Observed frequency of occurrence = 0.1000000`
			`___________________________________________`
			`Confidence Lower Upper`
			`Value (%) Limit Limit`
			`___________________________________________`
			`50.000 0.09536 0.10445`
			`75.000 0.09228 0.10776`
			`90.000 0.08916 0.11125`
			`95.000 0.08720 0.11352`
			`99.000 0.08344 0.11802`
			`99.900 0.07921 0.12336`
			`99.990 0.07577 0.12795`
			`99.999 0.07282 0.13206`
			`*/`