/* * molecule_geometry.cpp * * Created on: Oct 5, 2009 * Author: heber */ #include "atom.hpp" #include "bond.hpp" #include "config.hpp" #include "element.hpp" #include "helpers.hpp" #include "leastsquaremin.hpp" #include "log.hpp" #include "memoryallocator.hpp" #include "molecule.hpp" /************************************* Functions for class molecule *********************************/ /** Centers the molecule in the box whose lengths are defined by vector \a *BoxLengths. * \param *out output stream for debugging */ bool molecule::CenterInBox() { bool status = true; const Vector *Center = DetermineCenterOfAll(); double *M = ReturnFullMatrixforSymmetric(cell_size); double *Minv = InverseMatrix(M); // go through all atoms ActOnAllVectors( &Vector::SubtractVector, Center); ActOnAllVectors( &Vector::WrapPeriodically, (const double *)M, (const double *)Minv); Free(&M); Free(&Minv); delete(Center); return status; }; /** Bounds the molecule in the box whose lengths are defined by vector \a *BoxLengths. * \param *out output stream for debugging */ bool molecule::BoundInBox() { bool status = true; double *M = ReturnFullMatrixforSymmetric(cell_size); double *Minv = InverseMatrix(M); // go through all atoms ActOnAllVectors( &Vector::WrapPeriodically, (const double *)M, (const double *)Minv); Free(&M); Free(&Minv); return status; }; /** Centers the edge of the atoms at (0,0,0). * \param *out output stream for debugging * \param *max coordinates of other edge, specifying box dimensions. */ void molecule::CenterEdge(Vector *max) { Vector *min = new Vector; // Log() << Verbose(3) << "Begin of CenterEdge." << endl; atom *ptr = start->next; // start at first in list if (ptr != end) { //list not empty? for (int i=NDIM;i--;) { max->x[i] = ptr->x.x[i]; min->x[i] = ptr->x.x[i]; } while (ptr->next != end) { // continue with second if present ptr = ptr->next; //ptr->Output(1,1,out); for (int i=NDIM;i--;) { max->x[i] = (max->x[i] < ptr->x.x[i]) ? ptr->x.x[i] : max->x[i]; min->x[i] = (min->x[i] > ptr->x.x[i]) ? ptr->x.x[i] : min->x[i]; } } // Log() << Verbose(4) << "Maximum is "; // max->Output(out); // Log() << Verbose(0) << ", Minimum is "; // min->Output(out); // Log() << Verbose(0) << endl; min->Scale(-1.); max->AddVector(min); Translate(min); Center.Zero(); } delete(min); // Log() << Verbose(3) << "End of CenterEdge." << endl; }; /** Centers the center of the atoms at (0,0,0). * \param *out output stream for debugging * \param *center return vector for translation vector */ void molecule::CenterOrigin() { int Num = 0; atom *ptr = start->next; // start at first in list Center.Zero(); if (ptr != end) { //list not empty? while (ptr->next != end) { // continue with second if present ptr = ptr->next; Num++; Center.AddVector(&ptr->x); } Center.Scale(-1./Num); // divide through total number (and sign for direction) Translate(&Center); Center.Zero(); } }; /** Returns vector pointing to center of all atoms. * \return pointer to center of all vector */ Vector * molecule::DetermineCenterOfAll() const { atom *ptr = start->next; // start at first in list Vector *a = new Vector(); Vector tmp; double Num = 0; a->Zero(); if (ptr != end) { //list not empty? while (ptr->next != end) { // continue with second if present ptr = ptr->next; Num += 1.; tmp.CopyVector(&ptr->x); a->AddVector(&tmp); } a->Scale(1./Num); // divide through total mass (and sign for direction) } return a; }; /** Returns vector pointing to center of gravity. * \param *out output stream for debugging * \return pointer to center of gravity vector */ Vector * molecule::DetermineCenterOfGravity() { atom *ptr = start->next; // start at first in list Vector *a = new Vector(); Vector tmp; double Num = 0; a->Zero(); if (ptr != end) { //list not empty? while (ptr->next != end) { // continue with second if present ptr = ptr->next; Num += ptr->type->mass; tmp.CopyVector(&ptr->x); tmp.Scale(ptr->type->mass); // scale by mass a->AddVector(&tmp); } a->Scale(-1./Num); // divide through total mass (and sign for direction) } // Log() << Verbose(1) << "Resulting center of gravity: "; // a->Output(out); // Log() << Verbose(0) << endl; return a; }; /** Centers the center of gravity of the atoms at (0,0,0). * \param *out output stream for debugging * \param *center return vector for translation vector */ void molecule::CenterPeriodic() { DeterminePeriodicCenter(Center); }; /** Centers the center of gravity of the atoms at (0,0,0). * \param *out output stream for debugging * \param *center return vector for translation vector */ void molecule::CenterAtVector(Vector *newcenter) { Center.CopyVector(newcenter); }; /** Scales all atoms by \a *factor. * \param *factor pointer to scaling factor */ void molecule::Scale(const double ** const factor) { atom *ptr = start; while (ptr->next != end) { ptr = ptr->next; for (int j=0;jTrajectory.R.at(j).Scale(factor); ptr->x.Scale(factor); } }; /** Translate all atoms by given vector. * \param trans[] translation vector. */ void molecule::Translate(const Vector *trans) { atom *ptr = start; while (ptr->next != end) { ptr = ptr->next; for (int j=0;jTrajectory.R.at(j).Translate(trans); ptr->x.Translate(trans); } }; /** Translate the molecule periodically in the box. * \param trans[] translation vector. * TODO treatment of trajetories missing */ void molecule::TranslatePeriodically(const Vector *trans) { double *M = ReturnFullMatrixforSymmetric(cell_size); double *Minv = InverseMatrix(M); // go through all atoms ActOnAllVectors( &Vector::SubtractVector, trans); ActOnAllVectors( &Vector::WrapPeriodically, (const double *)M, (const double *)Minv); Free(&M); Free(&Minv); }; /** Mirrors all atoms against a given plane. * \param n[] normal vector of mirror plane. */ void molecule::Mirror(const Vector *n) { ActOnAllVectors( &Vector::Mirror, n ); }; /** Determines center of molecule (yet not considering atom masses). * \param center reference to return vector */ void molecule::DeterminePeriodicCenter(Vector ¢er) { atom *Walker = start; double *matrix = ReturnFullMatrixforSymmetric(cell_size); double *inversematrix = InverseMatrix(cell_size); double tmp; bool flag; Vector Testvector, Translationvector; do { Center.Zero(); flag = true; while (Walker->next != end) { Walker = Walker->next; #ifdef ADDHYDROGEN if (Walker->type->Z != 1) { #endif Testvector.CopyVector(&Walker->x); Testvector.MatrixMultiplication(inversematrix); Translationvector.Zero(); for (BondList::const_iterator Runner = Walker->ListOfBonds.begin(); Runner != Walker->ListOfBonds.end(); (++Runner)) { if (Walker->nr < (*Runner)->GetOtherAtom(Walker)->nr) // otherwise we shift one to, the other fro and gain nothing for (int j=0;jx.x[j] - (*Runner)->GetOtherAtom(Walker)->x.x[j]; if ((fabs(tmp)) > BondDistance) { flag = false; Log() << Verbose(0) << "Hit: atom " << Walker->Name << " in bond " << *(*Runner) << " has to be shifted due to " << tmp << "." << endl; if (tmp > 0) Translationvector.x[j] -= 1.; else Translationvector.x[j] += 1.; } } } Testvector.AddVector(&Translationvector); Testvector.MatrixMultiplication(matrix); Center.AddVector(&Testvector); Log() << Verbose(1) << "vector is: "; Testvector.Output(); Log() << Verbose(0) << endl; #ifdef ADDHYDROGEN // now also change all hydrogens for (BondList::const_iterator Runner = Walker->ListOfBonds.begin(); Runner != Walker->ListOfBonds.end(); (++Runner)) { if ((*Runner)->GetOtherAtom(Walker)->type->Z == 1) { Testvector.CopyVector(&(*Runner)->GetOtherAtom(Walker)->x); Testvector.MatrixMultiplication(inversematrix); Testvector.AddVector(&Translationvector); Testvector.MatrixMultiplication(matrix); Center.AddVector(&Testvector); Log() << Verbose(1) << "Hydrogen vector is: "; Testvector.Output(); Log() << Verbose(0) << endl; } } } #endif } } while (!flag); Free(&matrix); Free(&inversematrix); Center.Scale(1./(double)AtomCount); }; /** Transforms/Rotates the given molecule into its principal axis system. * \param *out output stream for debugging * \param DoRotate whether to rotate (true) or only to determine the PAS. * TODO treatment of trajetories missing */ void molecule::PrincipalAxisSystem(bool DoRotate) { atom *ptr = start; // start at first in list double InertiaTensor[NDIM*NDIM]; Vector *CenterOfGravity = DetermineCenterOfGravity(); CenterPeriodic(); // reset inertia tensor for(int i=0;inext != end) { ptr = ptr->next; Vector x; x.CopyVector(&ptr->x); //x.SubtractVector(CenterOfGravity); InertiaTensor[0] += ptr->type->mass*(x.x[1]*x.x[1] + x.x[2]*x.x[2]); InertiaTensor[1] += ptr->type->mass*(-x.x[0]*x.x[1]); InertiaTensor[2] += ptr->type->mass*(-x.x[0]*x.x[2]); InertiaTensor[3] += ptr->type->mass*(-x.x[1]*x.x[0]); InertiaTensor[4] += ptr->type->mass*(x.x[0]*x.x[0] + x.x[2]*x.x[2]); InertiaTensor[5] += ptr->type->mass*(-x.x[1]*x.x[2]); InertiaTensor[6] += ptr->type->mass*(-x.x[2]*x.x[0]); InertiaTensor[7] += ptr->type->mass*(-x.x[2]*x.x[1]); InertiaTensor[8] += ptr->type->mass*(x.x[0]*x.x[0] + x.x[1]*x.x[1]); } // print InertiaTensor for debugging Log() << Verbose(0) << "The inertia tensor is:" << endl; for(int i=0;idata[i * evec->tda + 0] << "," << evec->data[i * evec->tda + 1] << "," << evec->data[i * evec->tda + 2] << ")" << endl; } // check whether we rotate or not if (DoRotate) { Log() << Verbose(1) << "Transforming molecule into PAS ... "; // the eigenvectors specify the transformation matrix ActOnAllVectors( &Vector::MatrixMultiplication, (const double *) evec->data ); Log() << Verbose(0) << "done." << endl; // summing anew for debugging (resulting matrix has to be diagonal!) // reset inertia tensor for(int i=0;inext != end) { ptr = ptr->next; Vector x; x.CopyVector(&ptr->x); //x.SubtractVector(CenterOfGravity); InertiaTensor[0] += ptr->type->mass*(x.x[1]*x.x[1] + x.x[2]*x.x[2]); InertiaTensor[1] += ptr->type->mass*(-x.x[0]*x.x[1]); InertiaTensor[2] += ptr->type->mass*(-x.x[0]*x.x[2]); InertiaTensor[3] += ptr->type->mass*(-x.x[1]*x.x[0]); InertiaTensor[4] += ptr->type->mass*(x.x[0]*x.x[0] + x.x[2]*x.x[2]); InertiaTensor[5] += ptr->type->mass*(-x.x[1]*x.x[2]); InertiaTensor[6] += ptr->type->mass*(-x.x[2]*x.x[0]); InertiaTensor[7] += ptr->type->mass*(-x.x[2]*x.x[1]); InertiaTensor[8] += ptr->type->mass*(x.x[0]*x.x[0] + x.x[1]*x.x[1]); } // print InertiaTensor for debugging Log() << Verbose(0) << "The inertia tensor is:" << endl; for(int i=0;ix[0]/n->x[2]); Log() << Verbose(1) << "Z-X-angle: " << alpha << " ... "; while (ptr->next != end) { ptr = ptr->next; tmp = ptr->x.x[0]; ptr->x.x[0] = cos(alpha) * tmp + sin(alpha) * ptr->x.x[2]; ptr->x.x[2] = -sin(alpha) * tmp + cos(alpha) * ptr->x.x[2]; for (int j=0;jTrajectory.R.at(j).x[0]; ptr->Trajectory.R.at(j).x[0] = cos(alpha) * tmp + sin(alpha) * ptr->Trajectory.R.at(j).x[2]; ptr->Trajectory.R.at(j).x[2] = -sin(alpha) * tmp + cos(alpha) * ptr->Trajectory.R.at(j).x[2]; } } // rotate n vector tmp = n->x[0]; n->x[0] = cos(alpha) * tmp + sin(alpha) * n->x[2]; n->x[2] = -sin(alpha) * tmp + cos(alpha) * n->x[2]; Log() << Verbose(1) << "alignment vector after first rotation: "; n->Output(); Log() << Verbose(0) << endl; // rotate on z-y plane ptr = start; alpha = atan(-n->x[1]/n->x[2]); Log() << Verbose(1) << "Z-Y-angle: " << alpha << " ... "; while (ptr->next != end) { ptr = ptr->next; tmp = ptr->x.x[1]; ptr->x.x[1] = cos(alpha) * tmp + sin(alpha) * ptr->x.x[2]; ptr->x.x[2] = -sin(alpha) * tmp + cos(alpha) * ptr->x.x[2]; for (int j=0;jTrajectory.R.at(j).x[1]; ptr->Trajectory.R.at(j).x[1] = cos(alpha) * tmp + sin(alpha) * ptr->Trajectory.R.at(j).x[2]; ptr->Trajectory.R.at(j).x[2] = -sin(alpha) * tmp + cos(alpha) * ptr->Trajectory.R.at(j).x[2]; } } // rotate n vector (for consistency check) tmp = n->x[1]; n->x[1] = cos(alpha) * tmp + sin(alpha) * n->x[2]; n->x[2] = -sin(alpha) * tmp + cos(alpha) * n->x[2]; Log() << Verbose(1) << "alignment vector after second rotation: "; n->Output(); Log() << Verbose(1) << endl; Log() << Verbose(0) << "End of Aligning all atoms." << endl; }; /** Calculates sum over least square distance to line hidden in \a *x. * \param *x offset and direction vector * \param *params pointer to lsq_params structure * \return \f$ sum_i^N | y_i - (a + t_i b)|^2\f$ */ double LeastSquareDistance (const gsl_vector * x, void * params) { double res = 0, t; Vector a,b,c,d; struct lsq_params *par = (struct lsq_params *)params; atom *ptr = par->mol->start; // initialize vectors a.x[0] = gsl_vector_get(x,0); a.x[1] = gsl_vector_get(x,1); a.x[2] = gsl_vector_get(x,2); b.x[0] = gsl_vector_get(x,3); b.x[1] = gsl_vector_get(x,4); b.x[2] = gsl_vector_get(x,5); // go through all atoms while (ptr != par->mol->end) { ptr = ptr->next; if (ptr->type == ((struct lsq_params *)params)->type) { // for specific type c.CopyVector(&ptr->x); // copy vector to temporary one c.SubtractVector(&a); // subtract offset vector t = c.ScalarProduct(&b); // get direction parameter d.CopyVector(&b); // and create vector d.Scale(&t); c.SubtractVector(&d); // ... yielding distance vector res += d.ScalarProduct((const Vector *)&d); // add squared distance } } return res; }; /** By minimizing the least square distance gains alignment vector. * \bug this is not yet working properly it seems */ void molecule::GetAlignvector(struct lsq_params * par) const { int np = 6; const gsl_multimin_fminimizer_type *T = gsl_multimin_fminimizer_nmsimplex; gsl_multimin_fminimizer *s = NULL; gsl_vector *ss; gsl_multimin_function minex_func; size_t iter = 0, i; int status; double size; /* Initial vertex size vector */ ss = gsl_vector_alloc (np); /* Set all step sizes to 1 */ gsl_vector_set_all (ss, 1.0); /* Starting point */ par->x = gsl_vector_alloc (np); par->mol = this; gsl_vector_set (par->x, 0, 0.0); // offset gsl_vector_set (par->x, 1, 0.0); gsl_vector_set (par->x, 2, 0.0); gsl_vector_set (par->x, 3, 0.0); // direction gsl_vector_set (par->x, 4, 0.0); gsl_vector_set (par->x, 5, 1.0); /* Initialize method and iterate */ minex_func.f = &LeastSquareDistance; minex_func.n = np; minex_func.params = (void *)par; s = gsl_multimin_fminimizer_alloc (T, np); gsl_multimin_fminimizer_set (s, &minex_func, par->x, ss); do { iter++; status = gsl_multimin_fminimizer_iterate(s); if (status) break; size = gsl_multimin_fminimizer_size (s); status = gsl_multimin_test_size (size, 1e-2); if (status == GSL_SUCCESS) { printf ("converged to minimum at\n"); } printf ("%5d ", (int)iter); for (i = 0; i < (size_t)np; i++) { printf ("%10.3e ", gsl_vector_get (s->x, i)); } printf ("f() = %7.3f size = %.3f\n", s->fval, size); } while (status == GSL_CONTINUE && iter < 100); for (i=0;i<(size_t)np;i++) gsl_vector_set(par->x, i, gsl_vector_get(s->x, i)); //gsl_vector_free(par->x); gsl_vector_free(ss); gsl_multimin_fminimizer_free (s); };