[ViewVC] Diff of: OpenMD/branches/development/src/nonbonded/Electrostatic.cpp

Comparing branches/development/src/nonbonded/Electrostatic.cpp (file contents):
Revision 1535 by gezelter, Fri Dec 31 18:31:56 2010 UTC vs.
Revision 1571 by gezelter, Fri May 27 16:45:44 2011 UTC

#	Line 113 \| Line 113 \| namespace OpenMD {
113		} else {
114		// throw error
115		sprintf( painCave.errMsg,
116	<	"SimInfo error: Unknown electrostaticSummationMethod.\n"
116	>	"Electrostatic::initialize: Unknown electrostaticSummationMethod.\n"
117		"\t(Input file specified %s .)\n"
118		"\telectrostaticSummationMethod must be one of: \"none\",\n"
119		"\t\"shifted_potential\", \"shifted_force\", or \n"
#	Line 429 \| Line 429 \| namespace OpenMD {
429		haveDielectric_ = true;
430		}
431
432	<	void Electrostatic::calcForce(InteractionData idat) {
432	>	void Electrostatic::calcForce(InteractionData &idat) {
433
434		// utility variables. Should clean these up and use the Vector3d and
435		// Mat3x3d to replace as many as we can in future versions:
#	Line 463 \| Line 463 \| namespace OpenMD {
463
464		if (!initialized_) initialize();
465
466	<	ElectrostaticAtomData data1 = ElectrostaticMap[idat.atype1];
467	<	ElectrostaticAtomData data2 = ElectrostaticMap[idat.atype2];
466	>	ElectrostaticAtomData data1 = ElectrostaticMap[idat.atypes.first];
467	>	ElectrostaticAtomData data2 = ElectrostaticMap[idat.atypes.second];
468
469		// some variables we'll need independent of electrostatic type:
470
471	<	riji = 1.0 / idat.rij;
472	<	Vector3d rhat = idat.d * riji;
471	>	riji = 1.0 / *(idat.rij) ;
472	>	Vector3d rhat = (idat.d) riji;
473
474		// logicals
475
#	Line 488 \| Line 488 \| namespace OpenMD {
488
489		if (i_is_Dipole) {
490		mu_i = data1.dipole_moment;
491	<	uz_i = idat.eFrame1.getColumn(2);
491	>	uz_i = idat.eFrame1->getColumn(2);
492
493		ct_i = dot(uz_i, rhat);
494
#	Line 504 \| Line 504 \| namespace OpenMD {
504		qyy_i = Q_i.y();
505		qzz_i = Q_i.z();
506
507	<	ux_i = idat.eFrame1.getColumn(0);
508	<	uy_i = idat.eFrame1.getColumn(1);
509	<	uz_i = idat.eFrame1.getColumn(2);
507	>	ux_i = idat.eFrame1->getColumn(0);
508	>	uy_i = idat.eFrame1->getColumn(1);
509	>	uz_i = idat.eFrame1->getColumn(2);
510
511		cx_i = dot(ux_i, rhat);
512		cy_i = dot(uy_i, rhat);
#	Line 522 \| Line 522 \| namespace OpenMD {
522
523		if (j_is_Dipole) {
524		mu_j = data2.dipole_moment;
525	<	uz_j = idat.eFrame2.getColumn(2);
525	>	uz_j = idat.eFrame2->getColumn(2);
526
527		ct_j = dot(uz_j, rhat);
528
#	Line 538 \| Line 538 \| namespace OpenMD {
538		qyy_j = Q_j.y();
539		qzz_j = Q_j.z();
540
541	<	ux_j = idat.eFrame2.getColumn(0);
542	<	uy_j = idat.eFrame2.getColumn(1);
543	<	uz_j = idat.eFrame2.getColumn(2);
541	>	ux_j = idat.eFrame2->getColumn(0);
542	>	uy_j = idat.eFrame2->getColumn(1);
543	>	uz_j = idat.eFrame2->getColumn(2);
544
545		cx_j = dot(ux_j, rhat);
546		cy_j = dot(uy_j, rhat);
#	Line 559 \| Line 559 \| namespace OpenMD {
559		if (j_is_Charge) {
560		if (screeningMethod_ == DAMPED) {
561		// assemble the damping variables
562	<	res = erfcSpline_->getValueAndDerivativeAt(idat.rij);
562	>	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
563		erfcVal = res.first;
564		derfcVal = res.second;
565		c1 = erfcVal * riji;
#	Line 569 \| Line 569 \| namespace OpenMD {
569		c2 = c1 * riji;
570		}
571
572	<	preVal = idat.electroMult * pre11_ * q_i * q_j;
572	>	preVal = (idat.electroMult) pre11_ * q_i * q_j;
573
574		if (summationMethod_ == esm_SHIFTED_POTENTIAL) {
575		vterm = preVal * (c1 - c1c_);
576	<	dudr = -idat.sw * preVal * c2;
576	>	dudr = - (idat.sw) preVal * c2;
577
578		} else if (summationMethod_ == esm_SHIFTED_FORCE) {
579	<	vterm = preVal * ( c1 - c1c_ + c2c_*(idat.rij - cutoffRadius_) );
580	<	dudr = idat.sw * preVal * (c2c_ - c2);
579	>	vterm = preVal * ( c1 - c1c_ + c2c_( (idat.rij) - cutoffRadius_) );
580	>	dudr = (idat.sw) preVal * (c2c_ - c2);
581
582		} else if (summationMethod_ == esm_REACTION_FIELD) {
583	<	rfVal = idat.electroMult * preRF_ * idat.rij * idat.rij;
583	>	rfVal = (idat.electroMult) preRF_ * (idat.rij) *(idat.rij) ;
584		vterm = preVal * ( riji + rfVal );
585	<	dudr = idat.sw * preVal * ( 2.0 * rfVal - riji ) * riji;
585	>	dudr = (idat.sw) preVal * ( 2.0 * rfVal - riji ) * riji;
586
587		} else {
588		vterm = preVal * riji * erfcVal;
589
590	<	dudr = - idat.sw * preVal * c2;
590	>	dudr = - (idat.sw) preVal * c2;
591
592		}
593
594	<	idat.vpair += vterm;
595	<	epot += idat.sw * vterm;
594	>	*(idat.vpair) += vterm;
595	>	epot += (idat.sw) vterm;
596
597		dVdr += dudr * rhat;
598		}
599
600		if (j_is_Dipole) {
601		// pref is used by all the possible methods
602	<	pref = idat.electroMult * pre12_ * q_i * mu_j;
603	<	preSw = idat.sw * pref;
602	>	pref = (idat.electroMult) pre12_ * q_i * mu_j;
603	>	preSw = (idat.sw) pref;
604
605		if (summationMethod_ == esm_REACTION_FIELD) {
606		ri2 = riji * riji;
607		ri3 = ri2 * riji;
608
609	<	vterm = - pref * ct_j * ( ri2 - preRF2_ * idat.rij );
610	<	idat.vpair += vterm;
611	<	epot += idat.sw * vterm;
609	>	vterm = - pref * ct_j * ( ri2 - preRF2_ * *(idat.rij) );
610	>	*(idat.vpair) += vterm;
611	>	epot += (idat.sw) vterm;
612
613		dVdr += -preSw * (ri3 * (uz_j - 3.0 * ct_j * rhat) - preRF2_*uz_j);
614	<	duduz_j += -preSw * rhat * (ri2 - preRF2_ * idat.rij);
614	>	duduz_j += -preSw * rhat * (ri2 - preRF2_ * *(idat.rij) );
615
616		} else {
617		// determine the inverse r used if we have split dipoles
618		if (j_is_SplitDipole) {
619	<	BigR = sqrt(idat.r2 + 0.25 * d_j * d_j);
619	>	BigR = sqrt( (idat.r2) + 0.25 d_j * d_j);
620		ri = 1.0 / BigR;
621	<	scale = idat.rij * ri;
621	>	scale = (idat.rij) ri;
622		} else {
623		ri = riji;
624		scale = 1.0;
#	Line 628 \| Line 628 \| namespace OpenMD {
628
629		if (screeningMethod_ == DAMPED) {
630		// assemble the damping variables
631	<	res = erfcSpline_->getValueAndDerivativeAt(idat.rij);
631	>	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
632		erfcVal = res.first;
633		derfcVal = res.second;
634		c1 = erfcVal * ri;
#	Line 645 \| Line 645 \| namespace OpenMD {
645		// calculate the potential
646		pot_term = scale * c2;
647		vterm = -pref * ct_j * pot_term;
648	<	idat.vpair += vterm;
649	<	epot += idat.sw * vterm;
648	>	*(idat.vpair) += vterm;
649	>	epot += (idat.sw) vterm;
650
651		// calculate derivatives for forces and torques
652
#	Line 661 \| Line 661 \| namespace OpenMD {
661		cx2 = cx_j * cx_j;
662		cy2 = cy_j * cy_j;
663		cz2 = cz_j * cz_j;
664	<	pref = idat.electroMult * pre14_ * q_i * one_third_;
664	>	pref = (idat.electroMult) pre14_ * q_i * one_third_;
665
666		if (screeningMethod_ == DAMPED) {
667		// assemble the damping variables
668	<	res = erfcSpline_->getValueAndDerivativeAt(idat.rij);
668	>	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
669		erfcVal = res.first;
670		derfcVal = res.second;
671		c1 = erfcVal * riji;
#	Line 680 \| Line 680 \| namespace OpenMD {
680		}
681
682		// precompute variables for convenience
683	<	preSw = idat.sw * pref;
683	>	preSw = (idat.sw) pref;
684		c2ri = c2 * riji;
685		c3ri = c3 * riji;
686	<	c4rij = c4 * idat.rij;
686	>	c4rij = c4 * *(idat.rij) ;
687		rhatdot2 = 2.0 * rhat * c3;
688		rhatc4 = rhat * c4rij;
689
#	Line 692 \| Line 692 \| namespace OpenMD {
692		qyy_j * (cy2*c3 - c2ri) +
693		qzz_j * (cz2*c3 - c2ri) );
694		vterm = pref * pot_term;
695	<	idat.vpair += vterm;
696	<	epot += idat.sw * vterm;
695	>	*(idat.vpair) += vterm;
696	>	epot += (idat.sw) vterm;
697
698		// calculate derivatives for the forces and torques
699
#	Line 711 \| Line 711 \| namespace OpenMD {
711
712		if (j_is_Charge) {
713		// variables used by all the methods
714	<	pref = idat.electroMult * pre12_ * q_j * mu_i;
715	<	preSw = idat.sw * pref;
714	>	pref = (idat.electroMult) pre12_ * q_j * mu_i;
715	>	preSw = (idat.sw) pref;
716
717		if (summationMethod_ == esm_REACTION_FIELD) {
718
719		ri2 = riji * riji;
720		ri3 = ri2 * riji;
721
722	<	vterm = pref * ct_i * ( ri2 - preRF2_ * idat.rij );
723	<	idat.vpair += vterm;
724	<	epot += idat.sw * vterm;
722	>	vterm = pref * ct_i * ( ri2 - preRF2_ * *(idat.rij) );
723	>	*(idat.vpair) += vterm;
724	>	epot += (idat.sw) vterm;
725
726		dVdr += preSw * (ri3 * (uz_i - 3.0 * ct_i * rhat) - preRF2_ * uz_i);
727
728	<	duduz_i += preSw * rhat * (ri2 - preRF2_ * idat.rij);
728	>	duduz_i += preSw * rhat * (ri2 - preRF2_ * *(idat.rij) );
729
730		} else {
731
732		// determine inverse r if we are using split dipoles
733		if (i_is_SplitDipole) {
734	<	BigR = sqrt(idat.r2 + 0.25 * d_i * d_i);
734	>	BigR = sqrt( (idat.r2) + 0.25 d_i * d_i);
735		ri = 1.0 / BigR;
736	<	scale = idat.rij * ri;
736	>	scale = (idat.rij) ri;
737		} else {
738		ri = riji;
739		scale = 1.0;
#	Line 743 \| Line 743 \| namespace OpenMD {
743
744		if (screeningMethod_ == DAMPED) {
745		// assemble the damping variables
746	<	res = erfcSpline_->getValueAndDerivativeAt(idat.rij);
746	>	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
747		erfcVal = res.first;
748		derfcVal = res.second;
749		c1 = erfcVal * ri;
#	Line 760 \| Line 760 \| namespace OpenMD {
760		// calculate the potential
761		pot_term = c2 * scale;
762		vterm = pref * ct_i * pot_term;
763	<	idat.vpair += vterm;
764	<	epot += idat.sw * vterm;
763	>	*(idat.vpair) += vterm;
764	>	epot += (idat.sw) vterm;
765
766		// calculate derivatives for the forces and torques
767		dVdr += preSw * (uz_i * c2ri - ct_i * rhat * sc2 * c3);
#	Line 773 \| Line 773 \| namespace OpenMD {
773		// variables used by all methods
774		ct_ij = dot(uz_i, uz_j);
775
776	<	pref = idat.electroMult * pre22_ * mu_i * mu_j;
777	<	preSw = idat.sw * pref;
776	>	pref = (idat.electroMult) pre22_ * mu_i * mu_j;
777	>	preSw = (idat.sw) pref;
778
779		if (summationMethod_ == esm_REACTION_FIELD) {
780		ri2 = riji * riji;
#	Line 783 \| Line 783 \| namespace OpenMD {
783
784		vterm = pref * ( ri3 * (ct_ij - 3.0 * ct_i * ct_j) -
785		preRF2_ * ct_ij );
786	<	idat.vpair += vterm;
787	<	epot += idat.sw * vterm;
786	>	*(idat.vpair) += vterm;
787	>	epot += (idat.sw) vterm;
788
789		a1 = 5.0 * ct_i * ct_j - ct_ij;
790
#	Line 797 \| Line 797 \| namespace OpenMD {
797
798		if (i_is_SplitDipole) {
799		if (j_is_SplitDipole) {
800	<	BigR = sqrt(idat.r2 + 0.25 * d_i * d_i + 0.25 * d_j * d_j);
800	>	BigR = sqrt( (idat.r2) + 0.25 d_i * d_i + 0.25 * d_j * d_j);
801		} else {
802	<	BigR = sqrt(idat.r2 + 0.25 * d_i * d_i);
802	>	BigR = sqrt( (idat.r2) + 0.25 d_i * d_i);
803		}
804		ri = 1.0 / BigR;
805	<	scale = idat.rij * ri;
805	>	scale = (idat.rij) ri;
806		} else {
807		if (j_is_SplitDipole) {
808	<	BigR = sqrt(idat.r2 + 0.25 * d_j * d_j);
808	>	BigR = sqrt( (idat.r2) + 0.25 d_j * d_j);
809		ri = 1.0 / BigR;
810	<	scale = idat.rij * ri;
810	>	scale = (idat.rij) ri;
811		} else {
812		ri = riji;
813		scale = 1.0;
#	Line 815 \| Line 815 \| namespace OpenMD {
815		}
816		if (screeningMethod_ == DAMPED) {
817		// assemble damping variables
818	<	res = erfcSpline_->getValueAndDerivativeAt(idat.rij);
818	>	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
819		erfcVal = res.first;
820		derfcVal = res.second;
821		c1 = erfcVal * ri;
#	Line 837 \| Line 837 \| namespace OpenMD {
837		preSwSc = preSw * scale;
838		c2ri = c2 * ri;
839		c3ri = c3 * ri;
840	<	c4rij = c4 * idat.rij;
840	>	c4rij = c4 * *(idat.rij) ;
841
842		// calculate the potential
843		pot_term = (ct_ij * c2ri - ctidotj * c3);
844		vterm = pref * pot_term;
845	<	idat.vpair += vterm;
846	<	epot += idat.sw * vterm;
845	>	*(idat.vpair) += vterm;
846	>	epot += (idat.sw) vterm;
847
848		// calculate derivatives for the forces and torques
849		dVdr += preSwSc * ( ctidotj * rhat * c4rij -
#	Line 862 \| Line 862 \| namespace OpenMD {
862		cy2 = cy_i * cy_i;
863		cz2 = cz_i * cz_i;
864
865	<	pref = idat.electroMult * pre14_ * q_j * one_third_;
865	>	pref = (idat.electroMult) pre14_ * q_j * one_third_;
866
867		if (screeningMethod_ == DAMPED) {
868		// assemble the damping variables
869	<	res = erfcSpline_->getValueAndDerivativeAt(idat.rij);
869	>	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
870		erfcVal = res.first;
871		derfcVal = res.second;
872		c1 = erfcVal * riji;
#	Line 881 \| Line 881 \| namespace OpenMD {
881		}
882
883		// precompute some variables for convenience
884	<	preSw = idat.sw * pref;
884	>	preSw = (idat.sw) pref;
885		c2ri = c2 * riji;
886		c3ri = c3 * riji;
887	<	c4rij = c4 * idat.rij;
887	>	c4rij = c4 * *(idat.rij) ;
888		rhatdot2 = 2.0 * rhat * c3;
889		rhatc4 = rhat * c4rij;
890
#	Line 894 \| Line 894 \| namespace OpenMD {
894		qzz_i * (cz2 * c3 - c2ri) );
895
896		vterm = pref * pot_term;
897	<	idat.vpair += vterm;
898	<	epot += idat.sw * vterm;
897	>	*(idat.vpair) += vterm;
898	>	epot += (idat.sw) vterm;
899
900		// calculate the derivatives for the forces and torques
901
#	Line 909 \| Line 909 \| namespace OpenMD {
909		}
910		}
911
912	<	idat.pot += epot;
913	<	idat.f1 += dVdr;
912	>	idat.pot[ELECTROSTATIC_FAMILY] += epot;
913	>	*(idat.f1) += dVdr;
914
915		if (i_is_Dipole \|\| i_is_Quadrupole)
916	<	idat.t1 -= cross(uz_i, duduz_i);
916	>	*(idat.t1) -= cross(uz_i, duduz_i);
917		if (i_is_Quadrupole) {
918	<	idat.t1 -= cross(ux_i, dudux_i);
919	<	idat.t1 -= cross(uy_i, duduy_i);
918	>	*(idat.t1) -= cross(ux_i, dudux_i);
919	>	*(idat.t1) -= cross(uy_i, duduy_i);
920		}
921	<
921	>
922		if (j_is_Dipole \|\| j_is_Quadrupole)
923	<	idat.t2 -= cross(uz_j, duduz_j);
923	>	*(idat.t2) -= cross(uz_j, duduz_j);
924		if (j_is_Quadrupole) {
925	<	idat.t2 -= cross(uz_j, dudux_j);
926	<	idat.t2 -= cross(uz_j, duduy_j);
925	>	*(idat.t2) -= cross(uz_j, dudux_j);
926	>	*(idat.t2) -= cross(uz_j, duduy_j);
927		}
928
929		return;
930		}
931
932	<	void Electrostatic::calcSkipCorrection(SkipCorrectionData skdat) {
932	>	void Electrostatic::calcSkipCorrection(InteractionData &idat) {
933
934		if (!initialized_) initialize();
935
936	<	ElectrostaticAtomData data1 = ElectrostaticMap[skdat.atype1];
937	<	ElectrostaticAtomData data2 = ElectrostaticMap[skdat.atype2];
936	>	ElectrostaticAtomData data1 = ElectrostaticMap[idat.atypes.first];
937	>	ElectrostaticAtomData data2 = ElectrostaticMap[idat.atypes.second];
938
939		// logicals
940
#	Line 951 \| Line 951 \| namespace OpenMD {
951
952		if (i_is_Charge) {
953		q_i = data1.charge;
954	<	skdat.skippedCharge2 += q_i;
954	>	*(idat.skippedCharge2) += q_i;
955		}
956
957		if (j_is_Charge) {
958		q_j = data2.charge;
959	<	skdat.skippedCharge1 += q_j;
959	>	*(idat.skippedCharge1) += q_j;
960		}
961
962		// the rest of this function should only be necessary for reaction field.
963
964		if (summationMethod_ == esm_REACTION_FIELD) {
965		RealType riji, ri2, ri3;
966	<	RealType q_i, mu_i, ct_i;
967	<	RealType q_j, mu_j, ct_j;
968	<	RealType preVal, rfVal, vterm, dudr, pref, myPot;
966	>	RealType mu_i, ct_i;
967	>	RealType mu_j, ct_j;
968	>	RealType preVal, rfVal, vterm, dudr, pref, myPot(0.0);
969		Vector3d dVdr, uz_i, uz_j, duduz_i, duduz_j, rhat;
970
971		// some variables we'll need independent of electrostatic type:
972
973	<	riji = 1.0 / skdat.rij;
974	<	rhat = skdat.d * riji;
973	>	riji = 1.0 / *(idat.rij) ;
974	>	rhat = (idat.d) riji;
975
976		if (i_is_Dipole) {
977		mu_i = data1.dipole_moment;
978	<	uz_i = skdat.eFrame1.getColumn(2);
978	>	uz_i = idat.eFrame1->getColumn(2);
979		ct_i = dot(uz_i, rhat);
980		duduz_i = V3Zero;
981		}
982
983		if (j_is_Dipole) {
984		mu_j = data2.dipole_moment;
985	<	uz_j = skdat.eFrame2.getColumn(2);
985	>	uz_j = idat.eFrame2->getColumn(2);
986		ct_j = dot(uz_j, rhat);
987		duduz_j = V3Zero;
988		}
989
990		if (i_is_Charge) {
991		if (j_is_Charge) {
992	<	preVal = skdat.electroMult * pre11_ * q_i * q_j;
993	<	rfVal = preRF_ * skdat.rij * skdat.rij;
992	>	preVal = (idat.electroMult) pre11_ * q_i * q_j;
993	>	rfVal = preRF_ * (idat.rij) *(idat.rij) ;
994		vterm = preVal * rfVal;
995	<	myPot += skdat.sw * vterm;
996	<	dudr = skdat.sw * preVal * 2.0 * rfVal * riji;
995	>	myPot += (idat.sw) vterm;
996	>	dudr = (idat.sw) preVal * 2.0 * rfVal * riji;
997		dVdr += dudr * rhat;
998		}
999
1000		if (j_is_Dipole) {
1001		ri2 = riji * riji;
1002		ri3 = ri2 * riji;
1003	<	pref = skdat.electroMult * pre12_ * q_i * mu_j;
1004	<	vterm = - pref * ct_j * ( ri2 - preRF2_ * skdat.rij );
1005	<	myPot += skdat.sw * vterm;
1006	<	dVdr += -skdat.sw * pref * ( ri3 * ( uz_j - 3.0 * ct_j * rhat) - preRF2_ * uz_j);
1007	<	duduz_j += -skdat.sw * pref * rhat * (ri2 - preRF2_ * skdat.rij);
1003	>	pref = (idat.electroMult) pre12_ * q_i * mu_j;
1004	>	vterm = - pref * ct_j * ( ri2 - preRF2_ * *(idat.rij) );
1005	>	myPot += (idat.sw) vterm;
1006	>	dVdr += - (idat.sw) pref * ( ri3 * ( uz_j - 3.0 * ct_j * rhat) - preRF2_ * uz_j);
1007	>	duduz_j += - (idat.sw) pref * rhat * (ri2 - preRF2_ * *(idat.rij) );
1008		}
1009		}
1010		if (i_is_Dipole) {
1011		if (j_is_Charge) {
1012		ri2 = riji * riji;
1013		ri3 = ri2 * riji;
1014	<	pref = skdat.electroMult * pre12_ * q_j * mu_i;
1015	<	vterm = - pref * ct_i * ( ri2 - preRF2_ * skdat.rij );
1016	<	myPot += skdat.sw * vterm;
1017	<	dVdr += skdat.sw * pref * ( ri3 * ( uz_i - 3.0 * ct_i * rhat) - preRF2_ * uz_i);
1018	<	duduz_i += skdat.sw * pref * rhat * (ri2 - preRF2_ * skdat.rij);
1014	>	pref = (idat.electroMult) pre12_ * q_j * mu_i;
1015	>	vterm = - pref * ct_i * ( ri2 - preRF2_ * *(idat.rij) );
1016	>	myPot += (idat.sw) vterm;
1017	>	dVdr += (idat.sw) pref * ( ri3 * ( uz_i - 3.0 * ct_i * rhat) - preRF2_ * uz_i);
1018	>	duduz_i += (idat.sw) pref * rhat * (ri2 - preRF2_ * *(idat.rij));
1019		}
1020		}
1021
1022		// accumulate the forces and torques resulting from the self term
1023	<	skdat.pot += myPot;
1024	<	skdat.f1 += dVdr;
1023	>	idat.pot[ELECTROSTATIC_FAMILY] += myPot;
1024	>	*(idat.f1) += dVdr;
1025
1026		if (i_is_Dipole)
1027	<	skdat.t1 -= cross(uz_i, duduz_i);
1027	>	*(idat.t1) -= cross(uz_i, duduz_i);
1028		if (j_is_Dipole)
1029	<	skdat.t2 -= cross(uz_j, duduz_j);
1029	>	*(idat.t2) -= cross(uz_j, duduz_j);
1030		}
1031		}
1032
1033	<	void Electrostatic::calcSelfCorrection(SelfCorrectionData scdat) {
1033	>	void Electrostatic::calcSelfCorrection(SelfData &sdat) {
1034		RealType mu1, preVal, chg1, self;
1035
1036		if (!initialized_) initialize();
1037
1038	<	ElectrostaticAtomData data = ElectrostaticMap[scdat.atype];
1038	>	ElectrostaticAtomData data = ElectrostaticMap[sdat.atype];
1039
1040		// logicals
1041
#	Line 1046 \| Line 1046 \| namespace OpenMD {
1046		if (i_is_Dipole) {
1047		mu1 = data.dipole_moment;
1048		preVal = pre22_ * preRF2_ * mu1 * mu1;
1049	<	scdat.pot -= 0.5 * preVal;
1049	>	sdat.pot[2] -= 0.5 * preVal;
1050
1051		// The self-correction term adds into the reaction field vector
1052	<	Vector3d uz_i = scdat.eFrame.getColumn(2);
1052	>	Vector3d uz_i = sdat.eFrame->getColumn(2);
1053		Vector3d ei = preVal * uz_i;
1054
1055		// This looks very wrong. A vector crossed with itself is zero.
1056	<	scdat.t -= cross(uz_i, ei);
1056	>	*(sdat.t) -= cross(uz_i, ei);
1057		}
1058		} else if (summationMethod_ == esm_SHIFTED_FORCE \|\| summationMethod_ == esm_SHIFTED_POTENTIAL) {
1059		if (i_is_Charge) {
1060		chg1 = data.charge;
1061		if (screeningMethod_ == DAMPED) {
1062	<	self = - 0.5 * (c1c_ + alphaPi_) * chg1 * (chg1 + scdat.skippedCharge) * pre11_;
1062	>	self = - 0.5 * (c1c_ + alphaPi_) * chg1 * (chg1 + (sdat.skippedCharge)) pre11_;
1063		} else {
1064	<	self = - 0.5 * rcuti_ * chg1 * (chg1 + scdat.skippedCharge) * pre11_;
1064	>	self = - 0.5 * rcuti_ * chg1 * (chg1 + (sdat.skippedCharge)) pre11_;
1065		}
1066	<	scdat.pot += self;
1066	>	sdat.pot[ELECTROSTATIC_FAMILY] += self;
1067		}
1068		}
1069		}
1070
1071	<	RealType Electrostatic::getSuggestedCutoffRadius(AtomType* at1, AtomType* at2) {
1071	>	RealType Electrostatic::getSuggestedCutoffRadius(pair<AtomType, AtomType> atypes) {
1072		// This seems to work moderately well as a default. There's no
1073		// inherent scale for 1/r interactions that we can standardize.
1074		// 12 angstroms seems to be a reasonably good guess for most

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Comparing branches/development/src/nonbonded/Electrostatic.cpp (file contents): Revision 1535 by gezelter, Fri Dec 31 18:31:56 2010 UTC vs. Revision 1571 by gezelter, Fri May 27 16:45:44 2011 UTC

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Comparing branches/development/src/nonbonded/Electrostatic.cpp (file contents):
Revision 1535 by gezelter, Fri Dec 31 18:31:56 2010 UTC vs.
Revision 1571 by gezelter, Fri May 27 16:45:44 2011 UTC