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

Comparing branches/development/src/nonbonded/Electrostatic.cpp (file contents):
Revision 1586 by gezelter, Tue Jun 21 06:34:35 2011 UTC vs.
Revision 1723 by gezelter, Thu May 24 20:59:54 2012 UTC

#	Line 34 \| Line 34
34		* work. Good starting points are:
35		*
36		* [1] Meineke, et al., J. Comp. Chem. 26, 252-271 (2005).
37	<	* [2] Fennell & Gezelter, J. Chem. Phys. 124, 234104 (2006).
37	>	* [2] Fennell & Gezelter, J. Chem. Phys. 124 234104 (2006).
38		* [3] Sun, Lin & Gezelter, J. Chem. Phys. 128, 24107 (2008).
39	<	* [4] Vardeman & Gezelter, in progress (2009).
39	>	* [4] Kuang & Gezelter, J. Chem. Phys. 133, 164101 (2010).
40	>	* [5] Vardeman, Stocker & Gezelter, J. Chem. Theory Comput. 7, 834 (2011).
41		*/
42
43		#include <stdio.h>
#	Line 46 \| Line 47
47		#include "nonbonded/Electrostatic.hpp"
48		#include "utils/simError.h"
49		#include "types/NonBondedInteractionType.hpp"
50	<	#include "types/DirectionalAtomType.hpp"
50	>	#include "types/FixedChargeAdapter.hpp"
51	>	#include "types/FluctuatingChargeAdapter.hpp"
52	>	#include "types/MultipoleAdapter.hpp"
53		#include "io/Globals.hpp"
54	+	#include "nonbonded/SlaterIntegrals.hpp"
55	+	#include "utils/PhysicalConstants.hpp"
56
57	+
58		namespace OpenMD {
59
60		Electrostatic::Electrostatic(): name_("Electrostatic"), initialized_(false),
61	<	forceField_(NULL), info_(NULL), haveCutoffRadius_(false),
62	<	haveDampingAlpha_(false), haveDielectric_(false),
61	>	forceField_(NULL), info_(NULL),
62	>	haveCutoffRadius_(false),
63	>	haveDampingAlpha_(false),
64	>	haveDielectric_(false),
65		haveElectroSpline_(false)
66	<	{}
66	>	{}
67
68		void Electrostatic::initialize() {
69	<
69	>
70		Globals* simParams_ = info_->getSimParams();
71
72		summationMap_["HARD"] = esm_HARD;
73	+	summationMap_["NONE"] = esm_HARD;
74		summationMap_["SWITCHING_FUNCTION"] = esm_SWITCHING_FUNCTION;
75		summationMap_["SHIFTED_POTENTIAL"] = esm_SHIFTED_POTENTIAL;
76		summationMap_["SHIFTED_FORCE"] = esm_SHIFTED_FORCE;
#	Line 114 \| Line 123 \| namespace OpenMD {
123		sprintf( painCave.errMsg,
124		"Electrostatic::initialize: Unknown electrostaticSummationMethod.\n"
125		"\t(Input file specified %s .)\n"
126	<	"\telectrostaticSummationMethod must be one of: \"none\",\n"
126	>	"\telectrostaticSummationMethod must be one of: \"hard\",\n"
127		"\t\"shifted_potential\", \"shifted_force\", or \n"
128		"\t\"reaction_field\".\n", myMethod.c_str() );
129		painCave.isFatal = 1;
#	Line 208 \| Line 217 \| namespace OpenMD {
217		addType(at);
218		}
219
211	–
220		cutoffRadius2_ = cutoffRadius_ * cutoffRadius_;
221		rcuti_ = 1.0 / cutoffRadius_;
222		rcuti2_ = rcuti_ * rcuti_;
#	Line 247 \| Line 255 \| namespace OpenMD {
255		preRF2_ = 2.0 * preRF_;
256		}
257
258	<	RealType dx = cutoffRadius_ / RealType(np_ - 1);
258	>	// Add a 2 angstrom safety window to deal with cutoffGroups that
259	>	// have charged atoms longer than the cutoffRadius away from each
260	>	// other. Splining may not be the best choice here. Direct calls
261	>	// to erfc might be preferrable.
262	>
263	>	RealType dx = (cutoffRadius_ + 2.0) / RealType(np_ - 1);
264		RealType rval;
265		vector<RealType> rvals;
266		vector<RealType> yvals;
#	Line 270 \| Line 283 \| namespace OpenMD {
283		electrostaticAtomData.is_Dipole = false;
284		electrostaticAtomData.is_SplitDipole = false;
285		electrostaticAtomData.is_Quadrupole = false;
286	+	electrostaticAtomData.is_Fluctuating = false;
287
288	<	if (atomType->isCharge()) {
275	<	GenericData* data = atomType->getPropertyByName("Charge");
288	>	FixedChargeAdapter fca = FixedChargeAdapter(atomType);
289
290	<	if (data == NULL) {
278	<	sprintf( painCave.errMsg, "Electrostatic::addType could not find "
279	<	"Charge\n"
280	<	"\tparameters for atomType %s.\n",
281	<	atomType->getName().c_str());
282	<	painCave.severity = OPENMD_ERROR;
283	<	painCave.isFatal = 1;
284	<	simError();
285	<	}
286	<
287	<	DoubleGenericData* doubleData = dynamic_cast<DoubleGenericData*>(data);
288	<	if (doubleData == NULL) {
289	<	sprintf( painCave.errMsg,
290	<	"Electrostatic::addType could not convert GenericData to "
291	<	"Charge for\n"
292	<	"\tatom type %s\n", atomType->getName().c_str());
293	<	painCave.severity = OPENMD_ERROR;
294	<	painCave.isFatal = 1;
295	<	simError();
296	<	}
290	>	if (fca.isFixedCharge()) {
291		electrostaticAtomData.is_Charge = true;
292	<	electrostaticAtomData.charge = doubleData->getData();
292	>	electrostaticAtomData.fixedCharge = fca.getCharge();
293		}
294
295	<	if (atomType->isDirectional()) {
296	<	DirectionalAtomType* daType = dynamic_cast<DirectionalAtomType*>(atomType);
297	<
304	<	if (daType->isDipole()) {
305	<	GenericData* data = daType->getPropertyByName("Dipole");
306	<
307	<	if (data == NULL) {
308	<	sprintf( painCave.errMsg,
309	<	"Electrostatic::addType could not find Dipole\n"
310	<	"\tparameters for atomType %s.\n",
311	<	daType->getName().c_str());
312	<	painCave.severity = OPENMD_ERROR;
313	<	painCave.isFatal = 1;
314	<	simError();
315	<	}
316	<
317	<	DoubleGenericData* doubleData = dynamic_cast<DoubleGenericData*>(data);
318	<	if (doubleData == NULL) {
319	<	sprintf( painCave.errMsg,
320	<	"Electrostatic::addType could not convert GenericData to "
321	<	"Dipole Moment\n"
322	<	"\tfor atom type %s\n", daType->getName().c_str());
323	<	painCave.severity = OPENMD_ERROR;
324	<	painCave.isFatal = 1;
325	<	simError();
326	<	}
295	>	MultipoleAdapter ma = MultipoleAdapter(atomType);
296	>	if (ma.isMultipole()) {
297	>	if (ma.isDipole()) {
298		electrostaticAtomData.is_Dipole = true;
299	<	electrostaticAtomData.dipole_moment = doubleData->getData();
299	>	electrostaticAtomData.dipole_moment = ma.getDipoleMoment();
300		}
301	<
331	<	if (daType->isSplitDipole()) {
332	<	GenericData* data = daType->getPropertyByName("SplitDipoleDistance");
333	<
334	<	if (data == NULL) {
335	<	sprintf(painCave.errMsg,
336	<	"Electrostatic::addType could not find SplitDipoleDistance\n"
337	<	"\tparameter for atomType %s.\n",
338	<	daType->getName().c_str());
339	<	painCave.severity = OPENMD_ERROR;
340	<	painCave.isFatal = 1;
341	<	simError();
342	<	}
343	<
344	<	DoubleGenericData* doubleData = dynamic_cast<DoubleGenericData*>(data);
345	<	if (doubleData == NULL) {
346	<	sprintf( painCave.errMsg,
347	<	"Electrostatic::addType could not convert GenericData to "
348	<	"SplitDipoleDistance for\n"
349	<	"\tatom type %s\n", daType->getName().c_str());
350	<	painCave.severity = OPENMD_ERROR;
351	<	painCave.isFatal = 1;
352	<	simError();
353	<	}
301	>	if (ma.isSplitDipole()) {
302		electrostaticAtomData.is_SplitDipole = true;
303	<	electrostaticAtomData.split_dipole_distance = doubleData->getData();
303	>	electrostaticAtomData.split_dipole_distance = ma.getSplitDipoleDistance();
304		}
305	<
358	<	if (daType->isQuadrupole()) {
359	<	GenericData* data = daType->getPropertyByName("QuadrupoleMoments");
360	<
361	<	if (data == NULL) {
362	<	sprintf( painCave.errMsg,
363	<	"Electrostatic::addType could not find QuadrupoleMoments\n"
364	<	"\tparameter for atomType %s.\n",
365	<	daType->getName().c_str());
366	<	painCave.severity = OPENMD_ERROR;
367	<	painCave.isFatal = 1;
368	<	simError();
369	<	}
370	<
305	>	if (ma.isQuadrupole()) {
306		// Quadrupoles in OpenMD are set as the diagonal elements
307		// of the diagonalized traceless quadrupole moment tensor.
308		// The column vectors of the unitary matrix that diagonalizes
309		// the quadrupole moment tensor become the eFrame (or the
310		// electrostatic version of the body-fixed frame.
376	–
377	–	Vector3dGenericData* v3dData = dynamic_cast<Vector3dGenericData*>(data);
378	–	if (v3dData == NULL) {
379	–	sprintf( painCave.errMsg,
380	–	"Electrostatic::addType could not convert GenericData to "
381	–	"Quadrupole Moments for\n"
382	–	"\tatom type %s\n", daType->getName().c_str());
383	–	painCave.severity = OPENMD_ERROR;
384	–	painCave.isFatal = 1;
385	–	simError();
386	–	}
311		electrostaticAtomData.is_Quadrupole = true;
312	<	electrostaticAtomData.quadrupole_moments = v3dData->getData();
312	>	electrostaticAtomData.quadrupole_moments = ma.getQuadrupoleMoments();
313		}
314		}
315
316	<	AtomTypeProperties atp = atomType->getATP();
316	>	FluctuatingChargeAdapter fqa = FluctuatingChargeAdapter(atomType);
317
318	+	if (fqa.isFluctuatingCharge()) {
319	+	electrostaticAtomData.is_Fluctuating = true;
320	+	electrostaticAtomData.electronegativity = fqa.getElectronegativity();
321	+	electrostaticAtomData.hardness = fqa.getHardness();
322	+	electrostaticAtomData.slaterN = fqa.getSlaterN();
323	+	electrostaticAtomData.slaterZeta = fqa.getSlaterZeta();
324	+	}
325	+
326		pair<map<int,AtomType*>::iterator,bool> ret;
327	<	ret = ElectrostaticList.insert( pair<int,AtomType*>(atp.ident, atomType) );
327	>	ret = ElectrostaticList.insert( pair<int,AtomType*>(atomType->getIdent(),
328	>	atomType) );
329		if (ret.second == false) {
330		sprintf( painCave.errMsg,
331		"Electrostatic already had a previous entry with ident %d\n",
332	<	atp.ident);
332	>	atomType->getIdent() );
333		painCave.severity = OPENMD_INFO;
334		painCave.isFatal = 0;
335		simError();
336		}
337
338	<	ElectrostaticMap[atomType] = electrostaticAtomData;
338	>	ElectrostaticMap[atomType] = electrostaticAtomData;
339	>
340	>	// Now, iterate over all known types and add to the mixing map:
341	>
342	>	map<AtomType*, ElectrostaticAtomData>::iterator it;
343	>	for( it = ElectrostaticMap.begin(); it != ElectrostaticMap.end(); ++it) {
344	>	AtomType* atype2 = (*it).first;
345	>	ElectrostaticAtomData eaData2 = (*it).second;
346	>	if (eaData2.is_Fluctuating && electrostaticAtomData.is_Fluctuating) {
347	>
348	>	RealType a = electrostaticAtomData.slaterZeta;
349	>	RealType b = eaData2.slaterZeta;
350	>	int m = electrostaticAtomData.slaterN;
351	>	int n = eaData2.slaterN;
352	>
353	>	// Create the spline of the coulombic integral for s-type
354	>	// Slater orbitals. Add a 2 angstrom safety window to deal
355	>	// with cutoffGroups that have charged atoms longer than the
356	>	// cutoffRadius away from each other.
357	>
358	>	RealType rval;
359	>	RealType dr = (cutoffRadius_ + 2.0) / RealType(np_ - 1);
360	>	vector<RealType> rvals;
361	>	vector<RealType> J1vals;
362	>	vector<RealType> J2vals;
363	>	for (int i = 0; i < np_; i++) {
364	>	rval = RealType(i) * dr;
365	>	rvals.push_back(rval);
366	>	J1vals.push_back( sSTOCoulInt( a, b, m, n, rval * PhysicalConstants::angstromsToBohr ) );
367	>	// may not be necessary if Slater coulomb integral is symmetric
368	>	J2vals.push_back( sSTOCoulInt( b, a, n, m, rval * PhysicalConstants::angstromsToBohr ) );
369	>	}
370	>
371	>	CubicSpline* J1 = new CubicSpline();
372	>	J1->addPoints(rvals, J1vals);
373	>	CubicSpline* J2 = new CubicSpline();
374	>	J2->addPoints(rvals, J2vals);
375	>
376	>	pair<AtomType, AtomType> key1, key2;
377	>	key1 = make_pair(atomType, atype2);
378	>	key2 = make_pair(atype2, atomType);
379	>
380	>	Jij[key1] = J1;
381	>	Jij[key2] = J2;
382	>	}
383	>	}
384	>
385		return;
386		}
387
#	Line 444 \| Line 423 \| namespace OpenMD {
423		RealType ct_i, ct_j, ct_ij, a1;
424		RealType riji, ri, ri2, ri3, ri4;
425		RealType pref, vterm, epot, dudr;
426	+	RealType vpair(0.0);
427		RealType scale, sc2;
428		RealType pot_term, preVal, rfVal;
429		RealType c2ri, c3ri, c4rij, cti3, ctj3, ctidotj;
430		RealType preSw, preSwSc;
431		RealType c1, c2, c3, c4;
432	<	RealType erfcVal, derfcVal;
432	>	RealType erfcVal(1.0), derfcVal(0.0);
433		RealType BigR;
434	+	RealType two(2.0), three(3.0);
435
436		Vector3d Q_i, Q_j;
437		Vector3d ux_i, uy_i, uz_i;
#	Line 460 \| Line 441 \| namespace OpenMD {
441		Vector3d rhatdot2, rhatc4;
442		Vector3d dVdr;
443
444	+	// variables for indirect (reaction field) interactions for excluded pairs:
445	+	RealType indirect_Pot(0.0);
446	+	RealType indirect_vpair(0.0);
447	+	Vector3d indirect_dVdr(V3Zero);
448	+	Vector3d indirect_duduz_i(V3Zero), indirect_duduz_j(V3Zero);
449	+
450	+	RealType coulInt, vFluc1(0.0), vFluc2(0.0);
451		pair<RealType, RealType> res;
452
453	+	// splines for coulomb integrals
454	+	CubicSpline* J1;
455	+	CubicSpline* J2;
456	+
457		if (!initialized_) initialize();
458
459		ElectrostaticAtomData data1 = ElectrostaticMap[idat.atypes.first];
#	Line 478 \| Line 470 \| namespace OpenMD {
470		bool i_is_Dipole = data1.is_Dipole;
471		bool i_is_SplitDipole = data1.is_SplitDipole;
472		bool i_is_Quadrupole = data1.is_Quadrupole;
473	+	bool i_is_Fluctuating = data1.is_Fluctuating;
474
475		bool j_is_Charge = data2.is_Charge;
476		bool j_is_Dipole = data2.is_Dipole;
477		bool j_is_SplitDipole = data2.is_SplitDipole;
478		bool j_is_Quadrupole = data2.is_Quadrupole;
479	+	bool j_is_Fluctuating = data2.is_Fluctuating;
480
481	<	if (i_is_Charge)
482	<	q_i = data1.charge;
481	>	if (i_is_Charge) {
482	>	q_i = data1.fixedCharge;
483
484	+	if (i_is_Fluctuating) {
485	+	q_i += *(idat.flucQ1);
486	+	}
487	+
488	+	if (idat.excluded) {
489	+	*(idat.skippedCharge2) += q_i;
490	+	}
491	+	}
492	+
493		if (i_is_Dipole) {
494		mu_i = data1.dipole_moment;
495		uz_i = idat.eFrame1->getColumn(2);
#	Line 518 \| Line 521 \| namespace OpenMD {
521		duduz_i = V3Zero;
522		}
523
524	<	if (j_is_Charge)
525	<	q_j = data2.charge;
524	>	if (j_is_Charge) {
525	>	q_j = data2.fixedCharge;
526
527	+	if (i_is_Fluctuating)
528	+	q_j += *(idat.flucQ2);
529	+
530	+	if (idat.excluded) {
531	+	*(idat.skippedCharge1) += q_j;
532	+	}
533	+	}
534	+
535	+
536		if (j_is_Dipole) {
537		mu_j = data2.dipole_moment;
538		uz_j = idat.eFrame2->getColumn(2);
#	Line 552 \| Line 564 \| namespace OpenMD {
564		duduz_j = V3Zero;
565		}
566
567	+	if (i_is_Fluctuating && j_is_Fluctuating) {
568	+	J1 = Jij[idat.atypes];
569	+	J2 = Jij[make_pair(idat.atypes.second, idat.atypes.first)];
570	+	}
571	+
572		epot = 0.0;
573		dVdr = V3Zero;
574
#	Line 560 \| Line 577 \| namespace OpenMD {
577		if (j_is_Charge) {
578		if (screeningMethod_ == DAMPED) {
579		// assemble the damping variables
580	<	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
581	<	erfcVal = res.first;
582	<	derfcVal = res.second;
580	>	//res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
581	>	//erfcVal = res.first;
582	>	//derfcVal = res.second;
583	>
584	>	erfcVal = erfc(dampingAlpha_ * *(idat.rij));
585	>	derfcVal = - alphaPi_ * exp(-alpha2_ * *(idat.r2));
586	>
587		c1 = erfcVal * riji;
588		c2 = (-derfcVal + c1) * riji;
589		} else {
#	Line 581 \| Line 602 \| namespace OpenMD {
602		dudr = (idat.sw) preVal * (c2c_ - c2);
603
604		} else if (summationMethod_ == esm_REACTION_FIELD) {
605	<	rfVal = (idat.electroMult) preRF_ * (idat.rij) *(idat.rij) ;
605	>	rfVal = preRF_ * (idat.rij) *(idat.rij);
606	>
607		vterm = preVal * ( riji + rfVal );
608		dudr = (idat.sw) preVal * ( 2.0 * rfVal - riji ) * riji;
609	+
610	+	// if this is an excluded pair, there are still indirect
611	+	// interactions via the reaction field we must worry about:
612
613	+	if (idat.excluded) {
614	+	indirect_vpair += preVal * rfVal;
615	+	indirect_Pot += (idat.sw) preVal * rfVal;
616	+	indirect_dVdr += (idat.sw) preVal * two * rfVal * riji * rhat;
617	+	}
618	+
619		} else {
589	–	vterm = preVal * riji * erfcVal;
620
621	+	vterm = preVal * riji * erfcVal;
622		dudr = - (idat.sw) preVal * c2;
623	<
623	>
624		}
625	<
626	<	*(idat.vpair) += vterm;
625	>
626	>	vpair += vterm;
627		epot += (idat.sw) vterm;
628	+	dVdr += dudr * rhat;
629
630	<	dVdr += dudr * rhat;
630	>	if (i_is_Fluctuating) {
631	>	if (idat.excluded) {
632	>	// vFluc1 is the difference between the direct coulomb integral
633	>	// and the normal 1/r-like interaction between point charges.
634	>	coulInt = J1->getValueAt( *(idat.rij) );
635	>	vFluc1 = pre11_ * coulInt * q_i * q_j - ((idat.sw) vterm);
636	>	} else {
637	>	vFluc1 = 0.0;
638	>	}
639	>	(idat.dVdFQ1) += ( (idat.sw) * vterm + vFluc1 ) / q_i;
640	>	}
641	>
642	>	if (j_is_Fluctuating) {
643	>	if (idat.excluded) {
644	>	// vFluc2 is the difference between the direct coulomb integral
645	>	// and the normal 1/r-like interaction between point charges.
646	>	coulInt = J2->getValueAt( *(idat.rij) );
647	>	vFluc2 = pre11_ * coulInt * q_i * q_j - ((idat.sw) vterm);
648	>	} else {
649	>	vFluc2 = 0.0;
650	>	}
651	>	(idat.dVdFQ2) += ( (idat.sw) * vterm + vFluc2 ) / q_j;
652	>	}
653	>
654	>
655		}
656
657		if (j_is_Dipole) {
#	Line 608 \| Line 664 \| namespace OpenMD {
664		ri3 = ri2 * riji;
665
666		vterm = - pref * ct_j * ( ri2 - preRF2_ * *(idat.rij) );
667	<	*(idat.vpair) += vterm;
667	>	vpair += vterm;
668		epot += (idat.sw) vterm;
669
670	<	dVdr += -preSw * (ri3 * (uz_j - 3.0 * ct_j * rhat) - preRF2_*uz_j);
670	>	dVdr += -preSw * (ri3 * (uz_j - three * ct_j * rhat) - preRF2_*uz_j);
671		duduz_j += -preSw * rhat * (ri2 - preRF2_ * *(idat.rij) );
672
673	+	// Even if we excluded this pair from direct interactions,
674	+	// we still have the reaction-field-mediated charge-dipole
675	+	// interaction:
676	+
677	+	if (idat.excluded) {
678	+	indirect_vpair += pref * ct_j * preRF2_ * *(idat.rij);
679	+	indirect_Pot += preSw * ct_j * preRF2_ * *(idat.rij);
680	+	indirect_dVdr += preSw * preRF2_ * uz_j;
681	+	indirect_duduz_j += preSw * rhat * preRF2_ * *(idat.rij);
682	+	}
683	+
684		} else {
685		// determine the inverse r used if we have split dipoles
686		if (j_is_SplitDipole) {
#	Line 629 \| Line 696 \| namespace OpenMD {
696
697		if (screeningMethod_ == DAMPED) {
698		// assemble the damping variables
699	<	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
700	<	erfcVal = res.first;
701	<	derfcVal = res.second;
699	>	//res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
700	>	//erfcVal = res.first;
701	>	//derfcVal = res.second;
702	>	erfcVal = erfc(dampingAlpha_ * *(idat.rij));
703	>	derfcVal = - alphaPi_ * exp(-alpha2_ * *(idat.r2));
704		c1 = erfcVal * ri;
705		c2 = (-derfcVal + c1) * ri;
706		c3 = -2.0 * derfcVal * alpha2_ + 3.0 * c2 * ri;
#	Line 646 \| Line 715 \| namespace OpenMD {
715		// calculate the potential
716		pot_term = scale * c2;
717		vterm = -pref * ct_j * pot_term;
718	<	*(idat.vpair) += vterm;
718	>	vpair += vterm;
719		epot += (idat.sw) vterm;
720
721		// calculate derivatives for forces and torques
#	Line 655 \| Line 724 \| namespace OpenMD {
724		duduz_j += -preSw * pot_term * rhat;
725
726		}
727	+	if (i_is_Fluctuating) {
728	+	(idat.dVdFQ1) += ( (idat.sw) * vterm ) / q_i;
729	+	}
730		}
731
732		if (j_is_Quadrupole) {
#	Line 666 \| Line 738 \| namespace OpenMD {
738
739		if (screeningMethod_ == DAMPED) {
740		// assemble the damping variables
741	<	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
742	<	erfcVal = res.first;
743	<	derfcVal = res.second;
741	>	//res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
742	>	//erfcVal = res.first;
743	>	//derfcVal = res.second;
744	>	erfcVal = erfc(dampingAlpha_ * *(idat.rij));
745	>	derfcVal = - alphaPi_ * exp(-alpha2_ * *(idat.r2));
746		c1 = erfcVal * riji;
747		c2 = (-derfcVal + c1) * riji;
748		c3 = -2.0 * derfcVal * alpha2_ + 3.0 * c2 * riji;
#	Line 685 \| Line 759 \| namespace OpenMD {
759		c2ri = c2 * riji;
760		c3ri = c3 * riji;
761		c4rij = c4 * *(idat.rij) ;
762	<	rhatdot2 = 2.0 * rhat * c3;
762	>	rhatdot2 = two * rhat * c3;
763		rhatc4 = rhat * c4rij;
764
765		// calculate the potential
#	Line 693 \| Line 767 \| namespace OpenMD {
767		qyy_j * (cy2*c3 - c2ri) +
768		qzz_j * (cz2*c3 - c2ri) );
769		vterm = pref * pot_term;
770	<	*(idat.vpair) += vterm;
770	>	vpair += vterm;
771		epot += (idat.sw) vterm;
772
773		// calculate derivatives for the forces and torques
774
775	<	dVdr += -preSw * ( qxx_j* (cx2rhatc4 - (2.0cx_jux_j + rhat)c3ri) +
776	<	qyy_j* (cy2rhatc4 - (2.0cy_juy_j + rhat)c3ri) +
777	<	qzz_j* (cz2rhatc4 - (2.0cz_juz_j + rhat)c3ri));
775	>	dVdr += -preSw * ( qxx_j* (cx2rhatc4 - (twocx_jux_j + rhat)c3ri) +
776	>	qyy_j* (cy2rhatc4 - (twocy_juy_j + rhat)c3ri) +
777	>	qzz_j* (cz2rhatc4 - (twocz_juz_j + rhat)c3ri));
778
779		dudux_j += preSw * qxx_j * cx_j * rhatdot2;
780		duduy_j += preSw * qyy_j * cy_j * rhatdot2;
781		duduz_j += preSw * qzz_j * cz_j * rhatdot2;
782	+	if (i_is_Fluctuating) {
783	+	(idat.dVdFQ1) += ( (idat.sw) * vterm ) / q_i;
784	+	}
785	+
786		}
787		}
788
#	Line 721 \| Line 799 \| namespace OpenMD {
799		ri3 = ri2 * riji;
800
801		vterm = pref * ct_i * ( ri2 - preRF2_ * *(idat.rij) );
802	<	*(idat.vpair) += vterm;
802	>	vpair += vterm;
803		epot += (idat.sw) vterm;
804
805	<	dVdr += preSw * (ri3 * (uz_i - 3.0 * ct_i * rhat) - preRF2_ * uz_i);
805	>	dVdr += preSw * (ri3 * (uz_i - three * ct_i * rhat) - preRF2_ * uz_i);
806
807		duduz_i += preSw * rhat * (ri2 - preRF2_ * *(idat.rij) );
808	+
809	+	// Even if we excluded this pair from direct interactions,
810	+	// we still have the reaction-field-mediated charge-dipole
811	+	// interaction:
812	+
813	+	if (idat.excluded) {
814	+	indirect_vpair += -pref * ct_i * preRF2_ * *(idat.rij);
815	+	indirect_Pot += -preSw * ct_i * preRF2_ * *(idat.rij);
816	+	indirect_dVdr += -preSw * preRF2_ * uz_i;
817	+	indirect_duduz_i += -preSw * rhat * preRF2_ * *(idat.rij);
818	+	}
819
820		} else {
821
#	Line 744 \| Line 833 \| namespace OpenMD {
833
834		if (screeningMethod_ == DAMPED) {
835		// assemble the damping variables
836	<	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
837	<	erfcVal = res.first;
838	<	derfcVal = res.second;
836	>	//res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
837	>	//erfcVal = res.first;
838	>	//derfcVal = res.second;
839	>	erfcVal = erfc(dampingAlpha_ * *(idat.rij));
840	>	derfcVal = - alphaPi_ * exp(-alpha2_ * *(idat.r2));
841		c1 = erfcVal * ri;
842		c2 = (-derfcVal + c1) * ri;
843		c3 = -2.0 * derfcVal * alpha2_ + 3.0 * c2 * ri;
#	Line 761 \| Line 852 \| namespace OpenMD {
852		// calculate the potential
853		pot_term = c2 * scale;
854		vterm = pref * ct_i * pot_term;
855	<	*(idat.vpair) += vterm;
855	>	vpair += vterm;
856		epot += (idat.sw) vterm;
857
858		// calculate derivatives for the forces and torques
859		dVdr += preSw * (uz_i * c2ri - ct_i * rhat * sc2 * c3);
860		duduz_i += preSw * pot_term * rhat;
861		}
862	+
863	+	if (j_is_Fluctuating) {
864	+	(idat.dVdFQ2) += ( (idat.sw) * vterm ) / q_j;
865	+	}
866	+
867		}
868
869		if (j_is_Dipole) {
#	Line 784 \| Line 880 \| namespace OpenMD {
880
881		vterm = pref * ( ri3 * (ct_ij - 3.0 * ct_i * ct_j) -
882		preRF2_ * ct_ij );
883	<	*(idat.vpair) += vterm;
883	>	vpair += vterm;
884		epot += (idat.sw) vterm;
885
886		a1 = 5.0 * ct_i * ct_j - ct_ij;
887
888	<	dVdr += preSw * 3.0 * ri4 * (a1 * rhat - ct_i * uz_j - ct_j * uz_i);
888	>	dVdr += preSw * three * ri4 * (a1 * rhat - ct_i * uz_j - ct_j * uz_i);
889
890	<	duduz_i += preSw * (ri3 * (uz_j - 3.0 * ct_j * rhat) - preRF2_*uz_j);
891	<	duduz_j += preSw * (ri3 * (uz_i - 3.0 * ct_i * rhat) - preRF2_*uz_i);
890	>	duduz_i += preSw * (ri3 * (uz_j - three * ct_j * rhat) - preRF2_*uz_j);
891	>	duduz_j += preSw * (ri3 * (uz_i - three * ct_i * rhat) - preRF2_*uz_i);
892
893	+	if (idat.excluded) {
894	+	indirect_vpair += - pref * preRF2_ * ct_ij;
895	+	indirect_Pot += - preSw * preRF2_ * ct_ij;
896	+	indirect_duduz_i += -preSw * preRF2_ * uz_j;
897	+	indirect_duduz_j += -preSw * preRF2_ * uz_i;
898	+	}
899	+
900		} else {
901
902		if (i_is_SplitDipole) {
#	Line 816 \| Line 919 \| namespace OpenMD {
919		}
920		if (screeningMethod_ == DAMPED) {
921		// assemble damping variables
922	<	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
923	<	erfcVal = res.first;
924	<	derfcVal = res.second;
922	>	//res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
923	>	//erfcVal = res.first;
924	>	//derfcVal = res.second;
925	>	erfcVal = erfc(dampingAlpha_ * *(idat.rij));
926	>	derfcVal = - alphaPi_ * exp(-alpha2_ * *(idat.r2));
927		c1 = erfcVal * ri;
928		c2 = (-derfcVal + c1) * ri;
929		c3 = -2.0 * derfcVal * alpha2_ + 3.0 * c2 * ri;
#	Line 843 \| Line 948 \| namespace OpenMD {
948		// calculate the potential
949		pot_term = (ct_ij * c2ri - ctidotj * c3);
950		vterm = pref * pot_term;
951	<	*(idat.vpair) += vterm;
951	>	vpair += vterm;
952		epot += (idat.sw) vterm;
953
954		// calculate derivatives for the forces and torques
#	Line 867 \| Line 972 \| namespace OpenMD {
972
973		if (screeningMethod_ == DAMPED) {
974		// assemble the damping variables
975	<	res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
976	<	erfcVal = res.first;
977	<	derfcVal = res.second;
975	>	//res = erfcSpline_->getValueAndDerivativeAt( *(idat.rij) );
976	>	//erfcVal = res.first;
977	>	//derfcVal = res.second;
978	>	erfcVal = erfc(dampingAlpha_ * *(idat.rij));
979	>	derfcVal = - alphaPi_ * exp(-alpha2_ * *(idat.r2));
980		c1 = erfcVal * riji;
981		c2 = (-derfcVal + c1) * riji;
982		c3 = -2.0 * derfcVal * alpha2_ + 3.0 * c2 * riji;
#	Line 886 \| Line 993 \| namespace OpenMD {
993		c2ri = c2 * riji;
994		c3ri = c3 * riji;
995		c4rij = c4 * *(idat.rij) ;
996	<	rhatdot2 = 2.0 * rhat * c3;
996	>	rhatdot2 = two * rhat * c3;
997		rhatc4 = rhat * c4rij;
998
999		// calculate the potential
#	Line 895 \| Line 1002 \| namespace OpenMD {
1002		qzz_i * (cz2 * c3 - c2ri) );
1003
1004		vterm = pref * pot_term;
1005	<	*(idat.vpair) += vterm;
1005	>	vpair += vterm;
1006		epot += (idat.sw) vterm;
1007
1008		// calculate the derivatives for the forces and torques
1009
1010	<	dVdr += -preSw * (qxx_i* (cx2rhatc4 - (2.0cx_iux_i + rhat)c3ri) +
1011	<	qyy_i* (cy2rhatc4 - (2.0cy_iuy_i + rhat)c3ri) +
1012	<	qzz_i* (cz2rhatc4 - (2.0cz_iuz_i + rhat)c3ri));
1010	>	dVdr += -preSw * (qxx_i* (cx2rhatc4 - (twocx_iux_i + rhat)c3ri) +
1011	>	qyy_i* (cy2rhatc4 - (twocy_iuy_i + rhat)c3ri) +
1012	>	qzz_i* (cz2rhatc4 - (twocz_iuz_i + rhat)c3ri));
1013
1014		dudux_i += preSw * qxx_i * cx_i * rhatdot2;
1015		duduy_i += preSw * qyy_i * cy_i * rhatdot2;
1016		duduz_i += preSw * qzz_i * cz_i * rhatdot2;
1017	+
1018	+	if (j_is_Fluctuating) {
1019	+	(idat.dVdFQ2) += ( (idat.sw) * vterm ) / q_j;
1020	+	}
1021	+
1022		}
1023		}
1024
913	–	(*(idat.pot))[ELECTROSTATIC_FAMILY] += epot;
914	–	*(idat.f1) += dVdr;
1025
1026	<	if (i_is_Dipole \|\| i_is_Quadrupole)
1027	<	*(idat.t1) -= cross(uz_i, duduz_i);
1028	<	if (i_is_Quadrupole) {
1029	<	*(idat.t1) -= cross(ux_i, dudux_i);
1030	<	*(idat.t1) -= cross(uy_i, duduy_i);
1031	<	}
1032	<
1033	<	if (j_is_Dipole \|\| j_is_Quadrupole)
1034	<	*(idat.t2) -= cross(uz_j, duduz_j);
1035	<	if (j_is_Quadrupole) {
1036	<	*(idat.t2) -= cross(uz_j, dudux_j);
1037	<	*(idat.t2) -= cross(uz_j, duduy_j);
1038	<	}
1026	>	if (!idat.excluded) {
1027	>	*(idat.vpair) += vpair;
1028	>	(*(idat.pot))[ELECTROSTATIC_FAMILY] += epot;
1029	>	*(idat.f1) += dVdr;
1030	>
1031	>	if (i_is_Dipole \|\| i_is_Quadrupole)
1032	>	*(idat.t1) -= cross(uz_i, duduz_i);
1033	>	if (i_is_Quadrupole) {
1034	>	*(idat.t1) -= cross(ux_i, dudux_i);
1035	>	*(idat.t1) -= cross(uy_i, duduy_i);
1036	>	}
1037	>
1038	>	if (j_is_Dipole \|\| j_is_Quadrupole)
1039	>	*(idat.t2) -= cross(uz_j, duduz_j);
1040	>	if (j_is_Quadrupole) {
1041	>	*(idat.t2) -= cross(uz_j, dudux_j);
1042	>	*(idat.t2) -= cross(uz_j, duduy_j);
1043	>	}
1044
1045	<	return;
931	<	}
1045	>	} else {
1046
1047	<	void Electrostatic::calcSkipCorrection(InteractionData &idat) {
1047	>	// only accumulate the forces and torques resulting from the
1048	>	// indirect reaction field terms.
1049
1050	<	if (!initialized_) initialize();
1051	<
1052	<	ElectrostaticAtomData data1 = ElectrostaticMap[idat.atypes.first];
938	<	ElectrostaticAtomData data2 = ElectrostaticMap[idat.atypes.second];
939	<
940	<	// logicals
941	<
942	<	bool i_is_Charge = data1.is_Charge;
943	<	bool i_is_Dipole = data1.is_Dipole;
944	<
945	<	bool j_is_Charge = data2.is_Charge;
946	<	bool j_is_Dipole = data2.is_Dipole;
947	<
948	<	RealType q_i, q_j;
949	<
950	<	// The skippedCharge computation is needed by the real-space cutoff methods
951	<	// (i.e. shifted force and shifted potential)
952	<
953	<	if (i_is_Charge) {
954	<	q_i = data1.charge;
955	<	*(idat.skippedCharge2) += q_i;
956	<	}
957	<
958	<	if (j_is_Charge) {
959	<	q_j = data2.charge;
960	<	*(idat.skippedCharge1) += q_j;
961	<	}
962	<
963	<	// the rest of this function should only be necessary for reaction field.
964	<
965	<	if (summationMethod_ == esm_REACTION_FIELD) {
966	<	RealType riji, ri2, ri3;
967	<	RealType mu_i, ct_i;
968	<	RealType mu_j, ct_j;
969	<	RealType preVal, rfVal, vterm, dudr, pref, myPot(0.0);
970	<	Vector3d dVdr, uz_i, uz_j, duduz_i, duduz_j, rhat;
971	<
972	<	// some variables we'll need independent of electrostatic type:
1050	>	*(idat.vpair) += indirect_vpair;
1051	>	(*(idat.pot))[ELECTROSTATIC_FAMILY] += indirect_Pot;
1052	>	*(idat.f1) += indirect_dVdr;
1053
974	–	riji = 1.0 / *(idat.rij) ;
975	–	rhat = (idat.d) riji;
976	–
977	–	if (i_is_Dipole) {
978	–	mu_i = data1.dipole_moment;
979	–	uz_i = idat.eFrame1->getColumn(2);
980	–	ct_i = dot(uz_i, rhat);
981	–	duduz_i = V3Zero;
982	–	}
983	–
984	–	if (j_is_Dipole) {
985	–	mu_j = data2.dipole_moment;
986	–	uz_j = idat.eFrame2->getColumn(2);
987	–	ct_j = dot(uz_j, rhat);
988	–	duduz_j = V3Zero;
989	–	}
990	–
991	–	if (i_is_Charge) {
992	–	if (j_is_Charge) {
993	–	preVal = (idat.electroMult) pre11_ * q_i * q_j;
994	–	rfVal = preRF_ * (idat.rij) *(idat.rij) ;
995	–	vterm = preVal * rfVal;
996	–	myPot += (idat.sw) vterm;
997	–	dudr = (idat.sw) preVal * 2.0 * rfVal * riji;
998	–	dVdr += dudr * rhat;
999	–	}
1000	–
1001	–	if (j_is_Dipole) {
1002	–	ri2 = riji * riji;
1003	–	ri3 = ri2 * riji;
1004	–	pref = (idat.electroMult) pre12_ * q_i * mu_j;
1005	–	vterm = - pref * ct_j * ( ri2 - preRF2_ * *(idat.rij) );
1006	–	myPot += (idat.sw) vterm;
1007	–	dVdr += - (idat.sw) pref * ( ri3 * ( uz_j - 3.0 * ct_j * rhat) - preRF2_ * uz_j);
1008	–	duduz_j += - (idat.sw) pref * rhat * (ri2 - preRF2_ * *(idat.rij) );
1009	–	}
1010	–	}
1011	–	if (i_is_Dipole) {
1012	–	if (j_is_Charge) {
1013	–	ri2 = riji * riji;
1014	–	ri3 = ri2 * riji;
1015	–	pref = (idat.electroMult) pre12_ * q_j * mu_i;
1016	–	vterm = - pref * ct_i * ( ri2 - preRF2_ * *(idat.rij) );
1017	–	myPot += (idat.sw) vterm;
1018	–	dVdr += (idat.sw) pref * ( ri3 * ( uz_i - 3.0 * ct_i * rhat) - preRF2_ * uz_i);
1019	–	duduz_i += (idat.sw) pref * rhat * (ri2 - preRF2_ * *(idat.rij));
1020	–	}
1021	–	}
1022	–
1023	–	// accumulate the forces and torques resulting from the self term
1024	–	(*(idat.pot))[ELECTROSTATIC_FAMILY] += myPot;
1025	–	*(idat.f1) += dVdr;
1026	–
1054		if (i_is_Dipole)
1055	<	*(idat.t1) -= cross(uz_i, duduz_i);
1055	>	*(idat.t1) -= cross(uz_i, indirect_duduz_i);
1056		if (j_is_Dipole)
1057	<	*(idat.t2) -= cross(uz_j, duduz_j);
1057	>	*(idat.t2) -= cross(uz_j, indirect_duduz_j);
1058		}
1059	<	}
1059	>
1060	>	return;
1061	>	}
1062
1063		void Electrostatic::calcSelfCorrection(SelfData &sdat) {
1064		RealType mu1, preVal, chg1, self;
#	Line 1057 \| Line 1086 \| namespace OpenMD {
1086		}
1087		} else if (summationMethod_ == esm_SHIFTED_FORCE \|\| summationMethod_ == esm_SHIFTED_POTENTIAL) {
1088		if (i_is_Charge) {
1089	<	chg1 = data.charge;
1089	>	chg1 = data.fixedCharge;
1090		if (screeningMethod_ == DAMPED) {
1091		self = - 0.5 * (c1c_ + alphaPi_) * chg1 * (chg1 + (sdat.skippedCharge)) pre11_;
1092		} else {

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Comparing branches/development/src/nonbonded/Electrostatic.cpp (file contents): Revision 1586 by gezelter, Tue Jun 21 06:34:35 2011 UTC vs. Revision 1723 by gezelter, Thu May 24 20:59:54 2012 UTC

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Comparing branches/development/src/nonbonded/Electrostatic.cpp (file contents):
Revision 1586 by gezelter, Tue Jun 21 06:34:35 2011 UTC vs.
Revision 1723 by gezelter, Thu May 24 20:59:54 2012 UTC