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All q at once kernel evaluation for speedup, don't repeat EMEarth1D calcualtions for each moment.

master
Trevor Irons пре 8 година
родитељ
комит
95100edf0b
3 измењених фајлова са 81 додато и 58 уклоњено
  1. 4
    3
      examples/KernelV0.cpp
  2. 10
    9
      include/KernelV0.h
  3. 67
    46
      src/KernelV0.cpp

+ 4
- 3
examples/KernelV0.cpp Прегледај датотеку

@@ -45,7 +45,7 @@ int main() {
45 45
 
46 46
         Kern->SetIntegrationSize( (Vector3r() << 200,200,200).finished() );
47 47
         Kern->SetIntegrationOrigin( (Vector3r() << 0,0,0).finished() );
48
-        Kern->SetTolerance( 1e-13 );
48
+        Kern->SetTolerance( 1e-12 );
49 49
         //Kern->SetTolerance( .55 ) ; // 1%
50 50
 
51 51
         Kern->SetPulseDuration(0.020);
@@ -57,8 +57,9 @@ int main() {
57 57
              31.347205894128976, 28.06346770557137, 25.139117042424758, 22.53420773366429, 20.214205433283347,
58 58
              18.144318026099942, 16.299965972298878, 14.652633628829891, 13.184271405688083, 11.870540177313893,
59 59
              10.697057141915716, 9.64778948429609, 8.709338689612677, 7.871268012862094;
60
-        Kern->SetPulseCurrent( VectorXr::LinSpaced( 1, 10, 200 )  ); // nbins, low, high
61
-        Kern->SetDepthLayerInterfaces( VectorXr::LinSpaced( 2, 5, 5.5 ) );
60
+        //Kern->SetPulseCurrent( VectorXr::LinSpaced( 1, 10, 200 )  ); // nbins, low, high
61
+        Kern->SetPulseCurrent( I ); // nbins, low, high
62
+        Kern->SetDepthLayerInterfaces( VectorXr::LinSpaced( 30, 3, 45.5 ) );
62 63
 
63 64
     // We could, I suppose, take the earth model in here? For non-linear that
64 65
     // may be more natural to work with?

+ 10
- 9
include/KernelV0.h Прегледај датотеку

@@ -223,10 +223,10 @@ namespace Lemma {
223 223
         /**
224 224
          *  Returns the kernel value for an input prism
225 225
          */
226
-        Complex f( const Vector3r& r, const Real& volume , const Vector3cr& Ht, const Vector3cr& Hr);
226
+        VectorXcr f( const Vector3r& r, const Real& volume , const Vector3cr& Ht, const Vector3cr& Hr);
227 227
 
228
-        Complex ComputeV0Cell(const Vector3cr& Bt, const Vector3cr& Br, const Real& vol,
229
-            const Real& phi);
228
+//         Complex ComputeV0Cell(const Vector3cr& Bt, const Vector3cr& Br, const Real& vol,
229
+//             const Real& phi);
230 230
 
231 231
         Complex ComputeV0Cell(const EllipticB& EBT, const EllipticB& EBR,
232 232
                 const Real& sintheta, const Real& phase, const Real& Mn0Abs,
@@ -236,7 +236,7 @@ namespace Lemma {
236 236
 
237 237
         Vector3r ComputeMn0(const Real& Porosity, const Vector3r& B0);
238 238
 
239
-        Complex IntegrateOnOctreeGrid( const int& ilay, const int& iq, bool vtkOutput=false );
239
+        Complex IntegrateOnOctreeGrid( const int& iq, bool vtkOutput=false );
240 240
 
241 241
         /**
242 242
          *  Recursive call to integrate a function on an adaptive Octree Grid.
@@ -249,7 +249,7 @@ namespace Lemma {
249 249
          *  @param[in] cpos is the centre position of the parent cuboid
250 250
          */
251 251
         void EvaluateKids(  const Vector3r& size, const int& level, const Vector3r& cpos,
252
-                            const Complex& parentVal );
252
+                            const VectorXcr& parentVal );
253 253
 
254 254
         #ifdef LEMMAUSEVTK
255 255
         /**
@@ -264,6 +264,7 @@ namespace Lemma {
264 264
 
265 265
         // ====================  DATA MEMBERS  =========================
266 266
 
267
+        int                                       ilay;
267 268
         int                                       nleaves;
268 269
         int                                       minLevel=4;
269 270
         int                                       maxLevel=8;
@@ -272,10 +273,10 @@ namespace Lemma {
272 273
         Real                                      tol=1e-11;
273 274
         Real                                      Temperature=283.;
274 275
         Real                                      Taup = .020;  // Sec
275
-        Real                                      Ip = 10;      // Amps
276
+        Real                                      Ip;           // Amps pulse current, deprecated PulseI
276 277
         Real                                      Larmor;
277 278
 
278
-        Complex                                   SUM;
279
+        Complex                                   SUM;          // Depreceated, use Kern instead
279 280
 
280 281
         Vector3r                                  Size;
281 282
         Vector3r                                  Origin;
@@ -283,12 +284,12 @@ namespace Lemma {
283 284
         VectorXr   PulseI;
284 285
         VectorXr   Interfaces;
285 286
 
286
-        std::shared_ptr< LayeredEarthEM >         SigmaModel = nullptr;
287
+        MatrixXcr   Kern;
287 288
 
289
+        std::shared_ptr< LayeredEarthEM >         SigmaModel = nullptr;
288 290
         std::shared_ptr< FieldPoints >            cpoints;
289 291
 
290 292
         std::map< std::string , std::shared_ptr< PolygonalWireAntenna > >  TxRx;
291
-
292 293
         std::map< std::string , std::shared_ptr< EMEarth1D > >             EMEarths;
293 294
 
294 295
         #ifdef LEMMAUSEVTK

+ 67
- 46
src/KernelV0.cpp Прегледај датотеку

@@ -121,6 +121,7 @@ namespace Lemma {
121 121
                 // TODO query for method, altough with flat antennae, this is fastest
122 122
                 EMEarths[tx]->SetHankelTransformMethod(ANDERSON801);
123 123
                 EMEarths[tx]->SetTxRxMode(TX);
124
+                TxRx[tx]->SetCurrent(1.);
124 125
         }
125 126
         for (auto rx : Rx) {
126 127
             if (EMEarths.count(rx)) {
@@ -134,33 +135,34 @@ namespace Lemma {
134 135
                     // TODO query for method, altough with flat antennae, this is fastest
135 136
                     EMEarths[rx]->SetHankelTransformMethod(ANDERSON801);
136 137
                     EMEarths[rx]->SetTxRxMode(RX);
138
+                    TxRx[rx]->SetCurrent(1.);
137 139
             }
138 140
         }
139 141
 
140 142
         std::cout << "Calculating K0 kernel\n";
141
-        MatrixXcr Kern = MatrixXcr::Zero( Interfaces.size()-1, PulseI.size() );
142
-        for (int ilay=0; ilay<Interfaces.size()-1; ++ilay) {
143
-            for (int iq=0; iq< PulseI.size(); ++iq) {
144
-                std::cout << "Layer " << ilay << " q " << iq << std::endl;
145
-                Size(2) = Interfaces(ilay+1) - Interfaces(ilay);
146
-                Origin(2) = Interfaces(ilay);
147
-                Ip = PulseI(iq);
148
-                Kern(ilay, iq) = IntegrateOnOctreeGrid( ilay, iq, vtkOutput );
149
-            }
143
+        Kern = MatrixXcr::Zero( Interfaces.size()-1, PulseI.size() );
144
+        for (ilay=0; ilay<Interfaces.size()-1; ++ilay) {
145
+            std::cout << "Layer " << ilay << std::endl; //<< " q " << iq << std::endl;
146
+            Size(2) = Interfaces(ilay+1) - Interfaces(ilay);
147
+            Origin(2) = Interfaces(ilay);
148
+            //for (int iq=0; iq< PulseI.size(); ++iq) {
149
+            //    Ip = PulseI(iq);
150
+                //Kern(ilay, iq) =
151
+            IntegrateOnOctreeGrid( 0, vtkOutput );
152
+            //}
150 153
         }
151 154
         std::cout << "\rFinished KERNEL\n";
152 155
         std::cout << "real\n";
153 156
         std::cout << Kern.real() << std::endl;
154 157
         std::cout << "imag\n";
155 158
         std::cout << Kern.imag() << std::endl;
156
-        //IntegrateOnOctreeGrid( vtkOutput );
157 159
     }
158 160
 
159 161
     //--------------------------------------------------------------------------------------
160 162
     //       Class:  KernelV0
161 163
     //      Method:  IntegrateOnOctreeGrid
162 164
     //--------------------------------------------------------------------------------------
163
-    Complex KernelV0::IntegrateOnOctreeGrid( const int& ilay, const int& iq, bool vtkOutput) {
165
+    Complex KernelV0::IntegrateOnOctreeGrid( const int& iq, bool vtkOutput) {
164 166
 
165 167
         Vector3r cpos = Origin + Size/2.;
166 168
 
@@ -168,7 +170,7 @@ namespace Lemma {
168 170
         VOLSUM = 0;
169 171
         nleaves = 0;
170 172
         if (!vtkOutput) {
171
-            EvaluateKids( Size, 0, cpos, 1e6 );
173
+            EvaluateKids( Size, 0, cpos, VectorXcr::Ones(PulseI.size()) );
172 174
         } else {
173 175
         #ifdef LEMMAUSEVTK
174 176
             vtkHyperOctree* oct = vtkHyperOctree::New();
@@ -253,39 +255,60 @@ namespace Lemma {
253 255
     //       Class:  KernelV0
254 256
     //      Method:  f
255 257
     //--------------------------------------------------------------------------------------
256
-    Complex KernelV0::f( const Vector3r& r, const Real& volume, const Vector3cr& Ht, const Vector3cr& Hr ) {
257
-        //return Complex(volume*Ht.dot(Hr));
258
-        return ComputeV0Cell(MU0*Ht, MU0*Hr, volume, 1.0);
259
-    }
260
-
261
-    //--------------------------------------------------------------------------------------
262
-    //       Class:  KernelV0
263
-    //      Method:  ComputeV0Cell
264
-    //--------------------------------------------------------------------------------------
265
-    Complex KernelV0::ComputeV0Cell(const Vector3cr& Bt,
266
-                const Vector3cr& Br, const Real& vol, const Real& phi) {
258
+    VectorXcr KernelV0::f( const Vector3r& r, const Real& volume, const Vector3cr& Ht, const Vector3cr& Hr ) {
267 259
 
268 260
         // Compute the elliptic fields
269 261
         Vector3r B0hat = SigmaModel->GetMagneticFieldUnitVector();
270 262
         Vector3r B0 = SigmaModel->GetMagneticField();
271 263
 
272 264
         // Elliptic representation
273
-        EllipticB EBT = EllipticFieldRep(Bt, B0hat);
274
-        EllipticB EBR = EllipticFieldRep(Br, B0hat);
265
+        EllipticB EBT = EllipticFieldRep(MU0*Ht, B0hat);
266
+        EllipticB EBR = EllipticFieldRep(MU0*Hr, B0hat);
275 267
 
276 268
         // Compute Mn0
277
-        Vector3r Mn0 = ComputeMn0(phi, B0);
269
+        Vector3r Mn0 = ComputeMn0(1.0, B0);
278 270
         Real Mn0Abs = Mn0.norm();
279 271
 
280
-        // Compute the tipping angle
281
-        Real sintheta = std::sin(0.5*GAMMA*Ip*Taup*std::abs(EBT.alpha-EBT.beta));
282
-
283
-        // Compute phase delay, TODO add transmiiter phase and delay time phase!
272
+        // Compute phase delay
273
+        // TODO add transmiiter phase and delay time phase!
284 274
         Real phase = EBR.zeta+EBT.zeta;
285 275
 
286
-        return ComputeV0Cell(EBT, EBR, sintheta, phase, Mn0Abs, vol);
276
+        // Calcuate vector of all responses
277
+        VectorXcr F = VectorXcr::Zero( PulseI.size() );
278
+        for (int iq=0; iq<PulseI.size(); ++iq) {
279
+            // Compute the tipping angle
280
+            Real sintheta = std::sin(0.5*GAMMA*PulseI(iq)*Taup*std::abs(EBT.alpha-EBT.beta));
281
+            F(iq) = ComputeV0Cell(EBT, EBR, sintheta, phase, Mn0Abs, volume);
282
+        }
283
+        return F;
287 284
     }
288 285
 
286
+//     //--------------------------------------------------------------------------------------
287
+//     //       Class:  KernelV0
288
+//     //      Method:  ComputeV0Cell
289
+//     //--------------------------------------------------------------------------------------
290
+//     Complex KernelV0::ComputeV0Cell(const Vector3cr& Bt,
291
+//                 const Vector3cr& Br, const Real& vol, const Real& phi) {
292
+//
293
+//         // Compute the elliptic fields
294
+//         Vector3r B0hat = SigmaModel->GetMagneticFieldUnitVector();
295
+//         Vector3r B0 = SigmaModel->GetMagneticField();
296
+//
297
+//         // Elliptic representation
298
+//         EllipticB EBT = EllipticFieldRep(Bt, B0hat);
299
+//         EllipticB EBR = EllipticFieldRep(Br, B0hat);
300
+//
301
+//         // Compute Mn0
302
+//         Vector3r Mn0 = ComputeMn0(phi, B0);
303
+//         Real Mn0Abs = Mn0.norm();
304
+//
305
+//         // Compute phase delay, TODO add transmiiter phase and delay time phase!
306
+//         Real phase = EBR.zeta+EBT.zeta;
307
+//
308
+//         Real sintheta = std::sin(0.5*GAMMA*Ip*Taup*std::abs(EBT.alpha-EBT.beta));
309
+//         return 0; ComputeV0Cell(EBT, EBR, sintheta, phase, Mn0Abs, vol);
310
+//     }
311
+
289 312
     //--------------------------------------------------------------------------------------
290 313
     //       Class:  KernelV0
291 314
     //      Method:  ComputeV0Cell
@@ -293,14 +316,10 @@ namespace Lemma {
293 316
     Complex KernelV0::ComputeV0Cell(const EllipticB& EBT, const EllipticB& EBR,
294 317
                 const Real& sintheta, const Real& phase, const Real& Mn0Abs,
295 318
                 const Real& vol) {
296
-
297
-        Vector3r B0hat = {1,0,0};
298
-
299 319
         // earth response of receiver adjoint field
320
+        Vector3r B0hat = SigmaModel->GetMagneticFieldUnitVector();
300 321
         Complex ejztr = std::exp(Complex(0, EBR.zeta + EBT.zeta));
301
-
302
-        Complex PhaseTerm = EBR.bhat.dot(EBT.bhat) +
303
-               (B0hat.dot(EBR.bhat.cross(EBT.bhat) ));
322
+        Complex PhaseTerm = EBR.bhat.dot(EBT.bhat) + (B0hat.dot(EBR.bhat.cross(EBT.bhat) ));
304 323
         return -vol*Complex(0,Larmor)*Mn0Abs*(EBR.alpha+EBR.beta)*ejztr*sintheta*PhaseTerm;
305 324
     }
306 325
 
@@ -338,7 +357,7 @@ namespace Lemma {
338 357
     //      Method:  EvaluateKids
339 358
     //--------------------------------------------------------------------------------------
340 359
     void KernelV0::EvaluateKids( const Vector3r& size, const int& level, const Vector3r& cpos,
341
-        const Complex& parentVal ) {
360
+        const VectorXcr& parentVal ) {
342 361
 
343 362
         std::cout << "\r" << (int)(1e2*VOLSUM/(Size[0]*Size[1]*Size[2])) << "\t" << nleaves;
344 363
         std::cout.flush();
@@ -359,7 +378,8 @@ namespace Lemma {
359 378
                         0, step[1], step[2],
360 379
                   step[0], step[1], step[2] ).finished();
361 380
 
362
-        VectorXcr kvals(8);       // individual kernel vals
381
+        //VectorXcr kvals(8);       // individual kernel vals
382
+        MatrixXcr kvals(8, PulseI.size());       // individual kernel vals
363 383
         cpoints->ClearFields();
364 384
         for (int ichild=0; ichild<8; ++ichild) {
365 385
             Vector3r cp = pos;    // Eigen complains about combining these
@@ -392,21 +412,22 @@ namespace Lemma {
392 412
         for (int ichild=0; ichild<8; ++ichild) {
393 413
             Vector3r cp = pos;    // Eigen complains about combining these
394 414
             cp += posadd.row(ichild);
395
-            kvals(ichild) = f(cp, vol, Ht.col(ichild), Hr.col(ichild));
415
+            kvals.row(ichild) = f(cp, vol, Ht.col(ichild), Hr.col(ichild));
396 416
         }
397 417
 
398
-        Complex ksum = kvals.sum();     // Kernel sum
418
+        VectorXcr ksum = kvals.colwise().sum();     // Kernel sum
399 419
         // Evaluate whether or not furthur splitting is needed
400
-        if ( std::abs(ksum - parentVal) > tol || level < minLevel && level < maxLevel ) {
420
+        if ( ((ksum - parentVal).array().abs() > tol).any() || level < minLevel && level < maxLevel ) {
421
+            // Not a leaf dive further in
401 422
             for (int ichild=0; ichild<8; ++ichild) {
402 423
                 Vector3r cp = pos; // Eigen complains about combining these
403 424
                 cp += posadd.row(ichild);
404
-                EvaluateKids( size, level+1, cp, kvals(ichild) );
425
+                EvaluateKids( size, level+1, cp, kvals.row(ichild) );
405 426
             }
406 427
             return; // not leaf
407 428
         }
408
-        // Save here instead?
409
-        SUM += ksum;
429
+        // implicit else, is a leaf
430
+        Kern.row(ilay) += ksum;
410 431
         VOLSUM += 8.*vol;
411 432
         nleaves += 1;
412 433
         return;     // is leaf
@@ -471,7 +492,7 @@ namespace Lemma {
471 492
         for (int ichild=0; ichild<8; ++ichild) {
472 493
             Vector3r cp = pos; // Eigen complains about combining these
473 494
             cp += posadd.row(ichild);
474
-            kvals(ichild) = f(cp, vol, Ht.col(ichild), Hr.col(ichild));
495
+            kvals(ichild) = f(cp, vol, Ht.col(ichild), Hr.col(ichild))(0);
475 496
         }
476 497
 
477 498
         Complex ksum = kvals.sum();     // Kernel sum

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