EVOLUTION-MANAGER

Edit File: cubic_b_spline.hpp

// Copyright Nick Thompson, 2017 // 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) // This implements the compactly supported cubic b spline algorithm described in // Kress, Rainer. "Numerical analysis, volume 181 of Graduate Texts in Mathematics." (1998). // Splines of compact support are faster to evaluate and are better conditioned than classical cubic splines. // Let f be the function we are trying to interpolate, and s be the interpolating spline. // The routine constructs the interpolant in O(N) time, and evaluating s at a point takes constant time. // The order of accuracy depends on the regularity of the f, however, assuming f is // four-times continuously differentiable, the error is of O(h^4). // In addition, we can differentiate the spline and obtain a good interpolant for f'. // The main restriction of this method is that the samples of f must be evenly spaced. // Look for barycentric rational interpolation for non-evenly sampled data. // Properties: // - s(x_j) = f(x_j) // - All cubic polynomials interpolated exactly #ifndef BOOST_MATH_INTERPOLATORS_CUBIC_B_SPLINE_HPP #define BOOST_MATH_INTERPOLATORS_CUBIC_B_SPLINE_HPP #include <boost/math/interpolators/detail/cubic_b_spline_detail.hpp> #include <boost/config/header_deprecated.hpp> BOOST_HEADER_DEPRECATED("<boost/math/interpolators/cardinal_cubic_b_spline.hpp>"); namespace boost{ namespace math{ template <class Real> class cubic_b_spline { public: // If you don't know the value of the derivative at the endpoints, leave them as nans and the routine will estimate them. // f[0] = f(a), f[length -1] = b, step_size = (b - a)/(length -1). template <class BidiIterator> cubic_b_spline(const BidiIterator f, BidiIterator end_p, Real left_endpoint, Real step_size, Real left_endpoint_derivative = std::numeric_limits<Real>::quiet_NaN(), Real right_endpoint_derivative = std::numeric_limits<Real>::quiet_NaN()); cubic_b_spline(const Real* const f, size_t length, Real left_endpoint, Real step_size, Real left_endpoint_derivative = std::numeric_limits<Real>::quiet_NaN(), Real right_endpoint_derivative = std::numeric_limits<Real>::quiet_NaN()); cubic_b_spline() = default; Real operator()(Real x) const; Real prime(Real x) const; Real double_prime(Real x) const; private: std::shared_ptr<detail::cubic_b_spline_imp<Real>> m_imp; }; template<class Real> cubic_b_spline<Real>::cubic_b_spline(const Real* const f, size_t length, Real left_endpoint, Real step_size, Real left_endpoint_derivative, Real right_endpoint_derivative) : m_imp(std::make_shared<detail::cubic_b_spline_imp<Real>>(f, f + length, left_endpoint, step_size, left_endpoint_derivative, right_endpoint_derivative)) { } template <class Real> template <class BidiIterator> cubic_b_spline<Real>::cubic_b_spline(BidiIterator f, BidiIterator end_p, Real left_endpoint, Real step_size, Real left_endpoint_derivative, Real right_endpoint_derivative) : m_imp(std::make_shared<detail::cubic_b_spline_imp<Real>>(f, end_p, left_endpoint, step_size, left_endpoint_derivative, right_endpoint_derivative)) { } template<class Real> Real cubic_b_spline<Real>::operator()(Real x) const { return m_imp->operator()(x); } template<class Real> Real cubic_b_spline<Real>::prime(Real x) const { return m_imp->prime(x); } template<class Real> Real cubic_b_spline<Real>::double_prime(Real x) const { return m_imp->double_prime(x); } }} #endif