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root/OpenMD/branches/development/src/primitives/RigidBody.cpp

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trunk/src/primitives/RigidBody.cpp (file contents), Revision 334 by tim, Mon Feb 14 17:57:01 2005 UTC vs.
branches/development/src/primitives/RigidBody.cpp (file contents), Revision 1874 by gezelter, Wed May 15 15:09:35 2013 UTC

#	Line 1 | Line 1
1	<	/*
1	>	/*
2		* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3		*
4		* The University of Notre Dame grants you ("Licensee") a
#	Line 6 | Line 6
6		* redistribute this software in source and binary code form, provided
7		* that the following conditions are met:
8		*
9	<	* 1. Acknowledgement of the program authors must be made in any
10	<	*    publication of scientific results based in part on use of the
11	<	*    program.  An acceptable form of acknowledgement is citation of
12	<	*    the article in which the program was described (Matthew
13	<	*    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14	<	*    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15	<	*    Parallel Simulation Engine for Molecular Dynamics,"
16	<	*    J. Comput. Chem. 26, pp. 252-271 (2005))
17	<	*
18	<	* 2. Redistributions of source code must retain the above copyright
9	>	* 1. Redistributions of source code must retain the above copyright
10		*    notice, this list of conditions and the following disclaimer.
11		*
12	<	* 3. Redistributions in binary form must reproduce the above copyright
12	>	* 2. Redistributions in binary form must reproduce the above copyright
13		*    notice, this list of conditions and the following disclaimer in the
14		*    documentation and/or other materials provided with the
15		*    distribution.
#	Line 37 | Line 28
28		* arising out of the use of or inability to use software, even if the
29		* University of Notre Dame has been advised of the possibility of
30		* such damages.
31	+	*
32	+	* SUPPORT OPEN SCIENCE!  If you use OpenMD or its source code in your
33	+	* research, please cite the appropriate papers when you publish your
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).
38	+	* [3]  Sun, Lin & Gezelter, J. Chem. Phys. 128, 234107 (2008).
39	+	* [4]  Kuang & Gezelter,  J. Chem. Phys. 133, 164101 (2010).
40	+	* [5]  Vardeman, Stocker & Gezelter, J. Chem. Theory Comput. 7, 834 (2011).
41		*/
42		#include <algorithm>
43		#include <math.h>
44		#include "primitives/RigidBody.hpp"
45		#include "utils/simError.h"
46	<	namespace oopse {
47	<
48	<	RigidBody::RigidBody() : StuntDouble(otRigidBody, &Snapshot::rigidbodyData), inertiaTensor_(0.0){
49	<
50	<	}
51	<
52	<	void RigidBody::setPrevA(const RotMat3x3d& a) {
46	>	#include "utils/NumericConstant.hpp"
47	>	namespace OpenMD {
48	>
49	>	RigidBody::RigidBody() : StuntDouble(otRigidBody, &Snapshot::rigidbodyData),
50	>	inertiaTensor_(0.0){
51	>	}
52	>
53	>	void RigidBody::setPrevA(const RotMat3x3d& a) {
54		((snapshotMan_->getPrevSnapshot())->*storage_).aMat[localIndex_] = a;
55	<	//((snapshotMan_->getPrevSnapshot())->*storage_).electroFrame[localIndex_] = a.transpose() * sU_;
56	<
57	<	for (int i =0 ; i < atoms_.size(); ++i){
58	<	if (atoms_[i]->isDirectional()) {
59	<	atoms_[i]->setPrevA(a * refOrients_[i]);
58	<	}
55	>
56	>	for (unsigned int i = 0 ; i < atoms_.size(); ++i){
57	>	if (atoms_[i]->isDirectional()) {
58	>	atoms_[i]->setPrevA(refOrients_[i].transpose() * a);
59	>	}
60		}
61	<
62	<	}
63	<
64	<
65	<	void RigidBody::setA(const RotMat3x3d& a) {
61	>
62	>	}
63	>
64	>
65	>	void RigidBody::setA(const RotMat3x3d& a) {
66		((snapshotMan_->getCurrentSnapshot())->*storage_).aMat[localIndex_] = a;
66	–	//((snapshotMan_->getCurrentSnapshot())->*storage_).electroFrame[localIndex_] = a.transpose() * sU_;
67
68	<	for (int i =0 ; i < atoms_.size(); ++i){
69	<	if (atoms_[i]->isDirectional()) {
70	<	atoms_[i]->setA(a * refOrients_[i]);
71	<	}
68	>	for (unsigned int i = 0 ; i < atoms_.size(); ++i){
69	>	if (atoms_[i]->isDirectional()) {
70	>	atoms_[i]->setA(refOrients_[i].transpose() * a);
71	>	}
72		}
73	<	}
74	<
75	<	void RigidBody::setA(const RotMat3x3d& a, int snapshotNo) {
73	>	}
74	>
75	>	void RigidBody::setA(const RotMat3x3d& a, int snapshotNo) {
76		((snapshotMan_->getSnapshot(snapshotNo))->*storage_).aMat[localIndex_] = a;
77	<	//((snapshotMan_->getSnapshot(snapshotNo))->*storage_).electroFrame[localIndex_] = a.transpose() * sU_;
78	<
79	<	for (int i =0 ; i < atoms_.size(); ++i){
80	<	if (atoms_[i]->isDirectional()) {
81	<	atoms_[i]->setA(a * refOrients_[i], snapshotNo);
82	<	}
77	>
78	>	for (unsigned int i = 0 ; i < atoms_.size(); ++i){
79	>	if (atoms_[i]->isDirectional()) {
80	>	atoms_[i]->setA(refOrients_[i].transpose() * a, snapshotNo);
81	>	}
82		}
83	<
84	<	}
85	<
86	<	Mat3x3d RigidBody::getI() {
83	>
84	>	}
85	>
86	>	Mat3x3d RigidBody::getI() {
87		return inertiaTensor_;
88	<	}
89	<
90	<	std::vector<double> RigidBody::getGrad() {
91	<	std::vector<double> grad(6, 0.0);
88	>	}
89	>
90	>	std::vector<RealType> RigidBody::getGrad() {
91	>	std::vector<RealType> grad(6, 0.0);
92		Vector3d force;
93		Vector3d torque;
94		Vector3d myEuler;
95	<	double phi, theta, psi;
96	<	double cphi, sphi, ctheta, stheta;
95	>	RealType phi, theta;
96	>	// RealType psi;
97	>	RealType cphi, sphi, ctheta, stheta;
98		Vector3d ephi;
99		Vector3d etheta;
100		Vector3d epsi;
101	<
101	>
102		force = getFrc();
103		torque =getTrq();
104		myEuler = getA().toEulerAngles();
105	<
105	>
106		phi = myEuler[0];
107		theta = myEuler[1];
108	<	psi = myEuler[2];
109	<
108	>	// psi = myEuler[2];
109	>
110		cphi = cos(phi);
111		sphi = sin(phi);
112		ctheta = cos(theta);
113		stheta = sin(theta);
114	<
114	>
115		// get unit vectors along the phi, theta and psi rotation axes
116	<
116	>
117		ephi[0] = 0.0;
118		ephi[1] = 0.0;
119		ephi[2] = 1.0;
120	<
120	>
121	>	//etheta[0] = -sphi;
122	>	//etheta[1] =  cphi;
123	>	//etheta[2] =  0.0;
124	>
125		etheta[0] = cphi;
126		etheta[1] = sphi;
127	<	etheta[2] = 0.0;
128	<
127	>	etheta[2] =  0.0;
128	>
129		epsi[0] = stheta * cphi;
130		epsi[1] = stheta * sphi;
131		epsi[2] = ctheta;
132	<
132	>
133		//gradient is equal to -force
134		for (int j = 0 ; j<3; j++)
135	<	grad[j] = -force[j];
136	<
135	>	grad[j] = -force[j];
136	>
137		for (int j = 0; j < 3; j++ ) {
138	<
139	<	grad[3] += torque[j]*ephi[j];
140	<	grad[4] += torque[j]*etheta[j];
141	<	grad[5] += torque[j]*epsi[j];
142	<
138	>
139	>	grad[3] += torque[j]*ephi[j];
140	>	grad[4] += torque[j]*etheta[j];
141	>	grad[5] += torque[j]*epsi[j];
142	>
143		}
144
145		return grad;
146	<	}
147	<
148	<	void RigidBody::accept(BaseVisitor* v) {
146	>	}
147	>
148	>	void RigidBody::accept(BaseVisitor* v) {
149		v->visit(this);
150	<	}
150	>	}
151
152	<	/**@todo need modification */
153	<	void  RigidBody::calcRefCoords() {
154	<	double mtmp;
152	>	/**@todo need modification */
153	>	void  RigidBody::calcRefCoords() {
154	>	RealType mtmp;
155		Vector3d refCOM(0.0);
156		mass_ = 0.0;
157		for (std::size_t i = 0; i < atoms_.size(); ++i) {
158	<	mtmp = atoms_[i]->getMass();
159	<	mass_ += mtmp;
160	<	refCOM += refCoords_[i]*mtmp;
158	>	mtmp = atoms_[i]->getMass();
159	>	mass_ += mtmp;
160	>	refCOM += refCoords_[i]*mtmp;
161		}
162		refCOM /= mass_;
163	<
163	>
164		// Next, move the origin of the reference coordinate system to the COM:
165		for (std::size_t i = 0; i < atoms_.size(); ++i) {
166	<	refCoords_[i] -= refCOM;
166	>	refCoords_[i] -= refCOM;
167		}
168
169	<	// Moment of Inertia calculation
170	<	Mat3x3d Itmp(0.0);
167	<
169	>	// Moment of Inertia calculation
170	>	Mat3x3d Itmp(0.0);
171		for (std::size_t i = 0; i < atoms_.size(); i++) {
172	<	mtmp = atoms_[i]->getMass();
173	<	Itmp -= outProduct(refCoords_[i], refCoords_[i]) * mtmp;
174	<	double r2 = refCoords_[i].lengthSquare();
175	<	Itmp(0, 0) += mtmp * r2;
176	<	Itmp(1, 1) += mtmp * r2;
177	<	Itmp(2, 2) += mtmp * r2;
172	>	Mat3x3d IAtom(0.0);
173	>	mtmp = atoms_[i]->getMass();
174	>	IAtom -= outProduct(refCoords_[i], refCoords_[i]) * mtmp;
175	>	RealType r2 = refCoords_[i].lengthSquare();
176	>	IAtom(0, 0) += mtmp * r2;
177	>	IAtom(1, 1) += mtmp * r2;
178	>	IAtom(2, 2) += mtmp * r2;
179	>	Itmp += IAtom;
180	>
181	>	//project the inertial moment of directional atoms into this rigid body
182	>	if (atoms_[i]->isDirectional()) {
183	>	Itmp += refOrients_[i].transpose() * atoms_[i]->getI() * refOrients_[i];
184	>	}
185		}
186
187	<	//project the inertial moment of directional atoms into this rigid body
178	<	for (std::size_t i = 0; i < atoms_.size(); i++) {
179	<	if (atoms_[i]->isDirectional()) {
180	<	RectMatrix<double, 3, 3> Iproject = refOrients_[i].transpose() * atoms_[i]->getI();
181	<	Itmp(0, 0) += Iproject(0, 0);
182	<	Itmp(1, 1) += Iproject(1, 1);
183	<	Itmp(2, 2) += Iproject(2, 2);
184	<	}
185	<	}
187	>	//    std::cout << Itmp << std::endl;
188
189		//diagonalize
190		Vector3d evals;
#	Line 195 | Line 197 | void  RigidBody::calcRefCoords() {
197
198		int nLinearAxis = 0;
199		for (int i = 0; i < 3; i++) {
200	<	if (fabs(evals[i]) < oopse::epsilon) {
201	<	linear_ = true;
202	<	linearAxis_ = i;
203	<	++ nLinearAxis;
204	<	}
200	>	if (fabs(evals[i]) < OpenMD::epsilon) {
201	>	linear_ = true;
202	>	linearAxis_ = i;
203	>	++ nLinearAxis;
204	>	}
205		}
206
207		if (nLinearAxis > 1) {
208	<	sprintf( painCave.errMsg,
209	<	"RigidBody error.\n"
210	<	"\tOOPSE found more than one axis in this rigid body with a vanishing \n"
211	<	"\tmoment of inertia.  This can happen in one of three ways:\n"
212	<	"\t 1) Only one atom was specified, or \n"
213	<	"\t 2) All atoms were specified at the same location, or\n"
214	<	"\t 3) The programmers did something stupid.\n"
215	<	"\tIt is silly to use a rigid body to describe this situation.  Be smarter.\n"
216	<	);
217	<	painCave.isFatal = 1;
218	<	simError();
208	>	sprintf( painCave.errMsg,
209	>	"RigidBody error.\n"
210	>	"\tOpenMD found more than one axis in this rigid body with a vanishing \n"
211	>	"\tmoment of inertia.  This can happen in one of three ways:\n"
212	>	"\t 1) Only one atom was specified, or \n"
213	>	"\t 2) All atoms were specified at the same location, or\n"
214	>	"\t 3) The programmers did something stupid.\n"
215	>	"\tIt is silly to use a rigid body to describe this situation.  Be smarter.\n"
216	>	);
217	>	painCave.isFatal = 1;
218	>	simError();
219		}
220
221	<	}
221	>	}
222
223	<	void  RigidBody::calcForcesAndTorques() {
223	>	void  RigidBody::calcForcesAndTorques() {
224		Vector3d afrc;
225		Vector3d atrq;
226		Vector3d apos;
227		Vector3d rpos;
228		Vector3d frc(0.0);
229		Vector3d trq(0.0);
230	+	Vector3d ef(0.0);
231		Vector3d pos = this->getPos();
232	<	for (int i = 0; i < atoms_.size(); i++) {
232	>	AtomType* atype;
233	>	int eCount = 0;
234	>
235	>	int sl = ((snapshotMan_->getCurrentSnapshot())->*storage_).getStorageLayout();
236	>
237	>	for (unsigned int i = 0; i < atoms_.size(); i++) {
238
239	<	afrc = atoms_[i]->getFrc();
240	<	apos = atoms_[i]->getPos();
241	<	rpos = apos - pos;
239	>	atype = atoms_[i]->getAtomType();
240	>
241	>	afrc = atoms_[i]->getFrc();
242	>	apos = atoms_[i]->getPos();
243	>	rpos = apos - pos;
244
245	<	frc += afrc;
245	>	frc += afrc;
246
247	<	trq[0] += rpos[1]*afrc[2] - rpos[2]*afrc[1];
248	<	trq[1] += rpos[2]*afrc[0] - rpos[0]*afrc[2];
249	<	trq[2] += rpos[0]*afrc[1] - rpos[1]*afrc[0];
247	>	trq[0] += rpos[1]*afrc[2] - rpos[2]*afrc[1];
248	>	trq[1] += rpos[2]*afrc[0] - rpos[0]*afrc[2];
249	>	trq[2] += rpos[0]*afrc[1] - rpos[1]*afrc[0];
250
251	<	// If the atom has a torque associated with it, then we also need to
252	<	// migrate the torques onto the center of mass:
251	>	// If the atom has a torque associated with it, then we also need to
252	>	// migrate the torques onto the center of mass:
253
254	<	if (atoms_[i]->isDirectional()) {
255	<	atrq = atoms_[i]->getTrq();
256	<	trq += atrq;
257	<	}
254	>	if (atoms_[i]->isDirectional()) {
255	>	atrq = atoms_[i]->getTrq();
256	>	trq += atrq;
257	>	}
258	>
259	>	if ((sl & DataStorage::dslElectricField) && (atype->isElectrostatic())) {
260	>	ef += atoms_[i]->getElectricField();
261	>	eCount++;
262	>	}
263	>	}
264	>	addFrc(frc);
265	>	addTrq(trq);
266	>
267	>	if (sl & DataStorage::dslElectricField)  {
268	>	ef /= eCount;
269	>	setElectricField(ef);
270	>	}
271	>
272	>	}
273	>
274	>	Mat3x3d RigidBody::calcForcesAndTorquesAndVirial() {
275	>	Vector3d afrc;
276	>	Vector3d atrq;
277	>	Vector3d apos;
278	>	Vector3d rpos;
279	>	Vector3d dfrc;
280	>	Vector3d frc(0.0);
281	>	Vector3d trq(0.0);
282	>	Vector3d ef(0.0);
283	>	AtomType* atype;
284	>	int eCount = 0;
285	>
286	>	Vector3d pos = this->getPos();
287	>	Mat3x3d tau_(0.0);
288	>
289	>	int sl = ((snapshotMan_->getCurrentSnapshot())->*storage_).getStorageLayout();
290	>
291	>	for (unsigned int i = 0; i < atoms_.size(); i++) {
292	>
293	>	atype = atoms_[i]->getAtomType();
294	>
295	>	afrc = atoms_[i]->getFrc();
296	>	apos = atoms_[i]->getPos();
297	>	rpos = apos - pos;
298
299	+	frc += afrc;
300	+
301	+	trq[0] += rpos[1]*afrc[2] - rpos[2]*afrc[1];
302	+	trq[1] += rpos[2]*afrc[0] - rpos[0]*afrc[2];
303	+	trq[2] += rpos[0]*afrc[1] - rpos[1]*afrc[0];
304	+
305	+	// If the atom has a torque associated with it, then we also need to
306	+	// migrate the torques onto the center of mass:
307	+
308	+	if (atoms_[i]->isDirectional()) {
309	+	atrq = atoms_[i]->getTrq();
310	+	trq += atrq;
311	+	}
312	+
313	+	if ((sl & DataStorage::dslElectricField) && (atype->isElectrostatic())) {
314	+	ef += atoms_[i]->getElectricField();
315	+	eCount++;
316	+	}
317	+
318	+	tau_(0,0) -= rpos[0]*afrc[0];
319	+	tau_(0,1) -= rpos[0]*afrc[1];
320	+	tau_(0,2) -= rpos[0]*afrc[2];
321	+	tau_(1,0) -= rpos[1]*afrc[0];
322	+	tau_(1,1) -= rpos[1]*afrc[1];
323	+	tau_(1,2) -= rpos[1]*afrc[2];
324	+	tau_(2,0) -= rpos[2]*afrc[0];
325	+	tau_(2,1) -= rpos[2]*afrc[1];
326	+	tau_(2,2) -= rpos[2]*afrc[2];
327	+
328		}
329	<
330	<	setFrc(frc);
252	<	setTrq(trq);
253	<
254	<	}
329	>	addFrc(frc);
330	>	addTrq(trq);
331
332	<	void  RigidBody::updateAtoms() {
332	>	if (sl & DataStorage::dslElectricField) {
333	>	ef /= eCount;
334	>	setElectricField(ef);
335	>	}
336	>
337	>	return tau_;
338	>	}
339	>
340	>	void  RigidBody::updateAtoms() {
341		unsigned int i;
342		Vector3d ref;
343		Vector3d apos;
#	Line 263 | Line 347 | void  RigidBody::updateAtoms() {
347
348		for (i = 0; i < atoms_.size(); i++) {
349
350	<	ref = body2Lab(refCoords_[i]);
350	>	ref = body2Lab(refCoords_[i]);
351
352	<	apos = pos + ref;
352	>	apos = pos + ref;
353
354	<	atoms_[i]->setPos(apos);
354	>	atoms_[i]->setPos(apos);
355
356	<	if (atoms_[i]->isDirectional()) {
356	>	if (atoms_[i]->isDirectional()) {
357
358	<	dAtom = (DirectionalAtom *) atoms_[i];
359	<	dAtom->setA(a * refOrients_[i]);
360	<	//dAtom->rotateBy( A );
277	<	}
358	>	dAtom = dynamic_cast<DirectionalAtom *>(atoms_[i]);
359	>	dAtom->setA(refOrients_[i].transpose() * a);
360	>	}
361
362		}
363
364	<	}
364	>	}
365
366
367	<	void  RigidBody::updateAtoms(int frame) {
367	>	void  RigidBody::updateAtoms(int frame) {
368		unsigned int i;
369		Vector3d ref;
370		Vector3d apos;
#	Line 291 | Line 374 | void  RigidBody::updateAtoms(int frame) {
374
375		for (i = 0; i < atoms_.size(); i++) {
376
377	<	ref = body2Lab(refCoords_[i], frame);
377	>	ref = body2Lab(refCoords_[i], frame);
378
379	<	apos = pos + ref;
379	>	apos = pos + ref;
380
381	<	atoms_[i]->setPos(apos, frame);
381	>	atoms_[i]->setPos(apos, frame);
382
383	<	if (atoms_[i]->isDirectional()) {
383	>	if (atoms_[i]->isDirectional()) {
384
385	<	dAtom = (DirectionalAtom *) atoms_[i];
386	<	dAtom->setA(a * refOrients_[i], frame);
387	<	}
385	>	dAtom = dynamic_cast<DirectionalAtom *>(atoms_[i]);
386	>	dAtom->setA(refOrients_[i].transpose() * a, frame);
387	>	}
388
389		}
390
391	<	}
391	>	}
392
393	<	void RigidBody::updateAtomVel() {
393	>	void RigidBody::updateAtomVel() {
394		Mat3x3d skewMat;;
395
396		Vector3d ji = getJ();
#	Line 330 | Line 413 | void RigidBody::updateAtomVel() {
413
414
415		Vector3d velRot;
416	<	for (int i =0 ; i < refCoords_.size(); ++i) {
417	<	atoms_[i]->setVel(rbVel + mat * refCoords_[i]);
416	>	for (unsigned int i = 0 ; i < refCoords_.size(); ++i) {
417	>	atoms_[i]->setVel(rbVel + mat * refCoords_[i]);
418		}
419
420	<	}
420	>	}
421
422	<	void RigidBody::updateAtomVel(int frame) {
422	>	void RigidBody::updateAtomVel(int frame) {
423		Mat3x3d skewMat;;
424
425		Vector3d ji = getJ(frame);
#	Line 359 | Line 442 | void RigidBody::updateAtomVel(int frame) {
442
443
444		Vector3d velRot;
445	<	for (int i =0 ; i < refCoords_.size(); ++i) {
446	<	atoms_[i]->setVel(rbVel + mat * refCoords_[i], frame);
445	>	for (unsigned int i = 0 ; i < refCoords_.size(); ++i) {
446	>	atoms_[i]->setVel(rbVel + mat * refCoords_[i], frame);
447		}
448
449	<	}
449	>	}
450
451
452
453	<	bool RigidBody::getAtomPos(Vector3d& pos, unsigned int index) {
453	>	bool RigidBody::getAtomPos(Vector3d& pos, unsigned int index) {
454		if (index < atoms_.size()) {
455
456	<	Vector3d ref = body2Lab(refCoords_[index]);
457	<	pos = getPos() + ref;
458	<	return true;
456	>	Vector3d ref = body2Lab(refCoords_[index]);
457	>	pos = getPos() + ref;
458	>	return true;
459		} else {
460	<	std::cerr << index << " is an invalid index, current rigid body contains "
461	<	<< atoms_.size() << "atoms" << std::endl;
462	<	return false;
460	>	std::cerr << index << " is an invalid index, current rigid body contains "
461	>	<< atoms_.size() << "atoms" << std::endl;
462	>	return false;
463		}
464	<	}
464	>	}
465
466	<	bool RigidBody::getAtomPos(Vector3d& pos, Atom* atom) {
466	>	bool RigidBody::getAtomPos(Vector3d& pos, Atom* atom) {
467		std::vector<Atom*>::iterator i;
468		i = std::find(atoms_.begin(), atoms_.end(), atom);
469		if (i != atoms_.end()) {
470	<	//RigidBody class makes sure refCoords_ and atoms_ match each other
471	<	Vector3d ref = body2Lab(refCoords_[i - atoms_.begin()]);
472	<	pos = getPos() + ref;
473	<	return true;
470	>	//RigidBody class makes sure refCoords_ and atoms_ match each other
471	>	Vector3d ref = body2Lab(refCoords_[i - atoms_.begin()]);
472	>	pos = getPos() + ref;
473	>	return true;
474		} else {
475	<	std::cerr << "Atom " << atom->getGlobalIndex()
476	<	<<" does not belong to Rigid body "<< getGlobalIndex() << std::endl;
477	<	return false;
475	>	std::cerr << "Atom " << atom->getGlobalIndex()
476	>	<<" does not belong to Rigid body "<< getGlobalIndex() << std::endl;
477	>	return false;
478		}
479	<	}
480	<	bool RigidBody::getAtomVel(Vector3d& vel, unsigned int index) {
479	>	}
480	>	bool RigidBody::getAtomVel(Vector3d& vel, unsigned int index) {
481
482		//velRot = $(A\cdot skew(I^{-1}j))^{T}refCoor$
483
484		if (index < atoms_.size()) {
485
486	<	Vector3d velRot;
487	<	Mat3x3d skewMat;;
488	<	Vector3d ref = refCoords_[index];
489	<	Vector3d ji = getJ();
490	<	Mat3x3d I =  getI();
486	>	Vector3d velRot;
487	>	Mat3x3d skewMat;;
488	>	Vector3d ref = refCoords_[index];
489	>	Vector3d ji = getJ();
490	>	Mat3x3d I =  getI();
491
492	<	skewMat(0, 0) =0;
493	<	skewMat(0, 1) = ji[2] /I(2, 2);
494	<	skewMat(0, 2) = -ji[1] /I(1, 1);
492	>	skewMat(0, 0) =0;
493	>	skewMat(0, 1) = ji[2] /I(2, 2);
494	>	skewMat(0, 2) = -ji[1] /I(1, 1);
495
496	<	skewMat(1, 0) = -ji[2] /I(2, 2);
497	<	skewMat(1, 1) = 0;
498	<	skewMat(1, 2) = ji[0]/I(0, 0);
496	>	skewMat(1, 0) = -ji[2] /I(2, 2);
497	>	skewMat(1, 1) = 0;
498	>	skewMat(1, 2) = ji[0]/I(0, 0);
499
500	<	skewMat(2, 0) =ji[1] /I(1, 1);
501	<	skewMat(2, 1) = -ji[0]/I(0, 0);
502	<	skewMat(2, 2) = 0;
500	>	skewMat(2, 0) =ji[1] /I(1, 1);
501	>	skewMat(2, 1) = -ji[0]/I(0, 0);
502	>	skewMat(2, 2) = 0;
503
504	<	velRot = (getA() * skewMat).transpose() * ref;
504	>	velRot = (getA() * skewMat).transpose() * ref;
505
506	<	vel =getVel() + velRot;
507	<	return true;
506	>	vel =getVel() + velRot;
507	>	return true;
508
509		} else {
510	<	std::cerr << index << " is an invalid index, current rigid body contains "
511	<	<< atoms_.size() << "atoms" << std::endl;
512	<	return false;
510	>	std::cerr << index << " is an invalid index, current rigid body contains "
511	>	<< atoms_.size() << "atoms" << std::endl;
512	>	return false;
513		}
514	<	}
514	>	}
515
516	<	bool RigidBody::getAtomVel(Vector3d& vel, Atom* atom) {
516	>	bool RigidBody::getAtomVel(Vector3d& vel, Atom* atom) {
517
518		std::vector<Atom*>::iterator i;
519		i = std::find(atoms_.begin(), atoms_.end(), atom);
520		if (i != atoms_.end()) {
521	<	return getAtomVel(vel, i - atoms_.begin());
522	<	} else {
523	<	std::cerr << "Atom " << atom->getGlobalIndex()
524	<	<<" does not belong to Rigid body "<< getGlobalIndex() << std::endl;
525	<	return false;
521	>	return getAtomVel(vel, i - atoms_.begin());
522	>	} else {
523	>	std::cerr << "Atom " << atom->getGlobalIndex()
524	>	<<" does not belong to Rigid body "<< getGlobalIndex() << std::endl;
525	>	return false;
526		}
527	<	}
527	>	}
528
529	<	bool RigidBody::getAtomRefCoor(Vector3d& coor, unsigned int index) {
529	>	bool RigidBody::getAtomRefCoor(Vector3d& coor, unsigned int index) {
530		if (index < atoms_.size()) {
531
532	<	coor = refCoords_[index];
533	<	return true;
532	>	coor = refCoords_[index];
533	>	return true;
534		} else {
535	<	std::cerr << index << " is an invalid index, current rigid body contains "
536	<	<< atoms_.size() << "atoms" << std::endl;
537	<	return false;
535	>	std::cerr << index << " is an invalid index, current rigid body contains "
536	>	<< atoms_.size() << "atoms" << std::endl;
537	>	return false;
538		}
539
540	<	}
540	>	}
541
542	<	bool RigidBody::getAtomRefCoor(Vector3d& coor, Atom* atom) {
542	>	bool RigidBody::getAtomRefCoor(Vector3d& coor, Atom* atom) {
543		std::vector<Atom*>::iterator i;
544		i = std::find(atoms_.begin(), atoms_.end(), atom);
545		if (i != atoms_.end()) {
546	<	//RigidBody class makes sure refCoords_ and atoms_ match each other
547	<	coor = refCoords_[i - atoms_.begin()];
548	<	return true;
546	>	//RigidBody class makes sure refCoords_ and atoms_ match each other
547	>	coor = refCoords_[i - atoms_.begin()];
548	>	return true;
549		} else {
550	<	std::cerr << "Atom " << atom->getGlobalIndex()
551	<	<<" does not belong to Rigid body "<< getGlobalIndex() << std::endl;
552	<	return false;
550	>	std::cerr << "Atom " << atom->getGlobalIndex()
551	>	<<" does not belong to Rigid body "<< getGlobalIndex() << std::endl;
552	>	return false;
553		}
554
555	<	}
555	>	}
556
557
558	<	void RigidBody::addAtom(Atom* at, AtomStamp* ats) {
558	>	void RigidBody::addAtom(Atom* at, AtomStamp* ats) {
559
560	<	Vector3d coords;
561	<	Vector3d euler;
560	>	Vector3d coords;
561	>	Vector3d euler;
562
563
564	<	atoms_.push_back(at);
564	>	atoms_.push_back(at);
565
566	<	if( !ats->havePosition() ){
567	<	sprintf( painCave.errMsg,
568	<	"RigidBody error.\n"
569	<	"\tAtom %s does not have a position specified.\n"
570	<	"\tThis means RigidBody cannot set up reference coordinates.\n",
571	<	ats->getType() );
572	<	painCave.isFatal = 1;
573	<	simError();
574	<	}
566	>	if( !ats->havePosition() ){
567	>	sprintf( painCave.errMsg,
568	>	"RigidBody error.\n"
569	>	"\tAtom %s does not have a position specified.\n"
570	>	"\tThis means RigidBody cannot set up reference coordinates.\n",
571	>	ats->getType().c_str() );
572	>	painCave.isFatal = 1;
573	>	simError();
574	>	}
575
576	<	coords[0] = ats->getPosX();
577	<	coords[1] = ats->getPosY();
578	<	coords[2] = ats->getPosZ();
576	>	coords[0] = ats->getPosX();
577	>	coords[1] = ats->getPosY();
578	>	coords[2] = ats->getPosZ();
579
580	<	refCoords_.push_back(coords);
580	>	refCoords_.push_back(coords);
581
582	<	RotMat3x3d identMat = RotMat3x3d::identity();
582	>	RotMat3x3d identMat = RotMat3x3d::identity();
583
584	<	if (at->isDirectional()) {
584	>	if (at->isDirectional()) {
585
586	<	if( !ats->haveOrientation() ){
587	<	sprintf( painCave.errMsg,
588	<	"RigidBody error.\n"
589	<	"\tAtom %s does not have an orientation specified.\n"
590	<	"\tThis means RigidBody cannot set up reference orientations.\n",
591	<	ats->getType() );
592	<	painCave.isFatal = 1;
593	<	simError();
594	<	}
586	>	if( !ats->haveOrientation() ){
587	>	sprintf( painCave.errMsg,
588	>	"RigidBody error.\n"
589	>	"\tAtom %s does not have an orientation specified.\n"
590	>	"\tThis means RigidBody cannot set up reference orientations.\n",
591	>	ats->getType().c_str() );
592	>	painCave.isFatal = 1;
593	>	simError();
594	>	}
595
596	<	euler[0] = ats->getEulerPhi();
597	<	euler[1] = ats->getEulerTheta();
598	<	euler[2] = ats->getEulerPsi();
596	>	euler[0] = ats->getEulerPhi() * NumericConstant::PI /180.0;
597	>	euler[1] = ats->getEulerTheta() * NumericConstant::PI /180.0;
598	>	euler[2] = ats->getEulerPsi() * NumericConstant::PI /180.0;
599
600	<	RotMat3x3d Atmp(euler);
601	<	refOrients_.push_back(Atmp);
600	>	RotMat3x3d Atmp(euler);
601	>	refOrients_.push_back(Atmp);
602
603	<	}else {
604	<	refOrients_.push_back(identMat);
605	<	}
603	>	}else {
604	>	refOrients_.push_back(identMat);
605	>	}
606
607
608	<	}
608	>	}
609
610		}
611

Comparing:
trunk/src/primitives/RigidBody.cpp (property svn:keywords), Revision 334 by tim, Mon Feb 14 17:57:01 2005 UTC vs.
branches/development/src/primitives/RigidBody.cpp (property svn:keywords), Revision 1874 by gezelter, Wed May 15 15:09:35 2013 UTC

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