double InterMolecularTorsions::compute( const unsigned& tindex, multicolvar::AtomValuePack& myatoms ) const { Vector v1, v2, dv1, dv2, dconn, conn = getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); // Retrieve vectors std::vector<double> orient0( 5 ), orient1( 5 ); getInputData( 0, true, myatoms, orient0 ); getInputData( 1, true, myatoms, orient1 ); for(unsigned i=0; i<3; ++i) { v1[i]=orient0[2+i]; v2[i]=orient1[2+i]; } if( getBaseMultiColvar(0)->getNumberOfQuantities()<3 ) return 1.0; // Evaluate angle Torsion t; double angle = t.compute( v1, conn, v2, dv1, dconn, dv2 ); for(unsigned i=0; i<3; ++i) { orient0[i+2]=dv1[i]; orient1[i+2]=dv2[i]; } // And accumulate derivatives if( !doNotCalculateDerivatives() ) { MultiValue& myder0=getInputDerivatives( 0, true, myatoms ); mergeInputDerivatives( 1, 2, orient1.size(), 0, orient0, myder0, myatoms ); MultiValue& myder1=getInputDerivatives( 1, true, myatoms ); mergeInputDerivatives( 1, 2, orient0.size(), 1, orient1, myder1, myatoms ); addAtomDerivatives( 1, 0, -dconn, myatoms ); addAtomDerivatives( 1, 1, dconn, myatoms ); myatoms.addBoxDerivatives( 1, -extProduct( conn, dconn ) ); } return angle; }
double ContactAlignedMatrix::compute( const unsigned& tindex, multicolvar::AtomValuePack& myatoms ) const { double f_dot, dot_df; std::vector<double> orient0(ncomp), orient1(ncomp); getOrientationVector( myatoms.getIndex(0), true, orient0 ); getOrientationVector( myatoms.getIndex(1), true, orient1 ); double dot=0; for(unsigned k=2;k<orient0.size();++k) dot+=orient0[k]*orient1[k]; f_dot=0.5*( 1 + dot ); dot_df=0.5; // Retrieve the weight of the connection double weight = myatoms.getValue(0); myatoms.setValue(0,1.0); if( !doNotCalculateDerivatives() ){ Vector distance = getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); double dfunc, sw = switchingFunction( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).calculate( distance.modulo(), dfunc ); addAtomDerivatives( 1, 0, (-dfunc)*f_dot*distance, myatoms ); addAtomDerivatives( 1, 1, (+dfunc)*f_dot*distance, myatoms ); myatoms.addBoxDerivatives( 1, (-dfunc)*f_dot*Tensor(distance,distance) ); // Add derivatives of orientation for(unsigned k=2;k<orient0.size();++k){ orient0[k]*=sw*dot_df; orient1[k]*=sw*dot_df; } addOrientationDerivatives( 1, 0, orient1, myatoms ); addOrientationDerivatives( 1, 1, orient0, myatoms ); } return weight*f_dot; }
double ContactMatrix::compute( const unsigned& tindex, multicolvar::AtomValuePack& myatoms ) const { if( !doNotCalculateDerivatives() ){ Vector distance = getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); double dfunc, sw = switchingFunction( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) - ncol_t ).calculate( distance.modulo(), dfunc ); addAtomDerivatives( 1, 0, (-dfunc)*distance, myatoms ); addAtomDerivatives( 1, 1, (+dfunc)*distance, myatoms ); myatoms.addBoxDerivatives( 1, (-dfunc)*Tensor(distance,distance) ); } double val=myatoms.getValue(0); myatoms.setValue(0,1.0); return val; }
double TopologyMatrix::compute( const unsigned& tindex, multicolvar::AtomValuePack& myatoms ) const { HistogramBead bead; bead.isNotPeriodic(); bead.setKernelType( kerneltype ); // Initialise to zero density on all bins for(unsigned bin=0; bin<maxbins; ++bin) myatoms.setValue(bin+1,0); // Calculate whether or not atoms 1 and 2 are within cutoff (can use delta here as pbc are done in atom setup) Vector d1 = getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); double d1_len = d1.modulo(); d1 = d1 / d1_len; // Convert vector into director AtomNumber a1 = myatoms.getAbsoluteIndex( 0 ); AtomNumber a2 = myatoms.getAbsoluteIndex( 1 ); for(unsigned i=2; i<myatoms.getNumberOfAtoms(); ++i) { AtomNumber a3 = myatoms.getAbsoluteIndex( i ); if( a3!=a1 && a3!=a2 ) calculateForThreeAtoms( i, d1, d1_len, bead, myatoms ); } // std::vector<double> binvals( 1+maxbins ); for(unsigned i=1;i<maxbins;++i) binvals[i]=myatoms.getValue(i); // unsigned ii; double fdf; //std::cout<<"HELLO DENSITY "<<myatoms.getIndex(0)<<" "<<myatoms.getIndex(1)<<" "<<transformStoredValues( binvals, ii, fdf )<<std::endl; // Now find the element for which the density is maximal unsigned vout=2; double max=myatoms.getValue( 2 ); for(unsigned i=3; i<myatoms.getUnderlyingMultiValue().getNumberOfValues()-1; ++i) { if( myatoms.getValue(i)>max ) { max=myatoms.getValue(i); vout=i; } } // Calculate value and derivative of switching function between atoms 1 and 2 double dfuncl, sw = switchingFunction( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).calculate( d1_len, dfuncl ); // Transform the density double df, tsw = threshold_switch.calculate( max, df ); if( !doNotCalculateDerivatives() ) { // Factor of d1_len is required here because d1 is normalized d1 *= d1_len; addAtomDerivatives( 2+maxbins, 0, -dfuncl*d1, myatoms ); addAtomDerivatives( 2+maxbins, 1, dfuncl*d1, myatoms ); myatoms.addBoxDerivatives( 2+maxbins, (-dfuncl)*Tensor(d1,d1) ); // Update active atoms so that next bit works updateActiveAtoms( myatoms ); // Now finish caclulation of derivatives MultiValue& myvals=myatoms.getUnderlyingMultiValue(); for(unsigned jd=0; jd<myvals.getNumberActive(); ++jd) { unsigned ider=myvals.getActiveIndex(jd); myvals.addDerivative( 1, ider, sw*df*max*myvals.getDerivative( vout, ider ) + tsw*myvals.getDerivative( 2+maxbins, ider ) ); } } return sw*tsw; }
void BondOrientation::calculateVector( multicolvar::AtomValuePack& myatoms ) const { Vector distance=getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); addAtomDerivatives( 2, 0, Vector(-1.0,0,0), myatoms ); addAtomDerivatives( 2, 1, Vector(+1.0,0,0), myatoms ); myatoms.addBoxDerivatives( 2, Tensor(distance,Vector(-1.0,0,0)) ); myatoms.addValue( 2, distance[0] ); addAtomDerivatives( 3, 0, Vector(0,-1.0,0), myatoms ); addAtomDerivatives( 3, 1, Vector(0,+1.0,0), myatoms ); myatoms.addBoxDerivatives( 3, Tensor(distance,Vector(0,-1.0,0)) ); myatoms.addValue( 3, distance[1] ); addAtomDerivatives( 4, 0, Vector(0,0,-1.0), myatoms ); addAtomDerivatives( 4, 1, Vector(0,0,+1.0), myatoms ); myatoms.addBoxDerivatives( 4, Tensor(distance,Vector(0,0,-1.0)) ); myatoms.addValue( 4, distance[2] ); }
double OrientationSphere::compute( const unsigned& tindex, multicolvar::AtomValuePack& myatoms ) const { // Make sure derivatives for central atom are only calculated once VectorMultiColvar* vv = dynamic_cast<VectorMultiColvar*>( getBaseMultiColvar(0) ); vv->firstcall=true; double d2, sw, value=0, denom=0, dot, f_dot, dot_df, dfunc; unsigned ncomponents=getBaseMultiColvar(0)->getNumberOfQuantities(); unsigned nder=myatoms.getNumberOfDerivatives(); std::vector<double> catom_orient( ncomponents ), this_orient( ncomponents ), catom_der( ncomponents ); Vector catom_pos = myatoms.getPosition(0); getVectorForTask( myatoms.getIndex(0), true, catom_orient ); multicolvar::CatomPack atom0; MultiValue myder0(0,0), myder1(0,0); if( !doNotCalculateDerivatives() ){ myder0.resize( ncomponents,nder ); myder1.resize(ncomponents,nder); atom0=getCentralAtomPackFromInput( myatoms.getIndex(0) ); getVectorDerivatives( myatoms.getIndex(0), true, myder0 ); } for(unsigned i=1;i<myatoms.getNumberOfAtoms();++i){ Vector& distance=myatoms.getPosition(i); if ( (d2=distance[0]*distance[0])<rcut2 && (d2+=distance[1]*distance[1])<rcut2 && (d2+=distance[2]*distance[2])<rcut2) { sw = switchingFunction.calculateSqr( d2, dfunc ); getVectorForTask( myatoms.getIndex(i), true, this_orient ); // Calculate the dot product wrt to this position dot=0; for(unsigned k=2;k<catom_orient.size();++k) dot+=catom_orient[k]*this_orient[k]; f_dot = transformDotProduct( dot, dot_df ); if( !doNotCalculateDerivatives() ){ // N.B. We are assuming here that the imaginary part of the dot product is zero for(unsigned k=2;k<catom_orient.size();++k){ this_orient[k]*=sw*dot_df; catom_der[k]=sw*dot_df*catom_orient[k]; } getVectorDerivatives( myatoms.getIndex(i), true, myder1 ); mergeVectorDerivatives( 1, 2, this_orient.size(), myatoms.getIndex(0), this_orient, myder0, myatoms ); mergeVectorDerivatives( 1, 2, catom_der.size(), myatoms.getIndex(i), catom_der, myder1, myatoms ); myatoms.addComDerivatives( 1, f_dot*(-dfunc)*distance, atom0 ); addAtomDerivatives( 1, i, f_dot*(dfunc)*distance, myatoms ); myatoms.addBoxDerivatives( 1, (-dfunc)*f_dot*Tensor(distance,distance) ); myder1.clearAll(); myatoms.addComDerivatives( -1, (-dfunc)*distance, atom0 ); addAtomDerivatives( -1, i, (dfunc)*distance, myatoms ); myatoms.addTemporyBoxDerivatives( (-dfunc)*Tensor(distance,distance) ); } value += sw*f_dot; denom += sw; } } double rdenom, df2, pref=calculateCoordinationPrefactor( denom, df2 ); if( fabs(denom)>epsilon ){ rdenom = 1.0 / denom; } else { plumed_assert(fabs(value)<epsilon); rdenom=1.0; } // Now divide everything double rdenom2=rdenom*rdenom; updateActiveAtoms( myatoms ); MultiValue& myvals=myatoms.getUnderlyingMultiValue(); for(unsigned i=0;i<myvals.getNumberActive();++i){ unsigned ider=myvals.getActiveIndex(i); double dgd=myvals.getTemporyDerivative(ider); myvals.setDerivative( 1, ider, rdenom*(pref*myvals.getDerivative(1,ider)+value*df2*dgd) - (value*pref*dgd)*rdenom2 ); } return pref*rdenom*value; }
void ContactAlignedMatrix::calculateWeight( const unsigned& taskCode, multicolvar::AtomValuePack& myatoms ) const { Vector distance = getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); double dfunc, sw = switchingFunction( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).calculate( distance.modulo(), dfunc ); myatoms.setValue(0,sw); }
void Steinhardt::calculateVector( multicolvar::AtomValuePack& myatoms ) const { double dfunc, dpoly_ass, md, tq6, itq6, real_z, imag_z; Vector dz, myrealvec, myimagvec, real_dz, imag_dz; // The square root of -1 std::complex<double> ii( 0.0, 1.0 ), dp_x, dp_y, dp_z; unsigned ncomp=2*tmom+1; double sw, poly_ass, d2, dlen, nbond=0.0; std::complex<double> powered; for(unsigned i=1;i<myatoms.getNumberOfAtoms();++i){ Vector& distance=myatoms.getPosition(i); // getSeparation( myatoms.getPosition(0), myatoms.getPosition(i) ); if ( (d2=distance[0]*distance[0])<rcut2 && (d2+=distance[1]*distance[1])<rcut2 && (d2+=distance[2]*distance[2])<rcut2) { dlen = sqrt(d2); sw = switchingFunction.calculate( dlen, dfunc ); nbond += sw; // Accumulate total number of bonds double dlen3 = d2*dlen; // Store derivatives of weight addAtomDerivatives( -1, 0, (-dfunc)*distance, myatoms ); addAtomDerivatives( -1, i, (+dfunc)*distance, myatoms ); myatoms.addTemporyBoxDerivatives( (-dfunc)*Tensor( distance,distance ) ); // Do stuff for m=0 poly_ass=deriv_poly( 0, distance[2]/dlen, dpoly_ass ); // Derivatives of z/r wrt x, y, z dz = -( distance[2] / dlen3 )*distance; dz[2] += (1.0 / dlen); // Derivative wrt to the vector connecting the two atoms myrealvec = (+sw)*dpoly_ass*dz + poly_ass*(+dfunc)*distance; // Accumulate the derivatives addAtomDerivatives( 2 + tmom, 0, -myrealvec, myatoms ); addAtomDerivatives( 2 + tmom, i, myrealvec, myatoms); myatoms.addBoxDerivatives( 2 + tmom, Tensor( -myrealvec,distance ) ); // And store the vector function myatoms.addValue( 2 + tmom, sw*poly_ass ); // The complex number of which we have to take powers std::complex<double> com1( distance[0]/dlen ,distance[1]/dlen ); // Do stuff for all other m values for(unsigned m=1;m<=tmom;++m){ // Calculate Legendre Polynomial poly_ass=deriv_poly( m, distance[2]/dlen, dpoly_ass ); // Calculate powe of complex number powered=pow(com1,m-1); md=static_cast<double>(m); // Real and imaginary parts of z real_z = real(com1*powered); imag_z = imag(com1*powered ); // Calculate steinhardt parameter tq6=poly_ass*real_z; // Real part of steinhardt parameter itq6=poly_ass*imag_z; // Imaginary part of steinhardt parameter // Derivatives wrt ( x/r + iy )^m dp_x = md*powered*( (1.0/dlen)-(distance[0]*distance[0])/dlen3-ii*(distance[0]*distance[1])/dlen3 ); dp_y = md*powered*( ii*(1.0/dlen)-(distance[0]*distance[1])/dlen3-ii*(distance[1]*distance[1])/dlen3 ); dp_z = md*powered*( -(distance[0]*distance[2])/dlen3-ii*(distance[1]*distance[2])/dlen3 ); // Derivatives of real and imaginary parts of above real_dz[0] = real( dp_x ); real_dz[1] = real( dp_y ); real_dz[2] = real( dp_z ); imag_dz[0] = imag( dp_x ); imag_dz[1] = imag( dp_y ); imag_dz[2] = imag( dp_z ); // Complete derivative of steinhardt parameter myrealvec = (+sw)*dpoly_ass*real_z*dz + (+dfunc)*distance*tq6 + (+sw)*poly_ass*real_dz; myimagvec = (+sw)*dpoly_ass*imag_z*dz + (+dfunc)*distance*itq6 + (+sw)*poly_ass*imag_dz; // Real part myatoms.addValue( 2+tmom+m, sw*tq6 ); addAtomDerivatives( 2+tmom+m, 0, -myrealvec, myatoms ); addAtomDerivatives( 2+tmom+m, i, myrealvec, myatoms ); myatoms.addBoxDerivatives( 2+tmom+m, Tensor( -myrealvec,distance ) ); // Imaginary part myatoms.addValue( 2+ncomp+tmom+m, sw*itq6 ); addAtomDerivatives( 2+ncomp+tmom+m, 0, -myimagvec, myatoms ); addAtomDerivatives( 2+ncomp+tmom+m, i, myimagvec, myatoms ); myatoms.addBoxDerivatives( 2+ncomp+tmom+m, Tensor( -myimagvec,distance ) ); // Store -m part of vector double pref=pow(-1.0,m); // -m part of vector is just +m part multiplied by (-1.0)**m and multiplied by complex // conjugate of Legendre polynomial // Real part myatoms.addValue( 2+tmom-m, pref*sw*tq6 ); addAtomDerivatives( 2+tmom-m, 0, -pref*myrealvec, myatoms ); addAtomDerivatives( 2+tmom-m, i, pref*myrealvec, myatoms ); myatoms.addBoxDerivatives( 2+tmom-m, pref*Tensor( -myrealvec,distance ) ); // Imaginary part myatoms.addValue( 2+ncomp+tmom-m, -pref*sw*itq6 ); addAtomDerivatives( 2+ncomp+tmom-m, 0, pref*myimagvec, myatoms ); addAtomDerivatives( 2+ncomp+tmom-m, i, -pref*myimagvec, myatoms ); myatoms.addBoxDerivatives( 2+ncomp+tmom-m, pref*Tensor( myimagvec,distance ) ); } } } // Normalize updateActiveAtoms( myatoms ); for(unsigned i=0;i<getNumberOfComponentsInVector();++i) myatoms.getUnderlyingMultiValue().quotientRule( 2+i, nbond, 2+i ); }
double ContactMatrix::calculateWeight( const unsigned& taskCode, const double& weight, multicolvar::AtomValuePack& myatoms ) const { Vector distance = getSeparation( myatoms.getPosition(0), myatoms.getPosition(1) ); if( distance.modulo2()<switchingFunction( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) - ncol_t ).get_dmax2() ) return 1.0; return 0.0; }
void TopologyMatrix::calculateForThreeAtoms( const unsigned& iat, const Vector& d1, const double& d1_len, HistogramBead& bead, multicolvar::AtomValuePack& myatoms ) const { // Calculate if there are atoms in the cylinder (can use delta here as pbc are done in atom setup) Vector d2 = getSeparation( myatoms.getPosition(0), myatoms.getPosition(iat) ); // Now calculate projection of d2 on d1 double proj=dotProduct(d2,d1); // This tells us if we are outside the end of the cylinder double excess = proj - d1_len; // Return if we are outside of the cylinder as calculated based on excess if( excess>low_sf( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).get_dmax() ) return; // Find the length of the cylinder double binw = binw_mat( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ); double lcylinder = (std::floor( d1_len / binw ) + 1)*binw; // Return if the projection is outside the length of interest if( proj<-bead.getCutoff() || proj>(lcylinder+bead.getCutoff()) ) return; // Calculate the excess swiching function double edf, eval = low_sf( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).calculate( excess, edf ); // Calculate the projection on the perpendicular distance from the center of the tube double cm = d2.modulo2() - proj*proj; // Now calculate the density in the cylinder if( cm<cylinder_sw( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).get_dmax2() ) { double dfuncr, val = cylinder_sw( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ).calculateSqr( cm, dfuncr ); double cellv = cell_volume( getBaseColvarNumber( myatoms.getIndex(0) ), getBaseColvarNumber( myatoms.getIndex(1) ) ); Vector dc1, dc2, dc3, dd1, dd2, dd3, de1, de2, de3; if( !doNotCalculateDerivatives() ) { Tensor d1_a1; // Derivative of director connecting atom1 - atom2 wrt the position of atom 1 d1_a1(0,0) = ( -(d1[1]*d1[1]+d1[2]*d1[2])/d1_len ); // dx/dx d1_a1(0,1) = ( d1[0]*d1[1]/d1_len ); // dx/dy d1_a1(0,2) = ( d1[0]*d1[2]/d1_len ); // dx/dz d1_a1(1,0) = ( d1[1]*d1[0]/d1_len ); // dy/dx d1_a1(1,1) = ( -(d1[0]*d1[0]+d1[2]*d1[2])/d1_len ); // dy/dy d1_a1(1,2) = ( d1[1]*d1[2]/d1_len ); d1_a1(2,0) = ( d1[2]*d1[0]/d1_len ); d1_a1(2,1) = ( d1[2]*d1[1]/d1_len ); d1_a1(2,2) = ( -(d1[1]*d1[1]+d1[0]*d1[0])/d1_len ); // Calculate derivatives of dot product dd1 = matmul(d2, d1_a1) - d1; dd2 = matmul(d2, -d1_a1); dd3 = d1; // Calculate derivatives of cross product dc1 = dfuncr*( -d2 - proj*dd1 ); dc2 = dfuncr*( -proj*dd2 ); dc3 = dfuncr*( d2 - proj*dd3 ); // Calculate derivatives of excess de1 = edf*excess*( dd1 + d1 ); de2 = edf*excess*( dd2 - d1 ); de3 = edf*excess*dd3; } Vector pos1 = myatoms.getPosition(0) + d1_len*d1; Vector pos2 = myatoms.getPosition(0) + d2; Vector g1derivf,g2derivf,lderivf; Tensor vir; for(unsigned bin=0; bin<maxbins; ++bin) { bead.set( bin*binw, (bin+1)*binw, sigma ); if( proj<(bin*binw-bead.getCutoff()) || proj>binw*(bin+1)+bead.getCutoff() ) continue; double der, contr=bead.calculateWithCutoff( proj, der ) / cellv; der /= cellv; myatoms.addValue( 2+bin, contr*val*eval ); if( !doNotCalculateDerivatives() ) { g1derivf=contr*eval*dc1 + val*eval*der*dd1 + contr*val*de1; addAtomDerivatives( 2+bin, 0, g1derivf, myatoms ); g2derivf=contr*eval*dc2 + val*eval*der*dd2 + contr*val*de2; addAtomDerivatives( 2+bin, 1, g2derivf, myatoms ); lderivf=contr*eval*dc3 + val*eval*der*dd3 + contr*val*de3; addAtomDerivatives( 2+bin, iat, lderivf, myatoms ); // Virial vir = -Tensor( myatoms.getPosition(0), g1derivf ) - Tensor( pos1, g2derivf ) - Tensor( pos2, lderivf ); myatoms.addBoxDerivatives( 2+bin, vir ); } } } }