WSJT-X/boost/libs/math/doc/internals/fraction.qbk

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[section:cf Continued Fraction Evaluation]
[h4 Synopsis]
``
#include <boost/math/tools/fraction.hpp>
``
namespace boost{ namespace math{ namespace tools{
template <class Gen, class U>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_b(Gen& g, const U& tolerance, boost::uintmax_t& max_terms)
template <class Gen, class U>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_b(Gen& g, const U& tolerance)
template <class Gen, class U>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_a(Gen& g, const U& tolerance, boost::uintmax_t& max_terms)
template <class Gen, class U>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_a(Gen& g, const U& tolerance)
//
// These interfaces are present for legacy reasons, and are now deprecated:
//
template <class Gen>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_b(Gen& g, int bits);
template <class Gen>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_b(Gen& g, int bits, boost::uintmax_t& max_terms);
template <class Gen>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_a(Gen& g, int bits);
template <class Gen>
typename detail::fraction_traits<Gen>::result_type
continued_fraction_a(Gen& g, int bits, boost::uintmax_t& max_terms);
}}} // namespaces
[h4 Description]
[@http://en.wikipedia.org/wiki/Continued_fraction Continued fractions are a common method of approximation. ]
These functions all evaluate the continued fraction described by the /generator/
type argument. The functions with an "_a" suffix evaluate the fraction:
[equation fraction2]
and those with a "_b" suffix evaluate the fraction:
[equation fraction1]
This latter form is somewhat more natural in that it corresponds with the usual
definition of a continued fraction, but note that the first /a/ value returned by
the generator is discarded. Further, often the first /a/ and /b/ values in a
continued fraction have different defining equations to the remaining terms, which
may make the "_a" suffixed form more appropriate.
The generator type should be a function object which supports the following
operations:
[table
[[Expression] [Description]]
[[Gen::result_type] [The type that is the result of invoking operator().
This can be either an arithmetic type, or a std::pair<> of arithmetic types.]]
[[g()] [Returns an object of type Gen::result_type.
Each time this operator is called then the next pair of /a/ and /b/
values is returned. Or, if result_type is an arithmetic type,
then the next /b/ value is returned and all the /a/ values
are assumed to 1.]]
]
In all the continued fraction evaluation functions the /tolerance/ parameter is the
precision desired in the result, evaluation of the fraction will
continue until the last term evaluated leaves the relative error in the result
less than /tolerance/. The deprecated interfaces take a number of digits precision
here, internally they just convert this to a tolerance and forward call.
If the optional /max_terms/ parameter is specified then no more than /max_terms/
calls to the generator will be made, and on output,
/max_terms/ will be set to actual number of
calls made. This facility is particularly useful when profiling a continued
fraction for convergence.
[h4 Implementation]
Internally these algorithms all use the modified Lentz algorithm: refer to
Numeric Recipes in C++, W. H. Press et all, chapter 5,
(especially 5.2 Evaluation of continued fractions, p 175 - 179)
for more information, also
Lentz, W.J. 1976, Applied Optics, vol. 15, pp. 668-671.
[h4 Examples]
The [@http://en.wikipedia.org/wiki/Golden_ratio golden ratio phi = 1.618033989...]
can be computed from the simplest continued fraction of all:
[equation fraction3]
We begin by defining a generator function:
template <class T>
struct golden_ratio_fraction
{
typedef T result_type;
result_type operator()
{
return 1;
}
};
The golden ratio can then be computed to double precision using:
continued_fraction_a(
golden_ratio_fraction<double>(),
std::numeric_limits<double>::epsilon());
It's more usual though to have to define both the /a/'s and the /b/'s
when evaluating special functions by continued fractions, for example
the tan function is defined by:
[equation fraction4]
So its generator object would look like:
template <class T>
struct tan_fraction
{
private:
T a, b;
public:
tan_fraction(T v)
: a(-v*v), b(-1)
{}
typedef std::pair<T,T> result_type;
std::pair<T,T> operator()()
{
b += 2;
return std::make_pair(a, b);
}
};
Notice that if the continuant is subtracted from the /b/ terms,
as is the case here, then all the /a/ terms returned by the generator
will be negative. The tangent function can now be evaluated using:
template <class T>
T tan(T a)
{
tan_fraction<T> fract(a);
return a / continued_fraction_b(fract, std::numeric_limits<T>::epsilon());
}
Notice that this time we're using the "_b" suffixed version to evaluate
the fraction: we're removing the leading /a/ term during fraction evaluation
as it's different from all the others.
[endsect][/section:cf Continued Fraction Evaluation]
[/
Copyright 2006 John Maddock and Paul A. Bristow.
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).
]