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

Comparing branches/development/src/nonbonded/SC.cpp (file contents):
Revision 1554 by gezelter, Sat Apr 30 02:54:02 2011 UTC vs.
Revision 1710 by gezelter, Fri May 18 21:44:02 2012 UTC

#	Line 36 \| Line 36
36		* [1] Meineke, et al., J. Comp. Chem. 26, 252-271 (2005).
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 53 \| Line 54 \| namespace OpenMD {
54		SC::SC() : name_("SC"), initialized_(false), forceField_(NULL),
55		scRcut_(0.0), np_(3000) {}
56
56	–	SCParam SC::getSCParam(AtomType* atomType) {
57	–
58	–	// Do sanity checking on the AtomType we were passed before
59	–	// building any data structures:
60	–	if (!atomType->isSC()) {
61	–	sprintf( painCave.errMsg,
62	–	"SC::getSCParam was passed an atomType (%s) that does not\n"
63	–	"\tappear to be a Sutton-Chen (SC) atom.\n",
64	–	atomType->getName().c_str());
65	–	painCave.severity = OPENMD_ERROR;
66	–	painCave.isFatal = 1;
67	–	simError();
68	–	}
69	–
70	–	GenericData* data = atomType->getPropertyByName("SC");
71	–	if (data == NULL) {
72	–	sprintf( painCave.errMsg, "SC::getSCParam could not find SC\n"
73	–	"\tparameters for atomType %s.\n",
74	–	atomType->getName().c_str());
75	–	painCave.severity = OPENMD_ERROR;
76	–	painCave.isFatal = 1;
77	–	simError();
78	–	}
79	–
80	–	SCParamGenericData* scData = dynamic_cast<SCParamGenericData*>(data);
81	–	if (scData == NULL) {
82	–	sprintf( painCave.errMsg,
83	–	"SC::getSCParam could not convert GenericData to SCParamGenericData\n"
84	–	"\tfor atom type %s\n", atomType->getName().c_str());
85	–	painCave.severity = OPENMD_ERROR;
86	–	painCave.isFatal = 1;
87	–	simError();
88	–	}
89	–
90	–	return scData->getData();
91	–	}
92	–
93	–	RealType SC::getC(AtomType* atomType) {
94	–	SCParam scParam = getSCParam(atomType);
95	–	return scParam.c;
96	–	}
97	–
98	–	RealType SC::getM(AtomType* atomType) {
99	–	SCParam scParam = getSCParam(atomType);
100	–	return scParam.m;
101	–	}
102	–
57		RealType SC::getM(AtomType* atomType1, AtomType* atomType2) {
58	<	RealType m1 = getM(atomType1);
59	<	RealType m2 = getM(atomType2);
58	>	SuttonChenAdapter sca1 = SuttonChenAdapter(atomType1);
59	>	SuttonChenAdapter sca2 = SuttonChenAdapter(atomType2);
60	>	RealType m1 = sca1.getM();
61	>	RealType m2 = sca2.getM();
62		return 0.5 * (m1 + m2);
63		}
64
109	–	RealType SC::getN(AtomType* atomType) {
110	–	SCParam scParam = getSCParam(atomType);
111	–	return scParam.n;
112	–	}
113	–
65		RealType SC::getN(AtomType* atomType1, AtomType* atomType2) {
66	<	RealType n1 = getN(atomType1);
67	<	RealType n2 = getN(atomType2);
66	>	SuttonChenAdapter sca1 = SuttonChenAdapter(atomType1);
67	>	SuttonChenAdapter sca2 = SuttonChenAdapter(atomType2);
68	>	RealType n1 = sca1.getN();
69	>	RealType n2 = sca2.getN();
70		return 0.5 * (n1 + n2);
71		}
72
120	–	RealType SC::getAlpha(AtomType* atomType) {
121	–	SCParam scParam = getSCParam(atomType);
122	–	return scParam.alpha;
123	–	}
124	–
73		RealType SC::getAlpha(AtomType* atomType1, AtomType* atomType2) {
74	<	RealType alpha1 = getAlpha(atomType1);
75	<	RealType alpha2 = getAlpha(atomType2);
74	>	SuttonChenAdapter sca1 = SuttonChenAdapter(atomType1);
75	>	SuttonChenAdapter sca2 = SuttonChenAdapter(atomType2);
76	>	RealType alpha1 = sca1.getAlpha();
77	>	RealType alpha2 = sca2.getAlpha();
78
79		ForceFieldOptions& fopts = forceField_->getForceFieldOptions();
80		std::string DistanceMix = fopts.getDistanceMixingRule();
#	Line 136 \| Line 86 \| namespace OpenMD {
86		return 0.5 * (alpha1 + alpha2);
87		}
88
89	<	RealType SC::getEpsilon(AtomType* atomType) {
90	<	SCParam scParam = getSCParam(atomType);
91	<	return scParam.epsilon;
92	<	}
93	<
144	<	RealType SC::getEpsilon(AtomType* atomType1, AtomType* atomType2) {
145	<	RealType epsilon1 = getEpsilon(atomType1);
146	<	RealType epsilon2 = getEpsilon(atomType2);
89	>	RealType SC::getEpsilon(AtomType* atomType1, AtomType* atomType2) {
90	>	SuttonChenAdapter sca1 = SuttonChenAdapter(atomType1);
91	>	SuttonChenAdapter sca2 = SuttonChenAdapter(atomType2);
92	>	RealType epsilon1 = sca1.getEpsilon();
93	>	RealType epsilon2 = sca2.getEpsilon();
94		return sqrt(epsilon1 * epsilon2);
95		}
96
#	Line 155 \| Line 102 \| namespace OpenMD {
102
103		for (at = atomTypes->beginType(i); at != NULL;
104		at = atomTypes->nextType(i)) {
105	<	if (at->isSC())
105	>	SuttonChenAdapter sca = SuttonChenAdapter(at);
106	>	if (sca.isSuttonChen())
107		addType(at);
108		}
109		initialized_ = true;
#	Line 165 \| Line 113 \| namespace OpenMD {
113
114		void SC::addType(AtomType* atomType){
115
116	+	SuttonChenAdapter sca = SuttonChenAdapter(atomType);
117		SCAtomData scAtomData;
118
119	<	scAtomData.c = getC(atomType);
120	<	scAtomData.m = getM(atomType);
121	<	scAtomData.n = getN(atomType);
122	<	scAtomData.alpha = getAlpha(atomType);
123	<	scAtomData.epsilon = getEpsilon(atomType);
119	>	scAtomData.c = sca.getC();
120	>	scAtomData.m = sca.getM();
121	>	scAtomData.n = sca.getN();
122	>	scAtomData.alpha = sca.getAlpha();
123	>	scAtomData.epsilon = sca.getEpsilon();
124		scAtomData.rCut = 2.0 * scAtomData.alpha;
125
126		// add it to the map:
178	–	AtomTypeProperties atp = atomType->getATP();
127
128		pair<map<int,AtomType*>::iterator,bool> ret;
129	<	ret = SClist.insert( pair<int, AtomType*>(atp.ident, atomType) );
129	>	ret = SClist.insert( pair<int, AtomType*>(atomType->getIdent(), atomType) );
130		if (ret.second == false) {
131		sprintf( painCave.errMsg,
132		"SC already had a previous entry with ident %d\n",
133	<	atp.ident);
133	>	atomType->getIdent() );
134		painCave.severity = OPENMD_INFO;
135		painCave.isFatal = 0;
136		simError();
#	Line 306 \| Line 254 \| namespace OpenMD {
254
255		if (!initialized_) initialize();
256
257	<	SCInteractionData mixer = MixingMap[ *(idat.atypes) ];
257	>	SCInteractionData mixer = MixingMap[ idat.atypes ];
258
259		RealType rcij = mixer.rCut;
260
261		if ( *(idat.rij) < rcij) {
262	<	(idat.rho_i_at_j) = mixer.phi->getValueAt( (idat.rij) );
263	<	(idat.rho_j_at_i) = (idat.rho_i_at_j);
264	<	} else {
265	<	*(idat.rho_i_at_j) = 0.0;
318	<	*(idat.rho_j_at_i) = 0.0;
319	<	}
262	>	RealType rho = mixer.phi->getValueAt( *(idat.rij) );
263	>	*(idat.rho1) += rho;
264	>	*(idat.rho2) += rho;
265	>	}
266
267		return;
268		}
#	Line 326 \| Line 272 \| namespace OpenMD {
272		if (!initialized_) initialize();
273
274		SCAtomData data1 = SCMap[sdat.atype];
275	<
276	<	(sdat.frho) = - data1.c data1.epsilon * sqrt( *(sdat.rho) );
275	>
276	>	RealType u = - data1.c * data1.epsilon * sqrt( *(sdat.rho) );
277	>	*(sdat.frho) = u;
278		(sdat.dfrhodrho) = 0.5 (sdat.frho) / (sdat.rho);
279	+
280	+	(*(sdat.pot))[METALLIC_FAMILY] += u;
281	+	*(sdat.particlePot) += u;
282
283		return;
284		}
#	Line 338 \| Line 288 \| namespace OpenMD {
288
289		if (!initialized_) initialize();
290
291	<	SCAtomData data1 = SCMap[idat.atypes->first];
292	<	SCAtomData data2 = SCMap[idat.atypes->second];
291	>	SCAtomData data1 = SCMap[idat.atypes.first];
292	>	SCAtomData data2 = SCMap[idat.atypes.second];
293
294	<	SCInteractionData mixer = MixingMap[*(idat.atypes)];
294	>	SCInteractionData mixer = MixingMap[idat.atypes];
295
296		RealType rcij = mixer.rCut;
297
#	Line 365 \| Line 315 \| namespace OpenMD {
315
316		(idat.f1) += (idat.d) * dudr / *(idat.rij) ;
317
318	<	// particle_pot is the difference between the full potential
319	<	// and the full potential without the presence of a particular
318	>	// particlePot is the difference between the full potential and
319	>	// the full potential without the presence of a particular
320		// particle (atom1).
321		//
322	<	// This reduces the density at other particle locations, so
323	<	// we need to recompute the density at atom2 assuming atom1
324	<	// didn't contribute. This then requires recomputing the
325	<	// density functional for atom2 as well.
326	<	//
327	<	// Most of the particle_pot heavy lifting comes from the
328	<	// pair interaction, and will be handled by vpair.
322	>	// This reduces the density at other particle locations, so we
323	>	// need to recompute the density at atom2 assuming atom1 didn't
324	>	// contribute. This then requires recomputing the density
325	>	// functional for atom2 as well.
326	>
327	>	(idat.particlePot1) -= data2.c data2.epsilon *
328	>	sqrt( (idat.rho2) - rhtmp) + (idat.frho2);
329	>
330	>	(idat.particlePot2) -= data1.c data1.epsilon *
331	>	sqrt( (idat.rho1) - rhtmp) + (idat.frho1);
332
333	<	(idat.fshift1) = - data1.c data1.epsilon * sqrt( *(idat.rho1) - rhtmp);
381	<	(idat.fshift2) = - data2.c data2.epsilon * sqrt( *(idat.rho2) - rhtmp);
382	<
383	<	idat.pot[METALLIC_FAMILY] += pot_temp;
333	>	(*(idat.pot))[METALLIC_FAMILY] += pot_temp;
334		}
335
336		return;

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Comparing branches/development/src/nonbonded/SC.cpp (file contents): Revision 1554 by gezelter, Sat Apr 30 02:54:02 2011 UTC vs. Revision 1710 by gezelter, Fri May 18 21:44:02 2012 UTC

Diff Legend

Comparing branches/development/src/nonbonded/SC.cpp (file contents):
Revision 1554 by gezelter, Sat Apr 30 02:54:02 2011 UTC vs.
Revision 1710 by gezelter, Fri May 18 21:44:02 2012 UTC