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root/group/branches/new-templateless/OOPSE/libmdtools/NPTf.cpp
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Comparing:
trunk/OOPSE/libmdtools/NPTf.cpp (file contents), Revision 577 by gezelter, Wed Jul 9 01:41:11 2003 UTC vs.
branches/new-templateless/OOPSE/libmdtools/NPTf.cpp (file contents), Revision 851 by mmeineke, Wed Nov 5 19:18:17 2003 UTC

# Line 1 | Line 1
1 + #include <stdlib.h>
2 + #include <math.h>
3 + #include <string.h>
4 +
5   #include "Atom.hpp"
6   #include "SRI.hpp"
7   #include "AbstractClasses.hpp"
# Line 6 | Line 10
10   #include "Thermo.hpp"
11   #include "ReadWrite.hpp"
12   #include "Integrator.hpp"
13 < #include "simError.h"
13 > #include "simError.h"
14  
15 + #ifdef IS_MPI
16 + #include "mpiSimulation.hpp"
17 + #endif
18  
19 < // Basic isotropic thermostating and barostating via the Melchionna
19 > // Basic non-isotropic thermostating and barostating via the Melchionna
20   // modification of the Hoover algorithm:
21   //
22   //    Melchionna, S., Ciccotti, G., and Holian, B. L., 1993,
23 < //       Molec. Phys., 78, 533.
23 > //       Molec. Phys., 78, 533.
24   //
25   //           and
26 < //
26 > //
27   //    Hoover, W. G., 1986, Phys. Rev. A, 34, 2499.
28  
29   NPTf::NPTf ( SimInfo *theInfo, ForceFields* the_ff):
30 <  Integrator( theInfo, the_ff )
30 >  NPT( theInfo, the_ff )
31   {
32 <  int i;
33 <  chi = 0.0;
34 <  for(i = 0; i < 9; i++) eta[i] = 0.0;
28 <  have_tau_thermostat = 0;
29 <  have_tau_barostat = 0;
30 <  have_target_temp = 0;
31 <  have_target_pressure = 0;
32 < }
32 >  GenericData* data;
33 >  double *etaArray;
34 >  int i,j;
35  
36 < void NPTf::moveA() {
37 <  
36 <  int i,j,k;
37 <  int atomIndex, aMatIndex;
38 <  DirectionalAtom* dAtom;
39 <  double Tb[3];
40 <  double ji[3];
41 <  double rj[3];
42 <  double instaTemp, instaPress, instaVol;
43 <  double tt2, tb2;
44 <  double angle;
45 <  double press[9];
46 <  const double p_convert = 1.63882576e8;
36 >  for(i = 0; i < 3; i++){
37 >    for (j = 0; j < 3; j++){
38  
39 <  tt2 = tauThermostat * tauThermostat;
40 <  tb2 = tauBarostat * tauBarostat;
39 >      eta[i][j] = 0.0;
40 >      oldEta[i][j] = 0.0;
41 >    }
42 >  }
43  
44 <  instaTemp = tStats->getTemperature();
45 <  tStats->getPressureTensor(press);
46 <
54 <  for (i=0; i < 9; i++) press[i] *= p_convert;
55 <
56 <  instaVol = tStats->getVolume();
57 <  
58 <  // first evolve chi a half step
59 <  
60 <  chi += dt2 * ( instaTemp / targetTemp - 1.0) / tt2;
61 <  
62 <  eta[0] += dt2 * instaVol * (press[0] - targetPressure) / (NkBT*tb2);
63 <  eta[1] += dt2 * instaVol * press[1] / (NkBT*tb2);
64 <  eta[2] += dt2 * instaVol * press[2] / (NkBT*tb2);
65 <  eta[3] += dt2 * instaVol * press[3] / (NkBT*tb2);
66 <  eta[4] += dt2 * instaVol * (press[4] - targetPressure) / (NkBT*tb2);
67 <  eta[5] += dt2 * instaVol * press[5] / (NkBT*tb2);
68 <  eta[6] += dt2 * instaVol * press[6] / (NkBT*tb2);
69 <  eta[7] += dt2 * instaVol * press[7] / (NkBT*tb2);
70 <  eta[8] += dt2 * instaVol * (press[8] - targetPressure) / (NkBT*tb2);
71 <  
72 <  for( i=0; i<nAtoms; i++ ){
73 <    atomIndex = i * 3;
74 <    aMatIndex = i * 9;
44 >  // retrieve eta array from simInfo if it exists
45 >  data = info->getProperty(ETAVALUE_ID);
46 >  if(data != NULL){
47      
48 <    // velocity half step
48 >    int test = data->getDarray(etaArray);
49      
50 <    vx = vel[atomIndex];
51 <    vy = vel[atomIndex+1];
52 <    vz = vel[atomIndex+2];
53 <    
54 <    scx = (chi + eta[0])*vx + eta[1]*vy + eta[2]*vz;
55 <    scy = eta[3]*vx + (chi + eta[4])*vy + eta[5]*vz;
56 <    scz = eta[6]*vx + eta[7]*vy + (chi + eta[8])*vz;
57 <    
58 <    vx += dt2 * ((frc[atomIndex]  /atoms[i]->getMass())*eConvert - scx);
59 <    vy += dt2 * ((frc[atomIndex+1]/atoms[i]->getMass())*eConvert - scy);
60 <    vz += dt2 * ((frc[atomIndex+2]/atoms[i]->getMass())*eConvert - scz);
50 >    if( test == 9 ){
51 >      
52 >      for(i = 0; i < 3; i++){
53 >        for (j = 0; j < 3; j++){
54 >          eta[i][j] = etaArray[3*i+j];
55 >          oldEta[i][j] = eta[i][j];
56 >        }
57 >      }    
58 >      delete[] etaArray;
59 >    }
60 >    else
61 >      std::cerr << "NPTf error: etaArray is not length 9 (actual = " << test
62 >                << ").\n"
63 >                << "            Simulation wil proceed with eta = 0;\n";
64 >  }
65 > }
66  
67 <    vel[atomIndex] = vx;
91 <    vel[atomIndex+1] = vy;
92 <    vel[atomIndex+2] = vz;
67 > NPTf::~NPTf() {
68  
69 <    // position whole step    
69 >  // empty for now
70 > }
71  
72 <    rj[0] = pos[atomIndex];
97 <    rj[1] = pos[atomIndex+1];
98 <    rj[2] = pos[atomIndex+2];
72 > void NPTf::resetIntegrator() {
73  
74 <    info->wrapVector(rj);
74 >  int i, j;
75  
76 <    scx = eta[0]*rj[0] + eta[1]*rj[1] + eta[2]*rj[2];
77 <    scy = eta[3]*rj[0] + eta[4]*rj[1] + eta[5]*rj[2];
78 <    scz = eta[6]*rj[0] + eta[7]*rj[1] + eta[8]*rj[2];
76 >  for(i = 0; i < 3; i++)
77 >    for (j = 0; j < 3; j++)
78 >      eta[i][j] = 0.0;
79  
80 <    pos[atomIndex] += dt * (vel[atomIndex] + scx);
81 <    pos[atomIndex+1] += dt * (vel[atomIndex+1] + scy);
108 <    pos[atomIndex+2] += dt * (vel[atomIndex+2] + scz);
109 <  
110 <    if( atoms[i]->isDirectional() ){
80 >  NPT::resetIntegrator();
81 > }
82  
83 <      dAtom = (DirectionalAtom *)atoms[i];
113 <          
114 <      // get and convert the torque to body frame
115 <      
116 <      Tb[0] = dAtom->getTx();
117 <      Tb[1] = dAtom->getTy();
118 <      Tb[2] = dAtom->getTz();
119 <      
120 <      dAtom->lab2Body( Tb );
121 <      
122 <      // get the angular momentum, and propagate a half step
83 > void NPTf::evolveEtaA() {
84  
85 <      ji[0] = dAtom->getJx();
86 <      ji[1] = dAtom->getJy();
87 <      ji[2] = dAtom->getJz();
88 <      
89 <      ji[0] += dt2 * (Tb[0] * eConvert - ji[0]*chi);
90 <      ji[1] += dt2 * (Tb[1] * eConvert - ji[1]*chi);
91 <      ji[2] += dt2 * (Tb[2] * eConvert - ji[2]*chi);
92 <      
93 <      // use the angular velocities to propagate the rotation matrix a
133 <      // full time step
134 <      
135 <      // rotate about the x-axis      
136 <      angle = dt2 * ji[0] / dAtom->getIxx();
137 <      this->rotate( 1, 2, angle, ji, &Amat[aMatIndex] );
138 <      
139 <      // rotate about the y-axis
140 <      angle = dt2 * ji[1] / dAtom->getIyy();
141 <      this->rotate( 2, 0, angle, ji, &Amat[aMatIndex] );
142 <      
143 <      // rotate about the z-axis
144 <      angle = dt * ji[2] / dAtom->getIzz();
145 <      this->rotate( 0, 1, angle, ji, &Amat[aMatIndex] );
146 <      
147 <      // rotate about the y-axis
148 <      angle = dt2 * ji[1] / dAtom->getIyy();
149 <      this->rotate( 2, 0, angle, ji, &Amat[aMatIndex] );
150 <      
151 <       // rotate about the x-axis
152 <      angle = dt2 * ji[0] / dAtom->getIxx();
153 <      this->rotate( 1, 2, angle, ji, &Amat[aMatIndex] );
154 <      
155 <      dAtom->setJx( ji[0] );
156 <      dAtom->setJy( ji[1] );
157 <      dAtom->setJz( ji[2] );
85 >  int i, j;
86 >
87 >  for(i = 0; i < 3; i ++){
88 >    for(j = 0; j < 3; j++){
89 >      if( i == j)
90 >        eta[i][j] += dt2 *  instaVol *
91 >          (press[i][j] - targetPressure/p_convert) / (NkBT*tb2);
92 >      else
93 >        eta[i][j] += dt2 * instaVol * press[i][j] / (NkBT*tb2);
94      }
159    
95    }
96  
97 <  // Scale the box after all the positions have been moved:
98 <  
97 >  for(i = 0; i < 3; i++)
98 >    for (j = 0; j < 3; j++)
99 >      oldEta[i][j] = eta[i][j];
100 > }
101  
102 + void NPTf::evolveEtaB() {
103  
104 <  // Use a taylor expansion for eta products
167 <  
168 <  info->getBoxM(hm);
169 <  
104 >  int i,j;
105  
106 +  for(i = 0; i < 3; i++)
107 +    for (j = 0; j < 3; j++)
108 +      prevEta[i][j] = eta[i][j];
109  
110 +  for(i = 0; i < 3; i ++){
111 +    for(j = 0; j < 3; j++){
112 +      if( i == j) {
113 +        eta[i][j] = oldEta[i][j] + dt2 *  instaVol *
114 +          (press[i][j] - targetPressure/p_convert) / (NkBT*tb2);
115 +      } else {
116 +        eta[i][j] = oldEta[i][j] + dt2 * instaVol * press[i][j] / (NkBT*tb2);
117 +      }
118 +    }
119 +  }
120 + }
121  
122 + void NPTf::getVelScaleA(double sc[3], double vel[3]) {
123 +  int i,j;
124 +  double vScale[3][3];
125  
126 +  for (i = 0; i < 3; i++ ) {
127 +    for (j = 0; j < 3; j++ ) {
128 +      vScale[i][j] = eta[i][j];
129  
130 <   info->scaleBox(exp(dt*eta));
130 >      if (i == j) {
131 >        vScale[i][j] += chi;
132 >      }
133 >    }
134 >  }
135  
136 <
136 >  info->matVecMul3( vScale, vel, sc );
137   }
138  
139 < void NPTi::moveB( void ){
140 <  int i,j,k;
141 <  int atomIndex;
142 <  DirectionalAtom* dAtom;
184 <  double Tb[3];
185 <  double ji[3];
186 <  double instaTemp, instaPress, instaVol;
187 <  double tt2, tb2;
188 <  
189 <  tt2 = tauThermostat * tauThermostat;
190 <  tb2 = tauBarostat * tauBarostat;
139 > void NPTf::getVelScaleB(double sc[3], int index ){
140 >  int i,j;
141 >  double myVel[3];
142 >  double vScale[3][3];
143  
144 <  instaTemp = tStats->getTemperature();
193 <  instaPress = tStats->getPressure();
194 <  instaVol = tStats->getVolume();
144 > //   std::cerr << "velScaleB chi = " << chi << "\n";
145  
146 <  chi += dt2 * ( instaTemp / targetTemp - 1.0) / tt2;
147 <  eta += dt2 * ( instaVol * (instaPress - targetPressure) / (NkBT*tb2));
148 <  
149 <  for( i=0; i<nAtoms; i++ ){
150 <    atomIndex = i * 3;
151 <    
152 <    // velocity half step
203 <    for( j=atomIndex; j<(atomIndex+3); j++ )
204 <    for( j=atomIndex; j<(atomIndex+3); j++ )
205 <      vel[j] += dt2 * ((frc[j]/atoms[i]->getMass())*eConvert
206 <                       - vel[j]*(chi+eta));
207 <    
208 <    if( atoms[i]->isDirectional() ){
209 <      
210 <      dAtom = (DirectionalAtom *)atoms[i];
211 <      
212 <      // get and convert the torque to body frame
213 <      
214 <      Tb[0] = dAtom->getTx();
215 <      Tb[1] = dAtom->getTy();
216 <      Tb[2] = dAtom->getTz();
217 <      
218 <      dAtom->lab2Body( Tb );
219 <      
220 <      // get the angular momentum, and complete the angular momentum
221 <      // half step
222 <      
223 <      ji[0] = dAtom->getJx();
224 <      ji[1] = dAtom->getJy();
225 <      ji[2] = dAtom->getJz();
226 <      
227 <      ji[0] += dt2 * (Tb[0] * eConvert - ji[0]*chi);
228 <      ji[1] += dt2 * (Tb[1] * eConvert - ji[1]*chi);
229 <      ji[2] += dt2 * (Tb[2] * eConvert - ji[2]*chi);
230 <      
231 <      dAtom->setJx( ji[0] );
232 <      dAtom->setJy( ji[1] );
233 <      dAtom->setJz( ji[2] );
146 >  for (i = 0; i < 3; i++ ) {
147 >    for (j = 0; j < 3; j++ ) {
148 >      vScale[i][j] = eta[i][j];
149 >
150 >      if (i == j) {
151 >        vScale[i][j] += chi;
152 >      }
153      }
154    }
155 +
156 +  for (j = 0; j < 3; j++)
157 +    myVel[j] = oldVel[3*index + j];
158 +
159 + //   std::cerr << "velScaleB = \n"
160 + //          << "[ " << vScale[0][0] << " , " << vScale[0][1] << " , " << vScale[0][2] << "]\n"
161 + //          << "[ " << vScale[1][0] << " , " << vScale[1][1] << " , " << vScale[1][2] << "]\n"
162 + //          << "[ " << vScale[2][0] << " , " << vScale[2][1] << " , " << vScale[2][2] << "]\n\n";
163 +
164 +
165 + //  std::cerr << "myVel " << index << " in => "
166 + //          << myVel[0] << ", " << myVel[1] << ", " << myVel[2] << "\n";
167 +
168 +  info->matVecMul3( vScale, myVel, sc );
169 +
170 + //  std::cerr << "sc " << index << " out => "
171 + //          << sc[0] << ", " << sc[1] << ", " << sc[2] << "\n";
172   }
173  
174 < int NPTi::readyCheck() {
175 <
176 <  // First check to see if we have a target temperature.
177 <  // Not having one is fatal.
178 <  
179 <  if (!have_target_temp) {
180 <    sprintf( painCave.errMsg,
181 <             "NPTi error: You can't use the NPTi integrator\n"
182 <             "   without a targetTemp!\n"
183 <             );
184 <    painCave.isFatal = 1;
185 <    simError();
186 <    return -1;
174 > void NPTf::getPosScale(double pos[3], double COM[3],
175 >                                               int index, double sc[3]){
176 >  int j;
177 >  double rj[3];
178 >
179 >  for(j=0; j<3; j++)
180 >    rj[j] = ( oldPos[index*3+j] + pos[j]) / 2.0 - COM[j];
181 >
182 >  info->matVecMul3( eta, rj, sc );
183 > }
184 >
185 > void NPTf::scaleSimBox( void ){
186 >
187 >  int i,j,k;
188 >  double scaleMat[3][3];
189 >  double eta2ij;
190 >  double bigScale, smallScale, offDiagMax;
191 >  double hm[3][3], hmnew[3][3];
192 >
193 >
194 >
195 >  // Scale the box after all the positions have been moved:
196 >
197 >  // Use a taylor expansion for eta products:  Hmat = Hmat . exp(dt * etaMat)
198 >  //  Hmat = Hmat . ( Ident + dt * etaMat  + dt^2 * etaMat*etaMat / 2)
199 >
200 >  bigScale = 1.0;
201 >  smallScale = 1.0;
202 >  offDiagMax = 0.0;
203 >
204 >  for(i=0; i<3; i++){
205 >    for(j=0; j<3; j++){
206 >
207 >      // Calculate the matrix Product of the eta array (we only need
208 >      // the ij element right now):
209 >
210 >      eta2ij = 0.0;
211 >      for(k=0; k<3; k++){
212 >        eta2ij += eta[i][k] * eta[k][j];
213 >      }
214 >
215 >      scaleMat[i][j] = 0.0;
216 >      // identity matrix (see above):
217 >      if (i == j) scaleMat[i][j] = 1.0;
218 >      // Taylor expansion for the exponential truncated at second order:
219 >      scaleMat[i][j] += dt*eta[i][j]  + 0.5*dt*dt*eta2ij;
220 >
221 >      if (i != j)
222 >        if (fabs(scaleMat[i][j]) > offDiagMax)
223 >          offDiagMax = fabs(scaleMat[i][j]);
224 >    }
225 >
226 >    if (scaleMat[i][i] > bigScale) bigScale = scaleMat[i][i];
227 >    if (scaleMat[i][i] < smallScale) smallScale = scaleMat[i][i];
228    }
229  
230 <  if (!have_target_pressure) {
230 >  if ((bigScale > 1.1) || (smallScale < 0.9)) {
231      sprintf( painCave.errMsg,
232 <             "NPTi error: You can't use the NPTi integrator\n"
233 <             "   without a targetPressure!\n"
234 <             );
232 >             "NPTf error: Attempting a Box scaling of more than 10 percent.\n"
233 >             " Check your tauBarostat, as it is probably too small!\n\n"
234 >             " scaleMat = [%lf\t%lf\t%lf]\n"
235 >             "            [%lf\t%lf\t%lf]\n"
236 >             "            [%lf\t%lf\t%lf]\n",
237 >             scaleMat[0][0],scaleMat[0][1],scaleMat[0][2],
238 >             scaleMat[1][0],scaleMat[1][1],scaleMat[1][2],
239 >             scaleMat[2][0],scaleMat[2][1],scaleMat[2][2]);
240      painCave.isFatal = 1;
241      simError();
242 <    return -1;
261 <  }
262 <  
263 <  // We must set tauThermostat.
264 <  
265 <  if (!have_tau_thermostat) {
242 >  } else if (offDiagMax > 0.1) {
243      sprintf( painCave.errMsg,
244 <             "NPTi error: If you use the NPTi\n"
245 <             "   integrator, you must set tauThermostat.\n");
244 >             "NPTf error: Attempting an off-diagonal Box scaling of more than 10 percent.\n"
245 >             " Check your tauBarostat, as it is probably too small!\n\n"
246 >             " scaleMat = [%lf\t%lf\t%lf]\n"
247 >             "            [%lf\t%lf\t%lf]\n"
248 >             "            [%lf\t%lf\t%lf]\n",
249 >             scaleMat[0][0],scaleMat[0][1],scaleMat[0][2],
250 >             scaleMat[1][0],scaleMat[1][1],scaleMat[1][2],
251 >             scaleMat[2][0],scaleMat[2][1],scaleMat[2][2]);
252      painCave.isFatal = 1;
253      simError();
254 <    return -1;
255 <  }    
254 >  } else {
255 >    info->getBoxM(hm);
256 >    info->matMul3(hm, scaleMat, hmnew);
257 >    info->setBoxM(hmnew);
258 >  }
259 > }
260  
261 <  // We must set tauBarostat.
262 <  
263 <  if (!have_tau_barostat) {
277 <    sprintf( painCave.errMsg,
278 <             "NPTi error: If you use the NPTi\n"
279 <             "   integrator, you must set tauBarostat.\n");
280 <    painCave.isFatal = 1;
281 <    simError();
282 <    return -1;
283 <  }    
261 > bool NPTf::etaConverged() {
262 >  int i;
263 >  double diffEta, sumEta;
264  
265 <  // We need NkBT a lot, so just set it here:
265 >  sumEta = 0;
266 >  for(i = 0; i < 3; i++)
267 >    sumEta += pow(prevEta[i][i] - eta[i][i], 2);
268  
269 <  NkBT = (double)info->ndf * kB * targetTemp;
269 >  diffEta = sqrt( sumEta / 3.0 );
270  
271 <  return 1;
271 >  return ( diffEta <= etaTolerance );
272   }
273 +
274 + double NPTf::getConservedQuantity(void){
275 +
276 +  double conservedQuantity;
277 +  double totalEnergy;
278 +  double thermostat_kinetic;
279 +  double thermostat_potential;
280 +  double barostat_kinetic;
281 +  double barostat_potential;
282 +  double trEta;
283 +  double a[3][3], b[3][3];
284 +
285 +  totalEnergy = tStats->getTotalE();
286 +
287 +  thermostat_kinetic = fkBT * tt2 * chi * chi /
288 +    (2.0 * eConvert);
289 +
290 +  thermostat_potential = fkBT* integralOfChidt / eConvert;
291 +
292 +  info->transposeMat3(eta, a);
293 +  info->matMul3(a, eta, b);
294 +  trEta = info->matTrace3(b);
295 +
296 +  barostat_kinetic = NkBT * tb2 * trEta /
297 +    (2.0 * eConvert);
298 +
299 +  barostat_potential = (targetPressure * tStats->getVolume() / p_convert) /
300 +    eConvert;
301 +
302 +  conservedQuantity = totalEnergy + thermostat_kinetic + thermostat_potential +
303 +    barostat_kinetic + barostat_potential;
304 +
305 + //   cout.width(8);
306 + //   cout.precision(8);
307 +
308 + //   cerr << info->getTime() << "\t" << Energy << "\t" << thermostat_kinetic <<
309 + //       "\t" << thermostat_potential << "\t" << barostat_kinetic <<
310 + //       "\t" << barostat_potential << "\t" << conservedQuantity << endl;
311 +
312 +  return conservedQuantity;
313 +
314 + }
315 +
316 + char* NPTf::getAdditionalParameters(void){
317 +
318 +  sprintf(addParamBuffer,
319 +          "\t%G\t%G;"
320 +          "\t%G\t%G\t%G;"
321 +          "\t%G\t%G\t%G;"
322 +          "\t%G\t%G\t%G;",
323 +          chi, integralOfChidt,
324 +          eta[0][0], eta[0][1], eta[0][2],
325 +          eta[1][0], eta[1][1], eta[1][2],
326 +          eta[2][0], eta[2][1], eta[2][2]
327 +          );
328 +
329 +  return addParamBuffer;
330 + }

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