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229 lines
7.2 KiB
Plaintext
229 lines
7.2 KiB
Plaintext
[section:legendre Legendre (and Associated) Polynomials]
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[h4 Synopsis]
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``
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#include <boost/math/special_functions/legendre.hpp>
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``
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namespace boost{ namespace math{
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template <class T>
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``__sf_result`` legendre_p(int n, T x);
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template <class T, class ``__Policy``>
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``__sf_result`` legendre_p(int n, T x, const ``__Policy``&);
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template <class T>
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``__sf_result`` legendre_p(int n, int m, T x);
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template <class T, class ``__Policy``>
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``__sf_result`` legendre_p(int n, int m, T x, const ``__Policy``&);
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template <class T>
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``__sf_result`` legendre_q(unsigned n, T x);
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template <class T, class ``__Policy``>
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``__sf_result`` legendre_q(unsigned n, T x, const ``__Policy``&);
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template <class T1, class T2, class T3>
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``__sf_result`` legendre_next(unsigned l, T1 x, T2 Pl, T3 Plm1);
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template <class T1, class T2, class T3>
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``__sf_result`` legendre_next(unsigned l, unsigned m, T1 x, T2 Pl, T3 Plm1);
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}} // namespaces
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The return type of these functions is computed using the __arg_promotion_rules:
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note than when there is a single template argument the result is the same type
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as that argument or `double` if the template argument is an integer type.
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[optional_policy]
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[h4 Description]
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template <class T>
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``__sf_result`` legendre_p(int l, T x);
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template <class T, class ``__Policy``>
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``__sf_result`` legendre_p(int l, T x, const ``__Policy``&);
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Returns the Legendre Polynomial of the first kind:
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[equation legendre_0]
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Requires -1 <= x <= 1, otherwise returns the result of __domain_error.
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Negative orders are handled via the reflection formula:
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P[sub -l-1](x) = P[sub l](x)
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The following graph illustrates the behaviour of the first few
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Legendre Polynomials:
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[graph legendre_p]
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template <class T>
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``__sf_result`` legendre_p(int l, int m, T x);
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template <class T, class ``__Policy``>
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``__sf_result`` legendre_p(int l, int m, T x, const ``__Policy``&);
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Returns the associated Legendre polynomial of the first kind:
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[equation legendre_1]
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Requires -1 <= x <= 1, otherwise returns the result of __domain_error.
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Negative values of /l/ and /m/ are handled via the identity relations:
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[equation legendre_3]
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[caution The definition of the associated Legendre polynomial used here
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includes a leading Condon-Shortley phase term of (-1)[super m]. This
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matches the definition given by Abramowitz and Stegun (8.6.6) and that
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used by [@http://mathworld.wolfram.com/LegendrePolynomial.html Mathworld]
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and [@http://documents.wolfram.com/mathematica/functions/LegendreP
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Mathematica's LegendreP function]. However, uses in the literature
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do not always include this phase term, and strangely the specification
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for the associated Legendre function in the C++ TR1 (assoc_legendre)
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also omits it, in spite of stating that it uses Abramowitz and Stegun
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as the final arbiter on these matters.
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See:
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[@http://mathworld.wolfram.com/LegendrePolynomial.html
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Weisstein, Eric W. "Legendre Polynomial."
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From MathWorld--A Wolfram Web Resource].
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Abramowitz, M. and Stegun, I. A. (Eds.). "Legendre Functions" and
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"Orthogonal Polynomials." Ch. 22 in Chs. 8 and 22 in Handbook of
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Mathematical Functions with Formulas, Graphs, and Mathematical Tables,
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9th printing. New York: Dover, pp. 331-339 and 771-802, 1972.
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]
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template <class T>
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``__sf_result`` legendre_q(unsigned n, T x);
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template <class T, class ``__Policy``>
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``__sf_result`` legendre_q(unsigned n, T x, const ``__Policy``&);
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Returns the value of the Legendre polynomial that is the second solution
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to the Legendre differential equation, for example:
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[equation legendre_2]
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Requires -1 <= x <= 1, otherwise __domain_error is called.
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The following graph illustrates the first few Legendre functions of the
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second kind:
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[graph legendre_q]
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template <class T1, class T2, class T3>
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``__sf_result`` legendre_next(unsigned l, T1 x, T2 Pl, T3 Plm1);
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Implements the three term recurrence relation for the Legendre
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polynomials, this function can be used to create a sequence of
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values evaluated at the same /x/, and for rising /l/. This recurrence
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relation holds for Legendre Polynomials of both the first and second kinds.
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[equation legendre_4]
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For example we could produce a vector of the first 10 polynomial
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values using:
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double x = 0.5; // Abscissa value
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vector<double> v;
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v.push_back(legendre_p(0, x));
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v.push_back(legendre_p(1, x));
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for(unsigned l = 1; l < 10; ++l)
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v.push_back(legendre_next(l, x, v[l], v[l-1]));
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// Double check values:
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for(unsigned l = 1; l < 10; ++l)
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assert(v[l] == legendre_p(l, x));
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Formally the arguments are:
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[variablelist
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[[l][The degree of the last polynomial calculated.]]
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[[x][The abscissa value]]
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[[Pl][The value of the polynomial evaluated at degree /l/.]]
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[[Plm1][The value of the polynomial evaluated at degree /l-1/.]]
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]
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template <class T1, class T2, class T3>
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``__sf_result`` legendre_next(unsigned l, unsigned m, T1 x, T2 Pl, T3 Plm1);
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Implements the three term recurrence relation for the Associated Legendre
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polynomials, this function can be used to create a sequence of
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values evaluated at the same /x/, and for rising /l/.
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[equation legendre_5]
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For example we could produce a vector of the first m+10 polynomial
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values using:
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double x = 0.5; // Abscissa value
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int m = 10; // order
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vector<double> v;
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v.push_back(legendre_p(m, m, x));
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v.push_back(legendre_p(1 + m, m, x));
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for(unsigned l = 1; l < 10; ++l)
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v.push_back(legendre_next(l + 10, m, x, v[l], v[l-1]));
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// Double check values:
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for(unsigned l = 1; l < 10; ++l)
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assert(v[l] == legendre_p(10 + l, m, x));
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Formally the arguments are:
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[variablelist
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[[l][The degree of the last polynomial calculated.]]
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[[m][The order of the Associated Polynomial.]]
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[[x][The abscissa value]]
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[[Pl][The value of the polynomial evaluated at degree /l/.]]
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[[Plm1][The value of the polynomial evaluated at degree /l-1/.]]
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]
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[h4 Accuracy]
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The following table shows peak errors (in units of epsilon)
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for various domains of input arguments.
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Note that only results for the widest floating point type on the system are
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given as narrower types have __zero_error.
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[table_legendre_p]
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[table_legendre_q]
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[table_legendre_p_associated_]
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Note that the worst errors occur when the order increases, values greater than
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~120 are very unlikely to produce sensible results, especially in the associated
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polynomial case when the degree is also large. Further the relative errors
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are likely to grow arbitrarily large when the function is very close to a root.
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[h4 Testing]
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A mixture of spot tests of values calculated using functions.wolfram.com,
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and randomly generated test data are
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used: the test data was computed using
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[@http://shoup.net/ntl/doc/RR.txt NTL::RR] at 1000-bit precision.
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[h4 Implementation]
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These functions are implemented using the stable three term
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recurrence relations. These relations guarantee low absolute error
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but cannot guarantee low relative error near one of the roots of the
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polynomials.
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[endsect][/section:beta_function The Beta Function]
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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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