/*
* Project: MoleCuilder
* Description: creates and alters molecular systems
* Copyright (C) 2012 University of Bonn. All rights reserved.
* Please see the COPYING file or "Copyright notice" in builder.cpp for details.
*
*
* This file is part of MoleCuilder.
*
* MoleCuilder is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 2 of the License, or
* (at your option) any later version.
*
* MoleCuilder is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with MoleCuilder. If not, see .
*/
/*
* SaturationPotential.cpp
*
* Created on: Oct 11, 2012
* Author: heber
*/
// include config.h
#ifdef HAVE_CONFIG_H
#include
#endif
#include "CodePatterns/MemDebug.hpp"
#include "SaturationPotential.hpp"
#include "CodePatterns/Assert.hpp"
#include "CodePatterns/Log.hpp"
#include "Potentials/helpers.hpp"
SaturationPotential::SaturationPotential(
boost::function< std::vector(const argument_t &, const double)> &_triplefunction) :
energy_offset(0.),
triplefunction(_triplefunction),
saturation_cutoff(2.5)
{}
SaturationPotential::SaturationPotential(
const double _morse_spring_constant,
const double _morse_equilibrium_distance,
const double _morse_dissociation_energy,
const double _angle_spring_constant,
const double _angle_equilibrium_distance,
const double _all_energy_offset,
boost::function< std::vector(const argument_t &, const double)> &_triplefunction) :
energy_offset(_all_energy_offset),
triplefunction(_triplefunction),
saturation_cutoff(2.5)
{
parameters_t morse_params(morse.getParameterDimension());
morse_params[PairPotential_Morse::spring_constant] = _morse_spring_constant;
morse_params[PairPotential_Morse::equilibrium_distance] = _morse_equilibrium_distance;
morse_params[PairPotential_Morse::dissociation_energy] = _morse_dissociation_energy;
morse_params[PairPotential_Morse::energy_offset] = 0.;
morse.setParameters(morse_params);
parameters_t angle_params(angle.getParameterDimension());
angle_params[PairPotential_Angle::spring_constant] = _angle_spring_constant;
angle_params[PairPotential_Angle::equilibrium_distance] = _angle_equilibrium_distance;
angle_params[PairPotential_Angle::energy_offset] = 0.;
angle.setParameters(angle_params);
}
void SaturationPotential::setParameters(const parameters_t &_params)
{
const size_t paramsDim = _params.size();
ASSERT( paramsDim <= getParameterDimension(),
"SaturationPotential::setParameters() - we need not more than "
+toString(getParameterDimension())+" parameters.");
// LOG(1, "INFO: Setting new SaturationPotential params: " << _params);
// offsets
if (paramsDim > all_energy_offset)
energy_offset = _params[all_energy_offset];
// Morse
{
parameters_t morse_params(morse.getParameters());
if (paramsDim > morse_spring_constant)
morse_params[PairPotential_Morse::spring_constant] = _params[morse_spring_constant];
if (paramsDim > morse_equilibrium_distance)
morse_params[PairPotential_Morse::equilibrium_distance] = _params[morse_equilibrium_distance];
if (paramsDim > morse_dissociation_energy)
morse_params[PairPotential_Morse::dissociation_energy] = _params[morse_dissociation_energy];
morse_params[PairPotential_Morse::energy_offset] = 0.;
morse.setParameters(morse_params);
}
// Angle
{
parameters_t angle_params(angle.getParameters());
if (paramsDim > angle_spring_constant)
angle_params[PairPotential_Angle::spring_constant] = _params[angle_spring_constant];
if (paramsDim > angle_equilibrium_distance)
angle_params[PairPotential_Angle::equilibrium_distance] = _params[angle_equilibrium_distance];
angle_params[PairPotential_Angle::energy_offset] = 0.;
angle.setParameters(angle_params);
}
#ifndef NDEBUG
parameters_t check_params(getParameters());
check_params.resize(paramsDim); // truncate to same size
ASSERT( check_params == _params,
"SaturationPotential::setParameters() - failed, mismatch in to be set "
+toString(_params)+" and set "+toString(check_params)+" params.");
#endif
}
SaturationPotential::parameters_t SaturationPotential::getParameters() const
{
parameters_t params(getParameterDimension());
const parameters_t morse_params = morse.getParameters();
const parameters_t angle_params = angle.getParameters();
params[all_energy_offset] = energy_offset;
params[morse_spring_constant] = morse_params[PairPotential_Morse::spring_constant];
params[morse_equilibrium_distance] = morse_params[PairPotential_Morse::equilibrium_distance];
params[morse_dissociation_energy] = morse_params[PairPotential_Morse::dissociation_energy];
params[angle_spring_constant] = angle_params[PairPotential_Angle::spring_constant];
params[angle_equilibrium_distance] = angle_params[PairPotential_Angle::equilibrium_distance];
return params;
}
SaturationPotential::results_t
SaturationPotential::operator()(
const arguments_t &arguments
) const
{
double result = 0.;
for(arguments_t::const_iterator argiter = arguments.begin();
argiter != arguments.end();
++argiter) {
const argument_t &r_ij = *argiter;
arguments_t args(1, r_ij);
if ((r_ij.indices.first == 0)) { // || (r_ij.indices.second == 0)) {
result += morse(args)[0];
if (result != result)
ELOG(1, "result is NAN.");
std::vector triples = triplefunction(r_ij, saturation_cutoff);
for (std::vector::const_iterator iter = triples.begin();
iter != triples.end(); ++iter) {
ASSERT( iter->size() == 2,
"ManyBodyPotential_Tersoff::function_derivative_c() - the triples result must contain exactly two distances.");
const argument_t &r_ik = (*iter)[0];
const argument_t &r_jk = (*iter)[1];
arguments_t args;
args.push_back(r_ij);
args.push_back(r_ik);
args.push_back(r_jk);
result += .5 * angle(args)[0];
if (result != result)
ELOG(1, "result is NAN.");
}
}
}
return std::vector(1, energy_offset + result);
}
SaturationPotential::derivative_components_t
SaturationPotential::derivative(
const arguments_t &arguments
) const
{
ASSERT( 0,
"SaturationPotential::operator() - not implemented.");
derivative_components_t result;
return result;
}
SaturationPotential::results_t
SaturationPotential::parameter_derivative(
const arguments_t &arguments,
const size_t index
) const
{
double result = 0.;
for(arguments_t::const_iterator argiter = arguments.begin();
argiter != arguments.end();
++argiter) {
const argument_t &r_ij = *argiter;
arguments_t args(1, r_ij);
if ((r_ij.indices.first == 0)) { // || (r_ij.indices.second == 0)) {
switch (index) {
case morse_spring_constant:
{
result += morse.parameter_derivative(args, PairPotential_Morse::spring_constant)[0];
break;
}
case morse_equilibrium_distance:
{
result += morse.parameter_derivative(args, PairPotential_Morse::equilibrium_distance)[0];
break;
}
case morse_dissociation_energy:
{
result += morse.parameter_derivative(args, PairPotential_Morse::dissociation_energy)[0];
break;
}
default:
{
std::vector triples = triplefunction(r_ij, saturation_cutoff);
for (std::vector::const_iterator iter = triples.begin();
iter != triples.end(); ++iter) {
ASSERT( iter->size() == 2,
"ManyBodyPotential_Tersoff::function_derivative_c() - the triples result must contain exactly two distances.");
const argument_t &r_ik = (*iter)[0];
const argument_t &r_jk = (*iter)[1];
arguments_t args;
args.push_back(r_ij);
args.push_back(r_ik);
args.push_back(r_jk);
switch (index) {
case angle_spring_constant:
{
result += .5*angle.parameter_derivative(args, PairPotential_Angle::spring_constant)[0];
break;
}
case angle_equilibrium_distance:
{
result += .5*angle.parameter_derivative(args, PairPotential_Angle::equilibrium_distance)[0];
break;
}
default:
break;
}
}
}
}
}
}
if (index == all_energy_offset)
result = 1.;
return SaturationPotential::results_t(1, result);
}