libs/math/example/bessel_zeros_example_1.cpp
// Copyright Christopher Kormanyos 2013.
// Copyright Paul A. Bristow 2013.
// Copyright John Maddock 2013.
// Distributed under 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).
#ifdef _MSC_VER
# pragma warning (disable : 4512) // assignment operator could not be generated.
# pragma warning (disable : 4996) // assignment operator could not be generated.
#endif
#include <iostream>
#include <limits>
#include <vector>
#include <algorithm>
#include <iomanip>
#include <iterator>
// Weisstein, Eric W. "Bessel Function Zeros." From MathWorld--A Wolfram Web Resource.
// http://mathworld.wolfram.com/BesselFunctionZeros.html
// Test values can be calculated using [@wolframalpha.com WolframAlpha]
// See also http://dlmf.nist.gov/10.21
//[bessel_zeros_example_1
/*`This example demonstrates calculating zeros of the Bessel and Neumann functions.
It also shows how Boost.Math and Boost.Multiprecision can be combined to provide
a many decimal digit precision. For 50 decimal digit precision we need to include
*/
#include <boost/multiprecision/cpp_dec_float.hpp>
/*`and a `typedef` for `float_type` may be convenient
(allowing a quick switch to re-compute at built-in `double` or other precision)
*/
typedef boost::multiprecision::cpp_dec_float_50 float_type;
//`To use the functions for finding zeros of the functions we need
#include <boost/math/special_functions/bessel.hpp>
//`This file includes the forward declaration signatures for the zero-finding functions:
// #include <boost/math/special_functions/math_fwd.hpp>
/*`but more details are in the full documentation, for example at
[@http://www.boost.org/doc/libs/1_53_0/libs/math/doc/sf_and_dist/html/math_toolkit/special/bessel/bessel_over.html Boost.Math Bessel functions].
*/
/*`This example shows obtaining both a single zero of the Bessel function,
and then placing multiple zeros into a container like `std::vector` by providing an iterator.
*/
//] [/bessel_zeros_example_1]
/*The signature of the single value function is:
template <class T>
inline typename detail::bessel_traits<T, T, policies::policy<> >::result_type
cyl_bessel_j_zero(
T v, // Floating-point value for Jv.
int m); // start index.
The result type is controlled by the floating-point type of parameter `v`
(but subject to the usual __precision_policy and __promotion_policy).
The signature of multiple zeros function is:
template <class T, class OutputIterator>
inline OutputIterator cyl_bessel_j_zero(
T v, // Floating-point value for Jv.
int start_index, // 1-based start index.
unsigned number_of_zeros, // How many zeros to generate
OutputIterator out_it); // Destination for zeros.
There is also a version which allows control of the __policy_section for error handling and precision.
template <class T, class OutputIterator, class Policy>
inline OutputIterator cyl_bessel_j_zero(
T v, // Floating-point value for Jv.
int start_index, // 1-based start index.
unsigned number_of_zeros, // How many zeros to generate
OutputIterator out_it, // Destination for zeros.
const Policy& pol); // Policy to use.
*/
int main()
{
try
{
//[bessel_zeros_example_2
/*`[tip It is always wise to place code using Boost.Math inside try'n'catch blocks;
this will ensure that helpful error messages are shown when exceptional conditions arise.]
First, evaluate a single Bessel zero.
The precision is controlled by the float-point type of template parameter `T` of `v`
so this example has `double` precision, at least 15 but up to 17 decimal digits (for the common 64-bit double).
*/
// double root = boost::math::cyl_bessel_j_zero(0.0, 1);
// // Displaying with default precision of 6 decimal digits:
// std::cout << "boost::math::cyl_bessel_j_zero(0.0, 1) " << root << std::endl; // 2.40483
// // And with all the guaranteed (15) digits:
// std::cout.precision(std::numeric_limits<double>::digits10);
// std::cout << "boost::math::cyl_bessel_j_zero(0.0, 1) " << root << std::endl; // 2.40482555769577
/*`But note that because the parameter `v` controls the precision of the result,
`v` [*must be a floating-point type].
So if you provide an integer type, say 0, rather than 0.0, then it will fail to compile thus:
``
root = boost::math::cyl_bessel_j_zero(0, 1);
``
with this error message
``
error C2338: Order must be a floating-point type.
``
Optionally, we can use a policy to ignore errors, C-style, returning some value,
perhaps infinity or NaN, or the best that can be done. (See __user_error_handling).
To create a (possibly unwise!) policy `ignore_all_policy` that ignores all errors:
*/
typedef boost::math::policies::policy<
boost::math::policies::domain_error<boost::math::policies::ignore_error>,
boost::math::policies::overflow_error<boost::math::policies::ignore_error>,
boost::math::policies::underflow_error<boost::math::policies::ignore_error>,
boost::math::policies::denorm_error<boost::math::policies::ignore_error>,
boost::math::policies::pole_error<boost::math::policies::ignore_error>,
boost::math::policies::evaluation_error<boost::math::policies::ignore_error>
> ignore_all_policy;
//`Examples of use of this `ignore_all_policy` are
double inf = std::numeric_limits<double>::infinity();
double nan = std::numeric_limits<double>::quiet_NaN();
double dodgy_root = boost::math::cyl_bessel_j_zero(-1.0, 1, ignore_all_policy());
std::cout << "boost::math::cyl_bessel_j_zero(-1.0, 1) " << dodgy_root << std::endl; // 1.#QNAN
double inf_root = boost::math::cyl_bessel_j_zero(inf, 1, ignore_all_policy());
std::cout << "boost::math::cyl_bessel_j_zero(inf, 1) " << inf_root << std::endl; // 1.#QNAN
double nan_root = boost::math::cyl_bessel_j_zero(nan, 1, ignore_all_policy());
std::cout << "boost::math::cyl_bessel_j_zero(nan, 1) " << nan_root << std::endl; // 1.#QNAN
/*`Another version of `cyl_bessel_j_zero` allows calculation of multiple zeros with one call,
placing the results in a container, often `std::vector`.
For example, generate and display the first five `double` roots of J[sub v] for integral order 2,
as column ['J[sub 2](x)] in table 1 of
[@ http://mathworld.wolfram.com/BesselFunctionZeros.html Wolfram Bessel Function Zeros].
*/
unsigned int n_roots = 5U;
std::vector<double> roots;
boost::math::cyl_bessel_j_zero(2.0, 1, n_roots, std::back_inserter(roots));
std::copy(roots.begin(),
roots.end(),
std::ostream_iterator<double>(std::cout, "\n"));
/*`Or we can use Boost.Multiprecision to generate 50 decimal digit roots of ['J[sub v]]
for non-integral order `v= 71/19 == 3.736842`, expressed as an exact-integer fraction
to generate the most accurate value possible for all floating-point types.
We set the precision of the output stream, and show trailing zeros to display a fixed 50 decimal digits.
*/
std::cout.precision(std::numeric_limits<float_type>::digits10); // 50 decimal digits.
std::cout << std::showpoint << std::endl; // Show trailing zeros.
float_type x = float_type(71) / 19;
float_type r = boost::math::cyl_bessel_j_zero(x, 1); // 1st root.
std::cout << "x = " << x << ", r = " << r << std::endl;
r = boost::math::cyl_bessel_j_zero(x, 20U); // 20th root.
std::cout << "x = " << x << ", r = " << r << std::endl;
std::vector<float_type> zeros;
boost::math::cyl_bessel_j_zero(x, 1, 3, std::back_inserter(zeros));
std::cout << "cyl_bessel_j_zeros" << std::endl;
// Print the roots to the output stream.
std::copy(zeros.begin(), zeros.end(),
std::ostream_iterator<float_type>(std::cout, "\n"));
//] [/bessel_zeros_example_2]
}
catch (std::exception const& ex)
{
std::cout << "Thrown exception " << ex.what() << std::endl;
}
} // int main()
/*
Output:
Description: Autorun "J:\Cpp\big_number\Debug\bessel_zeros_example_1.exe"
boost::math::cyl_bessel_j_zero(-1.0, 1) 3.83171
boost::math::cyl_bessel_j_zero(inf, 1) 1.#QNAN
boost::math::cyl_bessel_j_zero(nan, 1) 1.#QNAN
5.13562
8.41724
11.6198
14.796
17.9598
x = 3.7368421052631578947368421052631578947368421052632, r = 7.2731751938316489503185694262290765588963196701623
x = 3.7368421052631578947368421052631578947368421052632, r = 67.815145619696290925556791375555951165111460585458
cyl_bessel_j_zeros
7.2731751938316489503185694262290765588963196701623
10.724858308883141732536172745851416647110749599085
14.018504599452388106120459558042660282427471931581
*/