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188 lines
5.2 KiB
188 lines
5.2 KiB
//============================================================================
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//
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// Ordinary differential equation solver using the Runge-Kutta method.
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// $Id$
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// Copyright (C) 2004 Georg Drenkhahn
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//
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// This file is free software; you can redistribute it and/or modify it under
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// the terms of the GNU General Public License version 2 as published by the
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// Free Software Foundation.
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//
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//============================================================================
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#ifndef RKODESOLVER_H
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#define RKODESOLVER_H
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// STL headers
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#include <valarray>
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/** @brief Solver class to integrate a first-order ordinary differential
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* equation (ODE) by means of a 6. order Runge-Kutta method.
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*
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* The ODE system must be given as the derivative
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* dy/dx = f(x,y)
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* with x in R and y in R^n.
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*
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* Within this class the function f() is a pure virtual function, which must be
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* reimplemented in a derived class.
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*
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* No other special data type for vectors or matrices are needed besides the STL
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* class std::valarray. */
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template<typename T>
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class RkOdeSolver
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{
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public:
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/** @brief Constructor
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* @param x Initial integration parameter
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* @param y Initial function values of function to integrate
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* @param dx Initial guess for step size. Will be automatically adjusted to
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* guarantee required precision.
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* @param eps Relative precision
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*
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* Initialises the solver with start conditions. */
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RkOdeSolver(const T& x=0.0,
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const std::valarray<T>& y=std::valarray<T>(0),
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const T& dx=0,
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const T& eps=1e-6);
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/** @brief Destructor */
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virtual ~RkOdeSolver(void);
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/** @brief Integrates the ordinary differential equation from the current x
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* value to x+@a dx.
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* @param dx x-interval size to integrate over starting from x. dx may be
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* negative.
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*
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* The integration is performed by calling rkStepCheck() repeatedly until the
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* desired x value is reached. */
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void integrate(const T& dx);
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// Accessors
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// get/set x value
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/** @brief Get current x value.
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* @return Reference of x value. */
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const T& X(void) const;
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/** @brief Set current x value.
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* @param a The value to be set. */
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void X(const T& a);
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// get/set y value
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/** @brief Get current y value.
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* @return Reference of y vector. */
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const std::valarray<T>& Y(void) const;
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/** @brief Set current y values.
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* @param a The vector to be set. */
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void Y(const std::valarray<T>& a);
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/** @brief Get current dy/dx value.
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* @return Reference of dy/dx vector. */
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const std::valarray<T>& dYdX(void) const;
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// get/set dx value
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/** @brief Get current estimated step size dX.
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* @return Reference of dX value. */
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const T& dX(void) const;
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/** @brief Set estimated step size dX.
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* @param a The value to be set. */
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void dX(const T& a);
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// get/set eps value
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/** @brief Get current presision.
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* @return Reference of precision value. */
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const T& Eps(void) const;
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/** @brief Set estimated presision.
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* @param a The value to be set. */
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void Eps(const T& a);
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protected:
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// purely virtual function which is integrated
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/** @brief ODE function
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* @param x Integration value
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* @param y Function value
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* @return Derivation
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*
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* This purely virtual function returns the value of dy/dx for the given
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* parameter values of x and y. */
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virtual std::valarray<T>
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f(const T& x, const std::valarray<T>& y) const = 0;
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private:
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/** @brief Perform one integration step with a tolerable relative error given
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* by ::mErr.
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* @param dx Maximal step size, may be positive or negative depending on
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* integration direction.
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* @return Flag indicating if made absolute integration step was equal |@a dx
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* | (true) less than |@a dx | (false).
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*
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* A new estimate for the maximum next step size is saved to ::mStep. The
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* new values for x, y and f are saved in ::mX, ::mY and ::mDydx. */
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bool rkStepCheck(const T& dx);
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/** @brief Perform one Runge-Kutta integration step forward with step size
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* ::mStep
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* @param dx Step size relative to current x value.
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* @param yerr Reference to vector in which the estimated error made in y is
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* returned.
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* @return The y value after the step at x+@a dx.
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*
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* Stored current x,y values are not adjusted. */
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std::valarray<T> rkStep(const T& dx, std::valarray<T>& yerr) const;
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/** current x value */
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T mX;
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/** current y value */
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std::valarray<T> mY;
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/** current value of dy/dx */
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std::valarray<T> mDydx;
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/** allowed relative error */
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T mEps;
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/** estimated step size for next Runge-Kutta step */
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T mStep;
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};
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// inline accessors
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template<typename T>
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inline const T&
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RkOdeSolver<T>::X(void) const
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{
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return mX;
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}
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template<typename T>
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inline void
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RkOdeSolver<T>::X(const T &a)
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{
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mX = a;
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}
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template<typename T>
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inline const std::valarray<T>&
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RkOdeSolver<T>::Y(void) const
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{
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return mY;
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}
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template<typename T>
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inline const std::valarray<T>&
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RkOdeSolver<T>::dYdX(void) const
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{
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return mDydx;
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}
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template<typename T>
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inline const T&
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RkOdeSolver<T>::dX(void) const
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{
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return mStep;
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}
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template<typename T>
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inline const T&
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RkOdeSolver<T>::Eps(void) const
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{
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return mEps;
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}
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#endif
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