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/***********************************************/
/**
* @file gravityfieldTides.cpp
*
* @brief Tidal forces computed with class Tide.
* @see Gravityfield
* @see Tides
*
* @author Torsten Mayer-Guerr
* @date 2004-11-01
*
*/
/***********************************************/
#include "base/import.h"
#include "base/sphericalHarmonics.h"
#include "config/config.h"
#include "classes/kernel/kernel.h"
#include "classes/earthRotation/earthRotation.h"
#include "classes/tides/tides.h"
#include "classes/gravityfield/gravityfield.h"
#include "classes/gravityfield/gravityfieldTides.h"
/***********************************************/
GravityfieldTides::GravityfieldTides(Config &config)
{
try
{
readConfig(config, "tides", tides, Config::MUSTSET, "", "");
readConfig(config, "earthRotation", earthRotation, Config::MUSTSET, "", "");
readConfig(config, "ephemerides", ephemerides, Config::OPTIONAL, "jpl", "");
if(isCreateSchema(config)) return;
}
catch(std::exception &e)
{
GROOPS_RETHROW(e)
}
}
/***********************************************/
Double GravityfieldTides::potential(const Time &time, const Vector3d &point) const
{
return tides->potential(time, point, earthRotation->rotaryMatrix(time), earthRotation, ephemerides);
}
/***********************************************/
Double GravityfieldTides::radialGradient(const Time &time, const Vector3d &point) const
{
return tides->radialGradient(time, point, earthRotation->rotaryMatrix(time), earthRotation, ephemerides);
}
/***********************************************/
Vector3d GravityfieldTides::gravity(const Time &time, const Vector3d &point) const
{
return tides->acceleration(time, point, earthRotation->rotaryMatrix(time), earthRotation, ephemerides);
}
/***********************************************/
Tensor3d GravityfieldTides::gravityGradient(const Time &time, const Vector3d &point) const
{
return tides->gradient(time, point, earthRotation->rotaryMatrix(time), earthRotation, ephemerides);
}
/***********************************************/
Vector3d GravityfieldTides::deformation(const Time &time, const Vector3d &point, Double gravity, const Vector &hn, const Vector &ln) const
{
return tides->deformation(time, point, earthRotation->rotaryMatrix(time), earthRotation, ephemerides, gravity, hn, ln);
}
/***********************************************/
void GravityfieldTides::deformation(const std::vector<Time> &time, const std::vector<Vector3d> &point, const std::vector<Double> &gravity,
const Vector &hn, const Vector &ln, std::vector<std::vector<Vector3d>> &disp) const
{
std::vector<Rotary3d> rotEarth(time.size());
for(UInt i=0; i<time.size(); i++)
rotEarth[i]= earthRotation->rotaryMatrix(time[i]);
tides->deformation(time, point, rotEarth, earthRotation, ephemerides, gravity, hn, ln, disp);
}
/***********************************************/
void GravityfieldTides::variance(const Time &/*time*/, const std::vector<Vector3d> &/*point*/, const Kernel &/*kernel*/, Matrix &/*D*/) const
{
try
{
}
catch(std::exception &e)
{
GROOPS_RETHROW(e)
}
}
/***********************************************/
SphericalHarmonics GravityfieldTides::sphericalHarmonics(const Time &time, UInt maxDegree, UInt minDegree, Double GM, Double R) const
{
try
{
return tides->sphericalHarmonics(time, earthRotation->rotaryMatrix(time), earthRotation, ephemerides, maxDegree, minDegree, GM, R);
}
catch(std::exception &e)
{
GROOPS_RETHROW(e)
}
}
/***********************************************/
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