[ViewVC] Diff of: group/trunk/OOPSE/libmdtools/Thermo.cpp

Comparing trunk/OOPSE/libmdtools/Thermo.cpp (file contents):
Revision 614 by mmeineke, Tue Jul 15 17:57:04 2003 UTC vs.
Revision 1133 by gezelter, Mon Apr 26 14:29:18 2004 UTC

#	Line 1 \| Line 1
1	<	#include <cmath>
1	>	#include <math.h>
2		#include <iostream>
3		using namespace std;
4
#	Line 10 \| Line 10 \| using namespace std;
10		#include "SRI.hpp"
11		#include "Integrator.hpp"
12		#include "simError.h"
13	+	#include "MatVec3.h"
14
15		#ifdef IS_MPI
16		#define __C
17		#include "mpiSimulation.hpp"
18		#endif // is_mpi
19
20	+	inline double roundMe( double x ){
21	+	return ( x >= 0 ) ? floor( x + 0.5 ) : ceil( x - 0.5 );
22	+	}
23
20	–	#define BASE_SEED 123456789
21	–
24		Thermo::Thermo( SimInfo* the_info ) {
25		info = the_info;
26	<	int baseSeed = BASE_SEED;
26	>	int baseSeed = the_info->getSeed();
27
28		gaussStream = new gaussianSPRNG( baseSeed );
29		}
#	Line 36 \| Line 38 \| double Thermo::getKinetic(){
38		double kinetic;
39		double amass;
40		double aVel[3], aJ[3], I[3][3];
41	<	int j, kl;
41	>	int i, j, k, kl;
42
41	–	DirectionalAtom *dAtom;
42	–
43	–	int n_atoms;
43		double kinetic_global;
44	<	Atom** atoms;
46	<
44	>	vector<StuntDouble *> integrableObjects = info->integrableObjects;
45
48	–	n_atoms = info->n_atoms;
49	–	atoms = info->atoms;
50	–
46		kinetic = 0.0;
47		kinetic_global = 0.0;
53	–	for( kl=0; kl < n_atoms; kl++ ){
54	–
55	–	atoms[kl]->getVel(aVel);
56	–	amass = atoms[kl]->getMass();
57	–
58	–	for (j=0; j < 3; j++)
59	–	kinetic += amass * aVel[j] * aVel[j];
48
49	<	if( atoms[kl]->isDirectional() ){
50	<
51	<	dAtom = (DirectionalAtom *)atoms[kl];
49	>	for (kl=0; kl<integrableObjects.size(); kl++) {
50	>	integrableObjects[kl]->getVel(aVel);
51	>	amass = integrableObjects[kl]->getMass();
52
53	<	dAtom->getJ( aJ );
54	<	dAtom->getI( I );
55	<
56	<	for (j=0; j<3; j++)
57	<	kinetic += aJ[j]*aJ[j] / I[j][j];
58	<
59	<	}
53	>	for(j=0; j<3; j++)
54	>	kinetic += amassaVel[j]aVel[j];
55	>
56	>	if (integrableObjects[kl]->isDirectional()){
57	>
58	>	integrableObjects[kl]->getJ( aJ );
59	>	integrableObjects[kl]->getI( I );
60	>
61	>	if (integrableObjects[kl]->isLinear()) {
62	>	i = integrableObjects[kl]->linearAxis();
63	>	j = (i+1)%3;
64	>	k = (i+2)%3;
65	>	kinetic += aJ[j]aJ[j]/I[j][j] + aJ[k]aJ[k]/I[k][k];
66	>	} else {
67	>	for (j=0; j<3; j++)
68	>	kinetic += aJ[j]*aJ[j] / I[j][j];
69	>	}
70	>	}
71		}
72		#ifdef IS_MPI
73		MPI_Allreduce(&kinetic,&kinetic_global,1,MPI_DOUBLE,
74		MPI_SUM, MPI_COMM_WORLD);
75		kinetic = kinetic_global;
76		#endif //is_mpi
77	<
77	>
78		kinetic = kinetic * 0.5 / e_convert;
79
80		return kinetic;
#	Line 107 \| Line 106 \| double Thermo::getPotential(){
106		potential = potential_local;
107		#endif // is_mpi
108
110	–	#ifdef IS_MPI
111	–	/*
112	–	std::cerr << "node " << worldRank << ": after pot = " << potential << "\n";
113	–	*/
114	–	#endif
115	–
109		return potential;
110		}
111
#	Line 126 \| Line 119 \| double Thermo::getTemperature(){
119
120		double Thermo::getTemperature(){
121
122	<	const double kb = 1.9872179E-3; // boltzman's constant in kcal/(mol K)
122	>	const double kb = 1.9872156E-3; // boltzman's constant in kcal/(mol K)
123		double temperature;
124	<
124	>
125		temperature = ( 2.0 * this->getKinetic() ) / ((double)info->ndf * kb );
126		return temperature;
127		}
128
136	–	double Thermo::getEnthalpy() {
137	–
138	–	const double e_convert = 4.184E-4; // convert kcal/mol -> (amu A^2)/fs^2
139	–	double u, p, v;
140	–	double press[3][3];
141	–
142	–	u = this->getTotalE();
143	–
144	–	this->getPressureTensor(press);
145	–	p = (press[0][0] + press[1][1] + press[2][2]) / 3.0;
146	–
147	–	v = this->getVolume();
148	–
149	–	return (u + (p*v)/e_convert);
150	–	}
151	–
129		double Thermo::getVolume() {
130
131		return info->boxVol;
#	Line 167 \| Line 144 \| double Thermo::getPressure() {
144		pressure = p_convert * (press[0][0] + press[1][1] + press[2][2]) / 3.0;
145
146		return pressure;
147	+	}
148	+
149	+	double Thermo::getPressureX() {
150	+
151	+	// Relies on the calculation of the full molecular pressure tensor
152	+
153	+	const double p_convert = 1.63882576e8;
154	+	double press[3][3];
155	+	double pressureX;
156	+
157	+	this->getPressureTensor(press);
158	+
159	+	pressureX = p_convert * press[0][0];
160	+
161	+	return pressureX;
162		}
163
164	+	double Thermo::getPressureY() {
165
166	+	// Relies on the calculation of the full molecular pressure tensor
167	+
168	+	const double p_convert = 1.63882576e8;
169	+	double press[3][3];
170	+	double pressureY;
171	+
172	+	this->getPressureTensor(press);
173	+
174	+	pressureY = p_convert * press[1][1];
175	+
176	+	return pressureY;
177	+	}
178	+
179	+	double Thermo::getPressureZ() {
180	+
181	+	// Relies on the calculation of the full molecular pressure tensor
182	+
183	+	const double p_convert = 1.63882576e8;
184	+	double press[3][3];
185	+	double pressureZ;
186	+
187	+	this->getPressureTensor(press);
188	+
189	+	pressureZ = p_convert * press[2][2];
190	+
191	+	return pressureZ;
192	+	}
193	+
194	+
195		void Thermo::getPressureTensor(double press[3][3]){
196		// returns pressure tensor in units amufs^-2Ang^-1
197		// routine derived via viral theorem description in:
#	Line 178 \| Line 200 \| void Thermo::getPressureTensor(double press[3][3]){
200		const double e_convert = 4.184e-4;
201
202		double molmass, volume;
203	<	double vcom[3];
203	>	double vcom[3], pcom[3], fcom[3], scaled[3];
204		double p_local[9], p_global[9];
205		int i, j, k, nMols;
206		Molecule* molecules;
#	Line 193 \| Line 215 \| void Thermo::getPressureTensor(double press[3][3]){
215		p_global[i] = 0.0;
216		}
217
218	<	for (i=0; i < nMols; i++) {
197	<	molmass = molecules[i].getCOMvel(vcom);
218	>	for (i=0; i < info->integrableObjects.size(); i++) {
219
220	<	p_local[0] += molmass * (vcom[0] * vcom[0]);
221	<	p_local[1] += molmass * (vcom[0] * vcom[1]);
222	<	p_local[2] += molmass * (vcom[0] * vcom[2]);
223	<	p_local[3] += molmass * (vcom[1] * vcom[0]);
224	<	p_local[4] += molmass * (vcom[1] * vcom[1]);
225	<	p_local[5] += molmass * (vcom[1] * vcom[2]);
226	<	p_local[6] += molmass * (vcom[2] * vcom[0]);
227	<	p_local[7] += molmass * (vcom[2] * vcom[1]);
228	<	p_local[8] += molmass * (vcom[2] * vcom[2]);
220	>	molmass = info->integrableObjects[i]->getMass();
221	>
222	>	info->integrableObjects[i]->getVel(vcom);
223	>	info->integrableObjects[i]->getPos(pcom);
224	>	info->integrableObjects[i]->getFrc(fcom);
225	>
226	>	matVecMul3(info->HmatInv, pcom, scaled);
227	>
228	>	for(j=0; j<3; j++)
229	>	scaled[j] -= roundMe(scaled[j]);
230	>
231	>	// calc the wrapped real coordinates from the wrapped scaled coordinates
232	>
233	>	matVecMul3(info->Hmat, scaled, pcom);
234	>
235	>	p_local[0] += molmass * (vcom[0] * vcom[0]) + fcom[0]pcom[0]eConvert;
236	>	p_local[1] += molmass * (vcom[0] * vcom[1]) + fcom[0]pcom[1]eConvert;
237	>	p_local[2] += molmass * (vcom[0] * vcom[2]) + fcom[0]pcom[2]eConvert;
238	>	p_local[3] += molmass * (vcom[1] * vcom[0]) + fcom[1]pcom[0]eConvert;
239	>	p_local[4] += molmass * (vcom[1] * vcom[1]) + fcom[1]pcom[1]eConvert;
240	>	p_local[5] += molmass * (vcom[1] * vcom[2]) + fcom[1]pcom[2]eConvert;
241	>	p_local[6] += molmass * (vcom[2] * vcom[0]) + fcom[2]pcom[0]eConvert;
242	>	p_local[7] += molmass * (vcom[2] * vcom[1]) + fcom[2]pcom[1]eConvert;
243	>	p_local[8] += molmass * (vcom[2] * vcom[2]) + fcom[2]pcom[2]eConvert;
244	>
245		}
246
247		// Get total for entire system from MPI.
#	Line 222 \| Line 259 \| void Thermo::getPressureTensor(double press[3][3]){
259		for(i = 0; i < 3; i++) {
260		for (j = 0; j < 3; j++) {
261		k = 3*i + j;
262	<	press[i][j] = (p_global[k] + info->tau[k]*e_convert) / volume;
262	>	press[i][j] = p_global[k] / volume;
263
264		}
265		}
#	Line 230 \| Line 267 \| void Thermo::velocitize() {
267
268		void Thermo::velocitize() {
269
233	–	double x,y;
270		double aVel[3], aJ[3], I[3][3];
271	<	int i, j, vr, vd; // velocity randomizer loop counters
271	>	int i, j, l, m, n, vr, vd; // velocity randomizer loop counters
272		double vdrift[3];
273		double vbar;
274		const double kb = 8.31451e-7; // kb in amu, angstroms, fs, etc.
275		double av2;
276		double kebar;
241	–	int n_atoms;
242	–	Atom** atoms;
243	–	DirectionalAtom* dAtom;
277		double temperature;
278	<	int n_oriented;
246	<	int n_constraints;
278	>	int nobj;
279
280	<	atoms = info->atoms;
281	<	n_atoms = info->n_atoms;
280	>	nobj = info->integrableObjects.size();
281	>
282		temperature = info->target_temp;
251	–	n_oriented = info->n_oriented;
252	–	n_constraints = info->n_constraints;
283
284	<	kebar = kb * temperature * (double)info->ndf /
285	<	( 2.0 * (double)info->ndfRaw );
284	>	kebar = kb * temperature * (double)info->ndfRaw /
285	>	( 2.0 * (double)info->ndf );
286
287	<	for(vr = 0; vr < n_atoms; vr++){
287	>	for(vr = 0; vr < nobj; vr++){
288
289		// uses equipartition theory to solve for vbar in angstrom/fs
290
291	<	av2 = 2.0 * kebar / atoms[vr]->getMass();
291	>	av2 = 2.0 * kebar / info->integrableObjects[vr]->getMass();
292		vbar = sqrt( av2 );
293	<
264	<	// vbar = sqrt( 8.31451e-7 * temperature / atoms[vr]->getMass() );
265	<
293	>
294		// picks random velocities from a gaussian distribution
295		// centered on vbar
296
297		for (j=0; j<3; j++)
298		aVel[j] = vbar * gaussStream->getGaussian();
299
300	<	atoms[vr]->setVel( aVel );
300	>	info->integrableObjects[vr]->setVel( aVel );
301	>
302	>	if(info->integrableObjects[vr]->isDirectional()){
303
304	+	info->integrableObjects[vr]->getI( I );
305	+
306	+	if (info->integrableObjects[vr]->isLinear()) {
307	+
308	+	l= info->integrableObjects[vr]->linearAxis();
309	+	m = (l+1)%3;
310	+	n = (l+2)%3;
311	+
312	+	aJ[l] = 0.0;
313	+	vbar = sqrt( 2.0 * kebar * I[m][m] );
314	+	aJ[m] = vbar * gaussStream->getGaussian();
315	+	vbar = sqrt( 2.0 * kebar * I[n][n] );
316	+	aJ[n] = vbar * gaussStream->getGaussian();
317	+
318	+	} else {
319	+	for (j = 0 ; j < 3; j++) {
320	+	vbar = sqrt( 2.0 * kebar * I[j][j] );
321	+	aJ[j] = vbar * gaussStream->getGaussian();
322	+	}
323	+	} // else isLinear
324	+
325	+	info->integrableObjects[vr]->setJ( aJ );
326	+
327	+	}//isDirectional
328	+
329		}
330
331		// Get the Center of Mass drift velocity.
#	Line 280 \| Line 335 \| void Thermo::velocitize() {
335		// Corrects for the center of mass drift.
336		// sums all the momentum and divides by total mass.
337
338	<	for(vd = 0; vd < n_atoms; vd++){
338	>	for(vd = 0; vd < nobj; vd++){
339
340	<	atoms[vd]->getVel(aVel);
340	>	info->integrableObjects[vd]->getVel(aVel);
341
342		for (j=0; j < 3; j++)
343		aVel[j] -= vdrift[j];
344
345	<	atoms[vd]->setVel( aVel );
345	>	info->integrableObjects[vd]->setVel( aVel );
346		}
292	–	if( n_oriented ){
293	–
294	–	for( i=0; i<n_atoms; i++ ){
295	–
296	–	if( atoms[i]->isDirectional() ){
297	–
298	–	dAtom = (DirectionalAtom *)atoms[i];
299	–	dAtom->getI( I );
300	–
301	–	for (j = 0 ; j < 3; j++) {
347
303	–	vbar = sqrt( 2.0 * kebar * I[j][j] );
304	–	aJ[j] = vbar * gaussStream->getGaussian();
305	–
306	–	}
307	–
308	–	dAtom->setJ( aJ );
309	–
310	–	}
311	–	}
312	–	}
348		}
349
350		void Thermo::getCOMVel(double vdrift[3]){
#	Line 317 \| Line 352 \| void Thermo::getCOMVel(double vdrift[3]){
352		double mtot, mtot_local;
353		double aVel[3], amass;
354		double vdrift_local[3];
355	<	int vd, n_atoms, j;
356	<	Atom** atoms;
355	>	int vd, j;
356	>	int nobj;
357
358	<	// We are very careless here with the distinction between n_atoms and n_local
324	<	// We should really fix this before someone pokes an eye out.
358	>	nobj = info->integrableObjects.size();
359
326	–	n_atoms = info->n_atoms;
327	–	atoms = info->atoms;
328	–
360		mtot_local = 0.0;
361		vdrift_local[0] = 0.0;
362		vdrift_local[1] = 0.0;
363		vdrift_local[2] = 0.0;
364
365	<	for(vd = 0; vd < n_atoms; vd++){
365	>	for(vd = 0; vd < nobj; vd++){
366
367	<	amass = atoms[vd]->getMass();
368	<	atoms[vd]->getVel( aVel );
367	>	amass = info->integrableObjects[vd]->getMass();
368	>	info->integrableObjects[vd]->getVel( aVel );
369
370		for(j = 0; j < 3; j++)
371		vdrift_local[j] += aVel[j] * amass;
#	Line 358 \| Line 389 \| void Thermo::getCOMVel(double vdrift[3]){
389
390		}
391
392	+	void Thermo::getCOM(double COM[3]){
393	+
394	+	double mtot, mtot_local;
395	+	double aPos[3], amass;
396	+	double COM_local[3];
397	+	int i, j;
398	+	int nobj;
399	+
400	+	mtot_local = 0.0;
401	+	COM_local[0] = 0.0;
402	+	COM_local[1] = 0.0;
403	+	COM_local[2] = 0.0;
404	+
405	+	nobj = info->integrableObjects.size();
406	+	for(i = 0; i < nobj; i++){
407	+
408	+	amass = info->integrableObjects[i]->getMass();
409	+	info->integrableObjects[i]->getPos( aPos );
410	+
411	+	for(j = 0; j < 3; j++)
412	+	COM_local[j] += aPos[j] * amass;
413	+
414	+	mtot_local += amass;
415	+	}
416	+
417	+	#ifdef IS_MPI
418	+	MPI_Allreduce(&mtot_local,&mtot,1,MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
419	+	MPI_Allreduce(COM_local,COM,3,MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
420	+	#else
421	+	mtot = mtot_local;
422	+	for(i = 0; i < 3; i++) {
423	+	COM[i] = COM_local[i];
424	+	}
425	+	#endif
426	+
427	+	for (i = 0; i < 3; i++) {
428	+	COM[i] = COM[i] / mtot;
429	+	}
430	+	}
431	+
432	+	void Thermo::removeCOMdrift() {
433	+	double vdrift[3], aVel[3];
434	+	int vd, j, nobj;
435	+
436	+	nobj = info->integrableObjects.size();
437	+
438	+	// Get the Center of Mass drift velocity.
439	+
440	+	getCOMVel(vdrift);
441	+
442	+	// Corrects for the center of mass drift.
443	+	// sums all the momentum and divides by total mass.
444	+
445	+	for(vd = 0; vd < nobj; vd++){
446	+
447	+	info->integrableObjects[vd]->getVel(aVel);
448	+
449	+	for (j=0; j < 3; j++)
450	+	aVel[j] -= vdrift[j];
451	+
452	+	info->integrableObjects[vd]->setVel( aVel );
453	+	}
454	+	}

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Comparing trunk/OOPSE/libmdtools/Thermo.cpp (file contents): Revision 614 by mmeineke, Tue Jul 15 17:57:04 2003 UTC vs. Revision 1133 by gezelter, Mon Apr 26 14:29:18 2004 UTC

Diff Legend

Comparing trunk/OOPSE/libmdtools/Thermo.cpp (file contents):
Revision 614 by mmeineke, Tue Jul 15 17:57:04 2003 UTC vs.
Revision 1133 by gezelter, Mon Apr 26 14:29:18 2004 UTC