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• StatisticalTorsionTerm.java

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com.actelion.research.chem.conf.torsionstrain.StatisticalTorsionTerm Maven / Gradle / Ivy

/*
* Copyright (c) 1997 - 2016
* Actelion Pharmaceuticals Ltd.
* Gewerbestrasse 16
* CH-4123 Allschwil, Switzerland
*
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
*    list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright notice,
*    this list of conditions and the following disclaimer in the documentation
*    and/or other materials provided with the distribution.
* 3. Neither the name of the the copyright holder nor the
*    names of its contributors may be used to endorse or promote products
*    derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
package com.actelion.research.chem.conf.torsionstrain;

import java.text.DecimalFormat;
import java.util.Arrays;

import com.actelion.research.chem.Coordinates;
import com.actelion.research.chem.StereoMolecule;
import com.actelion.research.chem.conf.Conformer;
import com.actelion.research.chem.forcefield.mmff.Vector3;
import com.actelion.research.chem.interactionstatistics.SplineFunction;
import com.actelion.research.chem.potentialenergy.PotentialEnergyTerm;


/**
 * Represents a torsion potential as a function of the angle, derived from statistical torsion distributions from the COD/CSD
 * The dihedral angle is defined by a atom sequence of 4 atoms. If a core atom is sp3 hybridized and has two neighbours of the same symmetry rank,
 * then the torsion angle has to be defined by a virtual atom, occupying the position of the hypothetical third atom
 * 
 */
public class StatisticalTorsionTerm implements PotentialEnergyTerm  {


	private static final double EPS = 0.00001;
	public double rik2;
	private Conformer conf;
	private int atoms[];
	private int rearAtoms[][]; //to define virtual torsion atoms
	//Statistics
	private final SplineFunction f; 
	
	private StatisticalTorsionTerm(Conformer conf, int[] atoms, SplineFunction f) {
		this.conf = conf;
		this.f = f;			
		this.atoms = atoms;
		assessRearAtoms();
		
	}
	
	private void assessRearAtoms() {
		StereoMolecule mol = conf.getMolecule();
		rearAtoms = new int[2][];
		if(atoms[0]==-1) {
			rearAtoms[0] = new int[2];
			int index = 0;
			for(int i=0;i 0.0) ? Math.sqrt(sinPhiSq) : 0.0);


           double sinTerm = -dEdPhi * (Math.abs(sinPhi) < 0.00001
                   ? (1.0 / cosPhi) : (1.0 / sinPhi));

           double[] dCos_dT = new double[]{
               1.0 / d[0] * (t[1].x - cosPhi * t[0].x),
               1.0 / d[0] * (t[1].y - cosPhi * t[0].y),
               1.0 / d[0] * (t[1].z - cosPhi * t[0].z),
               1.0 / d[1] * (t[0].x - cosPhi * t[1].x),
               1.0 / d[1] * (t[0].y - cosPhi * t[1].y),
               1.0 / d[1] * (t[0].z - cosPhi * t[1].z)
           };
           if(rearAtoms!=null) {
	           if(rearAtoms[0]!=null) { // chain rule, take into account derivate of virtual atom wrt rear atoms
	        	   double derX = sinTerm * (dCos_dT[2] * r[1].y - dCos_dT[1] * r[1].z);
	        	   double derY = sinTerm * (dCos_dT[0] * r[1].z - dCos_dT[2] * r[1].x);
	        	   double derZ = sinTerm * (dCos_dT[1] * r[1].x - dCos_dT[0] * r[1].y);
	        	   gradient[3*rearAtoms[0][0]] -= derX;
	        	   gradient[3*rearAtoms[0][0]+1] -= derY;
	        	   gradient[3*rearAtoms[0][0]+2] -= derZ;
	        	   gradient[3*rearAtoms[0][1]] -= derX;
	        	   gradient[3*rearAtoms[0][1]+1] -= derY;
	        	   gradient[3*rearAtoms[0][1]+2] -= derZ;
	           }
           
	           else {
	        	   gradient[3*a1+0] += sinTerm * (dCos_dT[2] * r[1].y - dCos_dT[1] * r[1].z);
	        	   gradient[3*a1+1] += sinTerm * (dCos_dT[0] * r[1].z - dCos_dT[2] * r[1].x);
	        	   gradient[3*a1+2] += sinTerm * (dCos_dT[1] * r[1].x - dCos_dT[0] * r[1].y);
	           }
           }

           gradient[3*a2+0] += sinTerm * (dCos_dT[1] * (r[1].z - r[0].z)
                   + dCos_dT[2] * (r[0].y - r[1].y)
                   + dCos_dT[4] * (-r[3].z)
                   + dCos_dT[5] * (r[3].y));
           gradient[3*a2+1] += sinTerm * (dCos_dT[0] * (r[0].z - r[1].z)
                   + dCos_dT[2] * (r[1].x - r[0].x)
                   + dCos_dT[3] * (r[3].z)
                   + dCos_dT[5] * (-r[3].x));
           gradient[3*a2+2] += sinTerm * (dCos_dT[0] * (r[1].y - r[0].y)
                   + dCos_dT[1] * (r[0].x - r[1].x)
                   + dCos_dT[3] * (-r[3].y)
                   + dCos_dT[4] * (r[3].x));

           gradient[3*a3+0] += sinTerm * (dCos_dT[1] * (r[0].z)
                   + dCos_dT[2] * (-r[0].y)
                   + dCos_dT[4] * (r[3].z - r[2].z)
                   + dCos_dT[5] * (r[2].y - r[3].y));
           gradient[3*a3+1] += sinTerm * (dCos_dT[0] * (-r[0].z)
                   + dCos_dT[2] * (r[0].x)
                   + dCos_dT[3] * (r[2].z - r[3].z)
                   + dCos_dT[5] * (r[3].x - r[2].x));
           gradient[3*a3+2] += sinTerm * (dCos_dT[0] * (r[0].y)
                   + dCos_dT[1] * (-r[0].x)
                   + dCos_dT[3] * (r[3].y - r[2].y)
                   + dCos_dT[4] * (r[2].x - r[3].x));
           
           if(rearAtoms!=null) {
	           if(rearAtoms[1]!=null) {
	        	   double derX = sinTerm * (dCos_dT[4] * r[2].z - dCos_dT[5] * r[2].y);
	        	   double derY = sinTerm * (dCos_dT[5] * r[2].x - dCos_dT[3] * r[2].z);
	        	   double derZ = sinTerm * (dCos_dT[3] * r[2].y - dCos_dT[4] * r[2].x);
	        	   gradient[3*rearAtoms[1][0]] -= derX;
	        	   gradient[3*rearAtoms[1][0]+1] -= derY;
	        	   gradient[3*rearAtoms[1][0]+2] -= derZ;
	        	   gradient[3*rearAtoms[1][1]] -= derX;
	        	   gradient[3*rearAtoms[1][1]+1] -= derY;
	        	   gradient[3*rearAtoms[1][1]+2] -= derZ;
	           }   
	           else {
	        	   gradient[3*a4+0] += sinTerm * (dCos_dT[4] * r[2].z - dCos_dT[5] * r[2].y);
	        	   gradient[3*a4+1] += sinTerm * (dCos_dT[5] * r[2].x - dCos_dT[3] * r[2].z);
	        	   gradient[3*a4+2] += sinTerm * (dCos_dT[3] * r[2].y - dCos_dT[4] * r[2].x);
	           }
           }
	}


	@Override
	public final double getFGValue(final double[] gradient) {
		for(int i=0;i