source: src/analysis_correlation.cpp@ 5be0eb

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Last change on this file since 5be0eb was 790807, checked in by Frederik Heber <heber@…>, 15 years ago

Output....Correlation() don't prepend header line with '#', BinData() changed to just calculate BinEnd by itself.

  • BinData(): If BinEnd < BinStart, BinStart is taken over and just BinEnd calculate by GetMinMax().
  • this is needed for many histograms to be added on top of one another, there we need to have the same bins in each.
  • in all Output..Correlation() functions the '#' was eliminiated as pgfplots does not like it.
  • Property mode set to 100644
File size: 18.9 KB
Line 
1/*
2 * analysis.cpp
3 *
4 * Created on: Oct 13, 2009
5 * Author: heber
6 */
7
8#include <iostream>
9
10#include "analysis_correlation.hpp"
11#include "element.hpp"
12#include "info.hpp"
13#include "log.hpp"
14#include "molecule.hpp"
15#include "tesselation.hpp"
16#include "tesselationhelpers.hpp"
17#include "vector.hpp"
18#include "verbose.hpp"
19
20
21/** Calculates the pair correlation between given elements.
22 * Note given element order is unimportant (i.e. g(Si, O) === g(O, Si))
23 * \param *out output stream for debugging
24 * \param *molecules list of molecules structure
25 * \param *type1 first element or NULL (if any element)
26 * \param *type2 second element or NULL (if any element)
27 * \return Map of doubles with values the pair of the two atoms.
28 */
29PairCorrelationMap *PairCorrelation(MoleculeListClass * const &molecules, const element * const type1, const element * const type2 )
30{
31 Info FunctionInfo(__func__);
32 PairCorrelationMap *outmap = NULL;
33 double distance = 0.;
34
35 if (molecules->ListOfMolecules.empty()) {
36 eLog() << Verbose(1) <<"No molecule given." << endl;
37 return outmap;
38 }
39 outmap = new PairCorrelationMap;
40 for (MoleculeList::const_iterator MolWalker = molecules->ListOfMolecules.begin(); MolWalker != molecules->ListOfMolecules.end(); MolWalker++)
41 if ((*MolWalker)->ActiveFlag) {
42 eLog() << Verbose(2) << "Current molecule is " << *MolWalker << "." << endl;
43 atom *Walker = (*MolWalker)->start;
44 while (Walker->next != (*MolWalker)->end) {
45 Walker = Walker->next;
46 Log() << Verbose(3) << "Current atom is " << *Walker << "." << endl;
47 if ((type1 == NULL) || (Walker->type == type1)) {
48 for (MoleculeList::const_iterator MolOtherWalker = MolWalker; MolOtherWalker != molecules->ListOfMolecules.end(); MolOtherWalker++)
49 if ((*MolOtherWalker)->ActiveFlag) {
50 Log() << Verbose(2) << "Current other molecule is " << *MolOtherWalker << "." << endl;
51 atom *OtherWalker = (*MolOtherWalker)->start;
52 while (OtherWalker->next != (*MolOtherWalker)->end) { // only go up to Walker
53 OtherWalker = OtherWalker->next;
54 Log() << Verbose(3) << "Current otheratom is " << *OtherWalker << "." << endl;
55 if (Walker->nr < OtherWalker->nr)
56 if ((type2 == NULL) || (OtherWalker->type == type2)) {
57 distance = Walker->node->PeriodicDistance(OtherWalker->node, (*MolWalker)->cell_size);
58 //Log() << Verbose(1) <<"Inserting " << *Walker << " and " << *OtherWalker << endl;
59 outmap->insert ( pair<double, pair <atom *, atom*> > (distance, pair<atom *, atom*> (Walker, OtherWalker) ) );
60 }
61 }
62 }
63 }
64 }
65 }
66
67 return outmap;
68};
69
70/** Calculates the pair correlation between given elements.
71 * Note given element order is unimportant (i.e. g(Si, O) === g(O, Si))
72 * \param *out output stream for debugging
73 * \param *molecules list of molecules structure
74 * \param *type1 first element or NULL (if any element)
75 * \param *type2 second element or NULL (if any element)
76 * \param ranges[NDIM] interval boundaries for the periodic images to scan also
77 * \return Map of doubles with values the pair of the two atoms.
78 */
79PairCorrelationMap *PeriodicPairCorrelation(MoleculeListClass * const &molecules, const element * const type1, const element * const type2, const int ranges[NDIM] )
80{
81 Info FunctionInfo(__func__);
82 PairCorrelationMap *outmap = NULL;
83 double distance = 0.;
84 int n[NDIM];
85 Vector checkX;
86 Vector periodicX;
87 int Othern[NDIM];
88 Vector checkOtherX;
89 Vector periodicOtherX;
90
91 if (molecules->ListOfMolecules.empty()) {
92 eLog() << Verbose(1) <<"No molecule given." << endl;
93 return outmap;
94 }
95 outmap = new PairCorrelationMap;
96 for (MoleculeList::const_iterator MolWalker = molecules->ListOfMolecules.begin(); MolWalker != molecules->ListOfMolecules.end(); MolWalker++)
97 if ((*MolWalker)->ActiveFlag) {
98 double * FullMatrix = ReturnFullMatrixforSymmetric((*MolWalker)->cell_size);
99 double * FullInverseMatrix = InverseMatrix(FullMatrix);
100 eLog() << Verbose(2) << "Current molecule is " << *MolWalker << "." << endl;
101 atom *Walker = (*MolWalker)->start;
102 while (Walker->next != (*MolWalker)->end) {
103 Walker = Walker->next;
104 Log() << Verbose(3) << "Current atom is " << *Walker << "." << endl;
105 if ((type1 == NULL) || (Walker->type == type1)) {
106 periodicX.CopyVector(Walker->node);
107 periodicX.MatrixMultiplication(FullInverseMatrix); // x now in [0,1)^3
108 // go through every range in xyz and get distance
109 for (n[0]=-ranges[0]; n[0] <= ranges[0]; n[0]++)
110 for (n[1]=-ranges[1]; n[1] <= ranges[1]; n[1]++)
111 for (n[2]=-ranges[2]; n[2] <= ranges[2]; n[2]++) {
112 checkX.Init(n[0], n[1], n[2]);
113 checkX.AddVector(&periodicX);
114 checkX.MatrixMultiplication(FullMatrix);
115 for (MoleculeList::const_iterator MolOtherWalker = MolWalker; MolOtherWalker != molecules->ListOfMolecules.end(); MolOtherWalker++)
116 if ((*MolOtherWalker)->ActiveFlag) {
117 Log() << Verbose(2) << "Current other molecule is " << *MolOtherWalker << "." << endl;
118 atom *OtherWalker = (*MolOtherWalker)->start;
119 while (OtherWalker->next != (*MolOtherWalker)->end) { // only go up to Walker
120 OtherWalker = OtherWalker->next;
121 Log() << Verbose(3) << "Current otheratom is " << *OtherWalker << "." << endl;
122 if (Walker->nr < OtherWalker->nr)
123 if ((type2 == NULL) || (OtherWalker->type == type2)) {
124 periodicOtherX.CopyVector(OtherWalker->node);
125 periodicOtherX.MatrixMultiplication(FullInverseMatrix); // x now in [0,1)^3
126 // go through every range in xyz and get distance
127 for (Othern[0]=-ranges[0]; Othern[0] <= ranges[0]; Othern[0]++)
128 for (Othern[1]=-ranges[1]; Othern[1] <= ranges[1]; Othern[1]++)
129 for (Othern[2]=-ranges[2]; Othern[2] <= ranges[2]; Othern[2]++) {
130 checkOtherX.Init(Othern[0], Othern[1], Othern[2]);
131 checkOtherX.AddVector(&periodicOtherX);
132 checkOtherX.MatrixMultiplication(FullMatrix);
133 distance = checkX.Distance(&checkOtherX);
134 //Log() << Verbose(1) <<"Inserting " << *Walker << " and " << *OtherWalker << endl;
135 outmap->insert ( pair<double, pair <atom *, atom*> > (distance, pair<atom *, atom*> (Walker, OtherWalker) ) );
136 }
137 }
138 }
139 }
140 }
141 }
142 }
143 Free(&FullMatrix);
144 Free(&FullInverseMatrix);
145 }
146
147 return outmap;
148};
149
150/** Calculates the distance (pair) correlation between a given element and a point.
151 * \param *out output stream for debugging
152 * \param *molecules list of molecules structure
153 * \param *type element or NULL (if any element)
154 * \param *point vector to the correlation point
155 * \return Map of dobules with values as pairs of atom and the vector
156 */
157CorrelationToPointMap *CorrelationToPoint(MoleculeListClass * const &molecules, const element * const type, const Vector *point )
158{
159 Info FunctionInfo(__func__);
160 CorrelationToPointMap *outmap = NULL;
161 double distance = 0.;
162
163 if (molecules->ListOfMolecules.empty()) {
164 Log() << Verbose(1) <<"No molecule given." << endl;
165 return outmap;
166 }
167 outmap = new CorrelationToPointMap;
168 for (MoleculeList::const_iterator MolWalker = molecules->ListOfMolecules.begin(); MolWalker != molecules->ListOfMolecules.end(); MolWalker++)
169 if ((*MolWalker)->ActiveFlag) {
170 Log() << Verbose(2) << "Current molecule is " << *MolWalker << "." << endl;
171 atom *Walker = (*MolWalker)->start;
172 while (Walker->next != (*MolWalker)->end) {
173 Walker = Walker->next;
174 Log() << Verbose(3) << "Current atom is " << *Walker << "." << endl;
175 if ((type == NULL) || (Walker->type == type)) {
176 distance = Walker->node->PeriodicDistance(point, (*MolWalker)->cell_size);
177 Log() << Verbose(4) << "Current distance is " << distance << "." << endl;
178 outmap->insert ( pair<double, pair<atom *, const Vector*> >(distance, pair<atom *, const Vector*> (Walker, point) ) );
179 }
180 }
181 }
182
183 return outmap;
184};
185
186/** Calculates the distance (pair) correlation between a given element, all its periodic images and a point.
187 * \param *out output stream for debugging
188 * \param *molecules list of molecules structure
189 * \param *type element or NULL (if any element)
190 * \param *point vector to the correlation point
191 * \param ranges[NDIM] interval boundaries for the periodic images to scan also
192 * \return Map of dobules with values as pairs of atom and the vector
193 */
194CorrelationToPointMap *PeriodicCorrelationToPoint(MoleculeListClass * const &molecules, const element * const type, const Vector *point, const int ranges[NDIM] )
195{
196 Info FunctionInfo(__func__);
197 CorrelationToPointMap *outmap = NULL;
198 double distance = 0.;
199 int n[NDIM];
200 Vector periodicX;
201 Vector checkX;
202
203 if (molecules->ListOfMolecules.empty()) {
204 Log() << Verbose(1) <<"No molecule given." << endl;
205 return outmap;
206 }
207 outmap = new CorrelationToPointMap;
208 for (MoleculeList::const_iterator MolWalker = molecules->ListOfMolecules.begin(); MolWalker != molecules->ListOfMolecules.end(); MolWalker++)
209 if ((*MolWalker)->ActiveFlag) {
210 double * FullMatrix = ReturnFullMatrixforSymmetric((*MolWalker)->cell_size);
211 double * FullInverseMatrix = InverseMatrix(FullMatrix);
212 Log() << Verbose(2) << "Current molecule is " << *MolWalker << "." << endl;
213 atom *Walker = (*MolWalker)->start;
214 while (Walker->next != (*MolWalker)->end) {
215 Walker = Walker->next;
216 Log() << Verbose(3) << "Current atom is " << *Walker << "." << endl;
217 if ((type == NULL) || (Walker->type == type)) {
218 periodicX.CopyVector(Walker->node);
219 periodicX.MatrixMultiplication(FullInverseMatrix); // x now in [0,1)^3
220 // go through every range in xyz and get distance
221 for (n[0]=-ranges[0]; n[0] <= ranges[0]; n[0]++)
222 for (n[1]=-ranges[1]; n[1] <= ranges[1]; n[1]++)
223 for (n[2]=-ranges[2]; n[2] <= ranges[2]; n[2]++) {
224 checkX.Init(n[0], n[1], n[2]);
225 checkX.AddVector(&periodicX);
226 checkX.MatrixMultiplication(FullMatrix);
227 distance = checkX.Distance(point);
228 Log() << Verbose(4) << "Current distance is " << distance << "." << endl;
229 outmap->insert ( pair<double, pair<atom *, const Vector*> >(distance, pair<atom *, const Vector*> (Walker, point) ) );
230 }
231 }
232 }
233 Free(&FullMatrix);
234 Free(&FullInverseMatrix);
235 }
236
237 return outmap;
238};
239
240/** Calculates the distance (pair) correlation between a given element and a surface.
241 * \param *out output stream for debugging
242 * \param *molecules list of molecules structure
243 * \param *type element or NULL (if any element)
244 * \param *Surface pointer to Tesselation class surface
245 * \param *LC LinkedCell structure to quickly find neighbouring atoms
246 * \return Map of doubles with values as pairs of atom and the BoundaryTriangleSet that's closest
247 */
248CorrelationToSurfaceMap *CorrelationToSurface(MoleculeListClass * const &molecules, const element * const type, const Tesselation * const Surface, const LinkedCell *LC )
249{
250 Info FunctionInfo(__func__);
251 CorrelationToSurfaceMap *outmap = NULL;
252 double distance = 0;
253 class BoundaryTriangleSet *triangle = NULL;
254 Vector centroid;
255
256 if ((Surface == NULL) || (LC == NULL) || (molecules->ListOfMolecules.empty())) {
257 Log() << Verbose(1) <<"No Tesselation, no LinkedCell or no molecule given." << endl;
258 return outmap;
259 }
260 outmap = new CorrelationToSurfaceMap;
261 for (MoleculeList::const_iterator MolWalker = molecules->ListOfMolecules.begin(); MolWalker != molecules->ListOfMolecules.end(); MolWalker++)
262 if ((*MolWalker)->ActiveFlag) {
263 Log() << Verbose(2) << "Current molecule is " << *MolWalker << "." << endl;
264 atom *Walker = (*MolWalker)->start;
265 while (Walker->next != (*MolWalker)->end) {
266 Walker = Walker->next;
267 Log() << Verbose(3) << "Current atom is " << *Walker << "." << endl;
268 if ((type == NULL) || (Walker->type == type)) {
269 triangle = Surface->FindClosestTriangleToVector(Walker->node, LC );
270 if (triangle != NULL) {
271 distance = DistanceToTrianglePlane(Walker->node, triangle);
272 outmap->insert ( pair<double, pair<atom *, BoundaryTriangleSet*> >(distance, pair<atom *, BoundaryTriangleSet*> (Walker, triangle) ) );
273 }
274 }
275 }
276 }
277
278 return outmap;
279};
280
281/** Calculates the distance (pair) correlation between a given element, all its periodic images and and a surface.
282 * Note that we also put all periodic images found in the cells given by [ -ranges[i], ranges[i] ] and i=0,...,NDIM-1.
283 * I.e. We multiply the atom::node with the inverse of the domain matrix, i.e. transform it to \f$[0,0^3\f$, then add per
284 * axis an integer from [ -ranges[i], ranges[i] ] onto it and multiply with the domain matrix to bring it back into
285 * the real space. Then, we Tesselation::FindClosestTriangleToPoint() and DistanceToTrianglePlane().
286 * \param *out output stream for debugging
287 * \param *molecules list of molecules structure
288 * \param *type element or NULL (if any element)
289 * \param *Surface pointer to Tesselation class surface
290 * \param *LC LinkedCell structure to quickly find neighbouring atoms
291 * \param ranges[NDIM] interval boundaries for the periodic images to scan also
292 * \return Map of doubles with values as pairs of atom and the BoundaryTriangleSet that's closest
293 */
294CorrelationToSurfaceMap *PeriodicCorrelationToSurface(MoleculeListClass * const &molecules, const element * const type, const Tesselation * const Surface, const LinkedCell *LC, const int ranges[NDIM] )
295{
296 Info FunctionInfo(__func__);
297 CorrelationToSurfaceMap *outmap = NULL;
298 double distance = 0;
299 class BoundaryTriangleSet *triangle = NULL;
300 Vector centroid;
301 int n[NDIM];
302 Vector periodicX;
303 Vector checkX;
304
305 if ((Surface == NULL) || (LC == NULL) || (molecules->ListOfMolecules.empty())) {
306 Log() << Verbose(1) <<"No Tesselation, no LinkedCell or no molecule given." << endl;
307 return outmap;
308 }
309 outmap = new CorrelationToSurfaceMap;
310 double ShortestDistance = 0.;
311 BoundaryTriangleSet *ShortestTriangle = NULL;
312 for (MoleculeList::const_iterator MolWalker = molecules->ListOfMolecules.begin(); MolWalker != molecules->ListOfMolecules.end(); MolWalker++)
313 if ((*MolWalker)->ActiveFlag) {
314 double * FullMatrix = ReturnFullMatrixforSymmetric((*MolWalker)->cell_size);
315 double * FullInverseMatrix = InverseMatrix(FullMatrix);
316 Log() << Verbose(2) << "Current molecule is " << *MolWalker << "." << endl;
317 atom *Walker = (*MolWalker)->start;
318 while (Walker->next != (*MolWalker)->end) {
319 Walker = Walker->next;
320 Log() << Verbose(3) << "Current atom is " << *Walker << "." << endl;
321 if ((type == NULL) || (Walker->type == type)) {
322 periodicX.CopyVector(Walker->node);
323 periodicX.MatrixMultiplication(FullInverseMatrix); // x now in [0,1)^3
324 // go through every range in xyz and get distance
325 ShortestDistance = -1.;
326 for (n[0]=-ranges[0]; n[0] <= ranges[0]; n[0]++)
327 for (n[1]=-ranges[1]; n[1] <= ranges[1]; n[1]++)
328 for (n[2]=-ranges[2]; n[2] <= ranges[2]; n[2]++) {
329 checkX.Init(n[0], n[1], n[2]);
330 checkX.AddVector(&periodicX);
331 checkX.MatrixMultiplication(FullMatrix);
332 triangle = Surface->FindClosestTriangleToVector(&checkX, LC);
333 distance = Surface->GetDistanceSquaredToTriangle(checkX, triangle);
334 if ((ShortestDistance == -1.) || (distance < ShortestDistance)) {
335 ShortestDistance = distance;
336 ShortestTriangle = triangle;
337 }
338 }
339 // insert
340 ShortestDistance = sqrt(ShortestDistance);
341 outmap->insert ( pair<double, pair<atom *, BoundaryTriangleSet*> >(ShortestDistance, pair<atom *, BoundaryTriangleSet*> (Walker, ShortestTriangle) ) );
342 //Log() << Verbose(1) << "INFO: Inserting " << Walker << " with distance " << ShortestDistance << " to " << *ShortestTriangle << "." << endl;
343 }
344 }
345 Free(&FullMatrix);
346 Free(&FullInverseMatrix);
347 }
348
349 return outmap;
350};
351
352/** Returns the start of the bin for a given value.
353 * \param value value whose bin to look for
354 * \param BinWidth width of bin
355 * \param BinStart first bin
356 */
357double GetBin ( const double value, const double BinWidth, const double BinStart )
358{
359 Info FunctionInfo(__func__);
360 double bin =(double) (floor((value - BinStart)/BinWidth));
361 return (bin*BinWidth+BinStart);
362};
363
364
365/** Prints correlation (double, int) pairs to file.
366 * \param *file file to write to
367 * \param *map map to write
368 */
369void OutputCorrelation( ofstream * const file, const BinPairMap * const map )
370{
371 Info FunctionInfo(__func__);
372 *file << "BinStart\tCount" << endl;
373 for (BinPairMap::const_iterator runner = map->begin(); runner != map->end(); ++runner) {
374 *file << runner->first << "\t" << runner->second << endl;
375 }
376};
377
378/** Prints correlation (double, (atom*,atom*) ) pairs to file.
379 * \param *file file to write to
380 * \param *map map to write
381 */
382void OutputPairCorrelation( ofstream * const file, const PairCorrelationMap * const map )
383{
384 Info FunctionInfo(__func__);
385 *file << "BinStart\tAtom1\tAtom2" << endl;
386 for (PairCorrelationMap::const_iterator runner = map->begin(); runner != map->end(); ++runner) {
387 *file << runner->first << "\t" << *(runner->second.first) << "\t" << *(runner->second.second) << endl;
388 }
389};
390
391/** Prints correlation (double, int) pairs to file.
392 * \param *file file to write to
393 * \param *map map to write
394 */
395void OutputCorrelationToPoint( ofstream * const file, const CorrelationToPointMap * const map )
396{
397 Info FunctionInfo(__func__);
398 *file << "BinStart\tAtom::x[i]-point.x[i]" << endl;
399 for (CorrelationToPointMap::const_iterator runner = map->begin(); runner != map->end(); ++runner) {
400 *file << runner->first;
401 for (int i=0;i<NDIM;i++)
402 *file << "\t" << (runner->second.first->node->x[i] - runner->second.second->x[i]);
403 *file << endl;
404 }
405};
406
407/** Prints correlation (double, int) pairs to file.
408 * \param *file file to write to
409 * \param *map map to write
410 */
411void OutputCorrelationToSurface( ofstream * const file, const CorrelationToSurfaceMap * const map )
412{
413 Info FunctionInfo(__func__);
414 *file << "BinStart\tTriangle" << endl;
415 for (CorrelationToSurfaceMap::const_iterator runner = map->begin(); runner != map->end(); ++runner) {
416 *file << runner->first << "\t" << *(runner->second.first) << "\t" << *(runner->second.second) << endl;
417 }
418};
419
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