Kaynağa Gözat

Cleaning up Doxygen warnings, and added DCIP Module

add-code-of-conduct-1
Trevor Irons 6 yıl önce
ebeveyn
işleme
6b77a42717
53 değiştirilmiş dosya ile 225 ekleme ve 7421 silme
  1. 50
    0
      Modules/DCIP/CMakeLists.txt
  2. 8
    16
      Modules/DCIP/config/DCIPConfig.h.in
  3. 33
    37
      Modules/DCIP/include/DCIPElectrode.h
  4. 43
    51
      Modules/DCIP/include/DCSurvey.h
  5. 7
    0
      Modules/DCIP/src/CMakeLists.txt
  6. 16
    48
      Modules/DCIP/src/DCIPElectrode.cpp
  7. 30
    73
      Modules/DCIP/src/DCSurvey.cpp
  8. 2
    2
      Modules/FDEM1D/include/FHTKey101.h
  9. 0
    88
      Modules/FDEM1D/include/GroundedElectricDipole.h
  10. 0
    1
      Modules/FDEM1D/include/KernelEM1DBase.h
  11. 0
    1
      Modules/FDEM1D/include/KernelEM1DManager.h
  12. 0
    1
      Modules/FDEM1D/include/KernelEM1DReflBase.h
  13. 0
    1
      Modules/FDEM1D/include/KernelEM1DReflSpec.h
  14. 0
    1
      Modules/FDEM1D/include/KernelEM1DSpec.h
  15. 0
    1
      Modules/FDEM1D/include/MagneticDipole.h
  16. 0
    1
      Modules/FDEM1D/include/digitalfilterintegrator.h
  17. 0
    1
      Modules/FDEM1D/include/integrationkernel.h
  18. 0
    1
      Modules/FDEM1D/include/inversesolver.h
  19. 0
    1
      Modules/FDEM1D/include/sintransintegrationkernel.h
  20. 0
    85
      Modules/FDEM1D/src/GroundedElectricDipole.cpp
  21. 0
    342
      Modules/LemmaCore/examples/utORS.cpp
  22. 0
    34
      Modules/LemmaCore/examples/utQWEKey.cpp
  23. 0
    86
      Modules/LemmaCore/examples/utSerialize.cpp
  24. 0
    197
      Modules/LemmaCore/examples/utTEMSurvey.cpp
  25. 0
    168
      Modules/LemmaCore/examples/utXMLParse.cpp
  26. 0
    67
      Modules/LemmaCore/examples/utYAMLconfig.cpp
  27. 0
    84
      Modules/LemmaCore/examples/utgaussquad.cpp
  28. 0
    258
      Modules/LemmaCore/examples/utgmrprint.cpp
  29. 0
    93
      Modules/LemmaCore/examples/uthankel2.cpp
  30. 0
    257
      Modules/LemmaCore/examples/uthantenna.cpp
  31. 0
    218
      Modules/LemmaCore/examples/utlogbarriercg.cpp
  32. 0
    67
      Modules/LemmaCore/examples/utpolygonalantenna.cpp
  33. 0
    68
      Modules/LemmaCore/examples/utreadfemubc.cpp
  34. 0
    54
      Modules/LemmaCore/examples/utsandbox.cpp
  35. 0
    199
      Modules/LemmaCore/examples/uttemforward.cpp
  36. 0
    131
      Modules/LemmaCore/examples/utteminv1d.cpp
  37. 0
    84
      Modules/LemmaCore/examples/uttemreader.cpp
  38. 0
    207
      Modules/LemmaCore/examples/uttemsandbox.cpp
  39. 0
    319
      Modules/LemmaCore/examples/wireantenna.cpp
  40. 5
    1
      Modules/LemmaCore/include/CubicSplineInterpolator.h
  41. 28
    20
      Modules/LemmaCore/include/EarthModel.h
  42. 0
    1
      Modules/LemmaCore/include/Filter.h
  43. 0
    1
      Modules/LemmaCore/include/GridReader.h
  44. 0
    1
      Modules/LemmaCore/include/RectilinearGridReader.h
  45. 0
    1
      Modules/LemmaCore/include/WindowFilter.h
  46. 3
    0
      Modules/LemmaCore/include/helper.h
  47. 0
    0
      Modules/Optimization/CMakeLists.txt
  48. 0
    98
      Modules/Optimization/include/bicgstab.h
  49. 0
    437
      Modules/Optimization/include/cg.h
  50. 0
    1366
      Modules/Optimization/include/logbarriercg.h
  51. 0
    1956
      Modules/Optimization/include/logbarriercg_newton.h
  52. 0
    111
      Modules/Optimization/include/quasinewtonbfgs.h
  53. 0
    85
      Modules/Optimization/src/quasinewtonbfgs.cpp

+ 50
- 0
Modules/DCIP/CMakeLists.txt Dosyayı Görüntüle

@@ -0,0 +1,50 @@
1
+# Configure EMSchur3D 
2
+set(DCIP_VERSION_MAJOR "0")
3
+set(DCIP_VERSION_MINOR "0")
4
+set(DCIP_VERSION_PATCH "1")
5
+set(DCIP_VERSION "\"${DCIP_VERSION_MAJOR}.${DCIP_VERSION_MINOR}.${DCIP_VERSION_PATCH}\"")
6
+set(DCIP_VERSION_NOQUOTES "${DCIP_VERSION_MAJOR}.${DCIP_VERSION_MINOR}.${DCIP_VERSION_PATCH}")
7
+
8
+option ( LEMMA_MODULE_DCIP TRUE )
9
+
10
+configure_file (
11
+	"${CMAKE_CURRENT_SOURCE_DIR}/config/DCIPConfig.h.in"
12
+	"${PROJECT_BINARY_DIR}/include/DCIPConfig.h"
13
+	)
14
+install ( FILES  ${PROJECT_BINARY_DIR}/include/EMSchur3DConfig.h   DESTINATION ${CMAKE_INSTALL_PREFIX}/include/Lemma/ )
15
+
16
+	add_subdirectory("src")
17
+	add_library( dcip ${DCIPSOURCE} )  
18
+	target_include_directories( dcip PUBLIC "${CMAKE_CURRENT_SOURCE_DIR}/include" )
19
+
20
+	set_target_properties(dcip PROPERTIES 
21
+		VERSION  "${DCIP_VERSION_NOQUOTES}"
22
+		SOVERSION "${DCIP_VERSION_MAJOR}.${LEMMA_VERSION_MINOR}"
23
+		PROJECT_LABEL "DCIP ${LABEL_SUFFIX}"
24
+    	CXX_STANDARD_14
25
+    	CXX_STANDARD_REQUIRED_ON
26
+	)
27
+
28
+	# Linking
29
+	target_link_libraries(dcip "lemmacore" "fdem1d" )
30
+
31
+	# Linking
32
+	target_link_libraries(dcip ${VTK_LIBRARIES})
33
+
34
+	# Testing
35
+	#if (LEMMA_ENABLE_TESTING)
36
+	#	add_subdirectory(testing)
37
+	#endif()
38
+
39
+	# Install
40
+	install ( TARGETS dcip DESTINATION ${CMAKE_INSTALL_PREFIX}/lib )
41
+	install ( FILES include/EMSchur3D  DESTINATION ${CMAKE_INSTALL_PREFIX}/include/Lemma ) 
42
+	install ( DIRECTORY include/ DESTINATION ${CMAKE_INSTALL_PREFIX}/include/Lemma  FILES_MATCHING PATTERN "*.h")
43
+
44
+	#install ( DIRECTORY include/ DESTINATION ${CMAKE_INSTALL_PREFIX}/include/Lemma/  FILES_MATCHING PATTERN "FDEM1D")
45
+	#install ( DIRECTORY include/ DESTINATION ${CMAKE_INSTALL_PREFIX}/include/Lemma/FDEM1D  FILES_MATCHING PATTERN "*.h")
46
+
47
+	# Examples
48
+	#if (LEMMA_BUILD_EXAMPLES)
49
+	#	add_subdirectory(examples)
50
+	#endif()

Modules/LemmaCore/examples/utSkyTEM.cpp → Modules/DCIP/config/DCIPConfig.h.in Dosyayı Görüntüle

@@ -9,23 +9,15 @@
9 9
 
10 10
 /**
11 11
  * @file
12
- * @date      02/27/2015 11:02:43 AM
12
+ * @date      10/23/2018 01:57:40 PM
13 13
  * @version   $Id$
14 14
  * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2015, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2015, Trevor Irons
15
+ * @email     Trevor.Irons@utah.edu
16
+ * @copyright Copyright (c) 2018, University of Utah
17
+ * @copyright Copyright (c) 2018, Lemma Software, LLC
18 18
  */
19 19
 
20
-// SkyTEM forward modelling programme
21
-
22
-#include "TEMSurvey.h"
23
-
24
-int main() {
25
-
26
-    std::cout << "SkyTEM modelling\n";
27
-
28
-
29
-
30
-}
31
-
20
+#define DCIP_VERSION_MAJOR @DCIP_VERSION_MAJOR@
21
+#define DCIP_VERSION_MINOR @DCIP_VERSION_MINOR@
22
+#define DCIP_VERSION_PATCH @DCIP_VERSION_PATCH@
23
+#define DCIP_VERSION @DCIP_VERSION@

+ 33
- 37
Modules/DCIP/include/DCIPElectrode.h Dosyayı Görüntüle

@@ -26,8 +26,9 @@
26 26
 namespace Lemma {
27 27
 
28 28
     /**
29
-      \brief
30
-      \details
29
+      \brief    Describes the location of an electrode used in a DC/IP survey
30
+      \details  This class is used together with FEM4EllipticPDE to solve DC/IP
31
+                problems.
31 32
      */
32 33
     class DCIPElectrode : public LemmaObject {
33 34
 
@@ -39,16 +40,30 @@ namespace Lemma {
39 40
         // ====================  LIFECYCLE     =======================
40 41
 
41 42
         /**
42
-         * @copybrief LemmaObject::New()
43
-         * @copydetails LemmaObject::New()
43
+         * \brief   Returns new shared pointer to DCIP object.
44
+         * \details Use this method, as the default constructor is locked.
44 45
          */
45
-        static DCIPElectrode* New();
46
+        static std::shared_ptr<DCIPElectrode> NewSP();
46 47
 
47 48
         /**
48
-         *  @copybrief   LemmaObject::Delete()
49
-         *  @copydetails LemmaObject::Delete()
49
+         *  Uses YAML to serialize this object.
50
+         *  @return a YAML::Node
50 51
          */
51
-        void Delete();
52
+        YAML::Node Serialize() const;
53
+
54
+        /**
55
+         *   Constructs an object from a YAML::Node.
56
+         */
57
+        static std::shared_ptr<DCIPElectrode> DeSerialize(const YAML::Node& node);
58
+
59
+        /** Default protected constructor, use New */
60
+        explicit DCIPElectrode (const ctor_key& key);
61
+
62
+        /** Protected DeDerializing constructor, use factory DeSerialize  method*/
63
+        DCIPElectrode (const YAML::Node& node, const ctor_key& key);
64
+
65
+        /** Default protected destructor, use Delete */
66
+        virtual ~DCIPElectrode ();
52 67
 
53 68
         // ====================  OPERATORS     =======================
54 69
 
@@ -72,44 +87,25 @@ namespace Lemma {
72 87
         int GetNodeID() {return Node_ID;}
73 88
         // ====================  INQUIRY       =======================
74 89
 
75
-#ifdef HAVE_YAMLCPP
76
-        /**
77
-         *  Uses YAML to serialize this object.
78
-         *  @return a YAML::Node
79
-         */
80
-        YAML::Node Serialize() const;
81
-
82
-        /**
83
-         *   Constructs an object from a YAML::Node.
84
-         */
85
-        static DCIPElectrode* DeSerialize(const YAML::Node& node);
86
-#endif
90
+        /** Returns the name of the underlying class, similiar to Python's type */
91
+        virtual std::string GetName() const {
92
+            return this->CName;
93
+        }
87 94
 
88 95
         protected:
89 96
 
90 97
         // ====================  LIFECYCLE     =======================
91 98
 
92
-        /** Default protected constructor, use New */
93
-        DCIPElectrode (const std::string& name);
94
-
95
-#ifdef HAVE_YAMLCPP
96
-        /** Protected DeDerializing constructor, use factory DeSerialize  method*/
97
-        DCIPElectrode (const YAML::Node& node);
98
-#endif
99
-
100
-        /** Default protected destructor, use Delete */
101
-        ~DCIPElectrode ();
102
-
103
-        /**
104
-         *  @copybrief   LemmaObject::Release()
105
-         *  @copydetails LemmaObject::Release()
106
-         */
107
-        void Release();
108
-
109 99
         private:
110 100
 
111 101
         // ====================  DATA MEMBERS  =========================
112 102
 
103
+        /** ASCII string representation of the class name */
104
+        static constexpr auto CName = "DCIPElectrode";
105
+
106
+        /** no copy */
107
+        DCIPElectrode ( const DCIPElectrode& ) = delete;
108
+
113 109
         /** The location of the electrode */
114 110
         Vector3r Location;
115 111
 

+ 43
- 51
Modules/DCIP/include/DCSurvey.h Dosyayı Görüntüle

@@ -10,11 +10,9 @@
10 10
 /**
11 11
  * @file
12 12
  * @date      10/08/2014 01:51:50 PM
13
- * @version   $Id$
14 13
  * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
14
+ * @email     Trevor.Irons@lemmasoftware.org
15
+ * @copyright Copyright (c) 2014, 2018 Trevor Irons
18 16
  */
19 17
 
20 18
 #ifndef  DCSURVEY
@@ -23,10 +21,6 @@
23 21
 #include "LemmaObject.h"
24 22
 #include "DCIPElectrode.h"
25 23
 
26
-#ifdef HAVE_YAMLCPP
27
-#include "yaml-cpp/yaml.h"
28
-#endif
29
-
30 24
 #ifdef LEMMAUSEVTK
31 25
 #include <vtkDataSet.h>
32 26
 #endif
@@ -49,16 +43,30 @@ namespace Lemma {
49 43
         // ====================  LIFECYCLE     =======================
50 44
 
51 45
         /**
52
-         * @copybrief LemmaObject::New()
53
-         * @copydetails LemmaObject::New()
46
+         * \brief   Returns new shared pointer to DCIP object.
47
+         * \details Use this method, as the default constructor is locked.
54 48
          */
55
-        static DCSurvey* New();
49
+        static std::shared_ptr<DCSurvey> NewSP();
56 50
 
57 51
         /**
58
-         *  @copybrief   LemmaObject::Delete()
59
-         *  @copydetails LemmaObject::Delete()
52
+         *  Uses YAML to serialize this object.
53
+         *  @return a YAML::Node
60 54
          */
61
-        void Delete();
55
+        YAML::Node Serialize() const;
56
+
57
+        /**
58
+         *   Constructs an object from a YAML::Node.
59
+         */
60
+        static std::shared_ptr<DCSurvey> DeSerialize(const YAML::Node& node);
61
+
62
+        /** Default protected constructor, use New */
63
+        explicit DCSurvey (const ctor_key& key);
64
+
65
+        /** Default protected constructor, use New */
66
+        DCSurvey (const YAML::Node& node, const ctor_key& key);
67
+
68
+        /** Default protected destructor, use Delete */
69
+        virtual ~DCSurvey ();
62 70
 
63 71
         // ====================  OPERATORS     =======================
64 72
 
@@ -75,7 +83,7 @@ namespace Lemma {
75 83
          *   @param[in] label is an optional tag for electrode.
76 84
          *   @param[in] nodeID is the optional node ID on a mesh
77 85
          */
78
-        int PoundElectrode( DCIPElectrode* Electrode, const std::string& label = "NULL", const int& nodeID=-1 );
86
+        int PoundElectrode( std::shared_ptr<DCIPElectrode> Electrode, const std::string& label = "NULL", const int& nodeID=-1 );
79 87
 
80 88
         /** Alternative Factory method of setting electrodes. IN this manner all memoy management
81 89
          *  is handled by DCSurvey.
@@ -88,10 +96,10 @@ namespace Lemma {
88 96
          *  @param[in] label is an optional label for electrode.
89 97
          *  @param[in] nodeID is the optional node ID on a mesh
90 98
          */
91
-        DCIPElectrode* PoundElectrode( const Vector3r& loc, const std::string& label = "NULL", const int& nodeID=-1  );
99
+        std::shared_ptr<DCIPElectrode> PoundElectrode( const Vector3r& loc, const std::string& label = "NULL", const int& nodeID=-1  );
92 100
 
93 101
 #ifdef LEMMAUSEVTK
94
-        DCIPElectrode* PoundElectrode( const int& nodeID, vtkDataSet* Mesh, const std::string& label = "NULL" );
102
+        std::shared_ptr<DCIPElectrode> PoundElectrode( const int& nodeID, vtkDataSet* Mesh, const std::string& label = "NULL" );
95 103
 #endif
96 104
 
97 105
         /**
@@ -106,9 +114,9 @@ namespace Lemma {
106 114
          *   @param[in] J is the current intensity
107 115
          *   @see AddInjection(const int& iA, const int& iB, const Real& J)
108 116
          *   @see AddInjection(const int& iA, const Real& J)
109
-         *   @see AddInjection(DCIPElectrode* A, const Real& J)
117
+         *   @see AddInjection(std::shared_ptr<DCIPElectrode> A, const Real& J)
110 118
          */
111
-        int AddInjection( DCIPElectrode* A, DCIPElectrode* B, const Real& J);
119
+        int AddInjection( std::shared_ptr<DCIPElectrode> A, std::shared_ptr<DCIPElectrode> B, const Real& J);
112 120
 
113 121
         /**
114 122
          *   Adds an injection point.
@@ -117,17 +125,17 @@ namespace Lemma {
117 125
          *   B,  the negative current electrode is taken to be infinity
118 126
          *   @see AddInjection(const int& iA, const int& iB, const Real& J)
119 127
          *   @see AddInjection(const int& iA, const Real& J)
120
-         *   @see AddInjection(DCIPElectrode* A, DCIPElectrode* B, const Real& J)
128
+         *   @see AddInjection(std::shared_ptr<DCIPElectrode> A, std::shared_ptr<DCIPElectrode> B, const Real& J)
121 129
          */
122
-        int AddInjection( DCIPElectrode* A, const Real& J );
130
+        int AddInjection( std::shared_ptr<DCIPElectrode> A, const Real& J );
123 131
 
124 132
         /**
125 133
          *   Adds an injection point.
126 134
          *   @param[in] A is the positive current electrode index
127 135
          *   @param[in] B is the negative current electrode index
128 136
          *   @param[in] J is the current intensity
129
-         *   @see AddInjection(DCIPElectrode* A, DCIPElectrode* B, const Real& J)
130
-         *   @see AddInjection(DCIPElectrode* A, const Real& J)
137
+         *   @see AddInjection(std::shared_ptr<DCIPElectrode> A, std::shared_ptr<DCIPElectrode> B, const Real& J)
138
+         *   @see AddInjection(std::shared_ptr<DCIPElectrode> A, const Real& J)
131 139
          *   @see AddInjection(const int& iA, const Real& J)
132 140
          */
133 141
         int AddInjection( const int& iA, const int& iB, const Real& J );
@@ -136,8 +144,8 @@ namespace Lemma {
136 144
          *   Adds an injection point with the negative electrode at infinity.
137 145
          *   @param[in] A is the positive current electrode index
138 146
          *   @param[in] J is the current intensity
139
-         *   @see AddInjection(DCIPElectrode* A, DCIPElectrode* B, const Real& J)
140
-         *   @see AddInjection(DCIPElectrode* A, const Real& J)
147
+         *   @see AddInjection(std::shared_ptr<DCIPElectrode> A, std::shared_ptr<DCIPElectrode> B, const Real& J)
148
+         *   @see AddInjection(std::shared_ptr<DCIPElectrode> A, const Real& J)
141 149
          *   @see AddInjection(const int& iA, const int& iB, const Real& J)
142 150
          */
143 151
         int AddInjection( const int& iA, const Real& J );
@@ -147,13 +155,13 @@ namespace Lemma {
147 155
          *   @param[in] N is a pointer to the `negative' electrode
148 156
          *   @param[in] iJ is the current injection index to associate with this measurement
149 157
          */
150
-        void AddMeasurement( const int& iJ, DCIPElectrode* M, DCIPElectrode* N );
158
+        void AddMeasurement( const int& iJ, std::shared_ptr<DCIPElectrode> M, std::shared_ptr<DCIPElectrode> N );
151 159
 
152 160
         /** Adds a potential measurement via the electrode pair comparison \f$ M - N \f$.
153 161
          *   @param[in] M is the `positive' electrode string label name
154 162
          *   @param[in] N is the `negative' electrode string label name
155 163
          *   @param[in] iJ is the current injection index to associate with this measurement
156
-         *   @see AddMeasurement( const int& iJ, DCIPElectrode* M, DCIPElectrode* N )
164
+         *   @see AddMeasurement( const int& iJ, std::shared_ptr<DCIPElectrode> M, std::shared_ptr<DCIPElectrode> N )
157 165
          */
158 166
         void AddMeasurement( const int& ij, const std::string& M, const std::string& N);
159 167
 
@@ -178,44 +186,28 @@ namespace Lemma {
178 186
 
179 187
         // ====================  INQUIRY       =======================
180 188
 
181
-        #ifdef HAVE_YAMLCPP
182
-        YAML::Node Serialize() const;
183
-        static DCSurvey* DeSerialize(const YAML::Node& node);
184
-        #endif
185
-
186 189
         protected:
187 190
 
188 191
         // ====================  LIFECYCLE     =======================
189 192
 
190
-        /** Default protected constructor, use New */
191
-        DCSurvey (const std::string& name);
192
-
193
-        #ifdef HAVE_YAMLCPP
194
-        /** Default protected constructor, use New */
195
-        DCSurvey (const YAML::Node& node);
196
-        #endif
197
-
198
-        /** Default protected destructor, use Delete */
199
-        ~DCSurvey ();
200
-
201
-        /**
202
-         *  @copybrief   LemmaObject::Release()
203
-         *  @copydetails LemmaObject::Release()
204
-         */
205
-        void Release();
206
-
207 193
         private:
208 194
 
209 195
         // ====================  DATA MEMBERS  =========================
210 196
 
197
+        /** ASCII string representation of the class name */
198
+        static constexpr auto CName = "DCSurvey";
199
+
200
+        /** no copy */
201
+        DCSurvey ( const DCSurvey& ) = delete;
202
+
211 203
         /** The electrodes */
212
-        std::vector<DCIPElectrode*>                Electrodes;
204
+        std::vector< std::shared_ptr<DCIPElectrode> >                Electrodes;
213 205
 
214 206
         /** Tags for the electrodes, lines etc. Ordered with Electrodes std::vector */
215 207
         std::vector<std::string>                   OrderedElectrodeLabels;
216 208
 
217 209
         /** Map of tags for the electrodes, lines etc. */
218
-        std::map<std::string, std::pair<DCIPElectrode*, int> >      ElectrodeLabelMap;
210
+        std::map<std::string, std::pair< std::shared_ptr<DCIPElectrode>, int> >      ElectrodeLabelMap;
219 211
 
220 212
         /** The A Injection electrodes */
221 213
         std::vector<int>     A_Electrodes;

+ 7
- 0
Modules/DCIP/src/CMakeLists.txt Dosyayı Görüntüle

@@ -0,0 +1,7 @@
1
+set (DCIPSOURCE
2
+	
3
+	${CMAKE_CURRENT_SOURCE_DIR}/DCIPElectrode.cpp
4
+	${CMAKE_CURRENT_SOURCE_DIR}/DCSurvey.cpp
5
+	
6
+	PARENT_SCOPE
7
+)

+ 16
- 48
Modules/DCIP/src/DCIPElectrode.cpp Dosyayı Görüntüle

@@ -24,54 +24,45 @@ namespace Lemma {
24 24
 
25 25
 
26 26
     // ====================  FRIEND METHODS  =====================
27
-#ifdef HAVE_YAMLCPP
27
+
28 28
     std::ostream &operator << (std::ostream &stream, const DCIPElectrode &ob) {
29
-        stream << ob.Serialize()  << "\n---\n"; // End of doc --- as a direct stream should encapulate thingy
30
-        return stream;
31
-    }
32
-#else
33
-    std::ostream &operator<<(std::ostream &stream, const DCIPElectrode& ob) {
34
-        stream << *(LemmaObject*)(&ob);
29
+        stream << ob.Serialize()  << "\n";
35 30
         return stream;
36 31
     }
37
-#endif
38 32
 
39 33
     // ====================  LIFECYCLE     =======================
40 34
 
41 35
     //--------------------------------------------------------------------------------------
42 36
     //       Class:  DCIPElectrode
43 37
     //      Method:  DCIPElectrode
44
-    // Description:  constructor (protected)
38
+    // Description:  constructor (locked)
45 39
     //--------------------------------------------------------------------------------------
46
-    DCIPElectrode::DCIPElectrode (const std::string& name) : LemmaObject(name), Node_ID(-1), Label(std::string("None")) {
40
+    DCIPElectrode::DCIPElectrode (const ctor_key& key) :
41
+            LemmaObject(key), Node_ID(-1), Label(std::string("None")) {
47 42
 
48 43
     }  // -----  end of method DCIPElectrode::DCIPElectrode  (constructor)  -----
49 44
 
50
-#ifdef HAVE_YAMLCPP
51 45
     //--------------------------------------------------------------------------------------
52 46
     //       Class:  DCIPElectrode
53 47
     //      Method:  DCIPElectrode
54
-    // Description:  DeSerializing constructor (protected)
48
+    // Description:  DeSerializing constructor (locked)
55 49
     //--------------------------------------------------------------------------------------
56
-    DCIPElectrode::DCIPElectrode (const YAML::Node& node) : LemmaObject(node) {
57
-        if (node.Tag() != this->Name) {
50
+    DCIPElectrode::DCIPElectrode (const YAML::Node& node, const ctor_key& key) : LemmaObject(node, key) {
51
+        if (node.Tag() != DCIPElectrode::CName) {
58 52
             throw std::runtime_error("In DCIPElectrode(node), node is of wrong type");
59 53
         }
60 54
         this->Location = node["Location"].as<Vector3r>();
61 55
         this->Node_ID = node["Node_ID"].as<int>();
62 56
         this->Label = node["Label"].as<std::string>();
63 57
     }  // -----  end of method DCIPElectrode::DCIPElectrode  (constructor)  -----
64
-#endif
65 58
 
66 59
     //--------------------------------------------------------------------------------------
67 60
     //       Class:  DCIPElectrode
68 61
     //      Method:  New()
69 62
     // Description:  public constructor
70 63
     //--------------------------------------------------------------------------------------
71
-    DCIPElectrode* DCIPElectrode::New() {
72
-        DCIPElectrode*  Obj = new DCIPElectrode("DCIPElectrode");
73
-        Obj->AttachTo(Obj);
74
-        return Obj;
64
+    std::shared_ptr<DCIPElectrode> DCIPElectrode::NewSP() {
65
+        return std::make_shared<DCIPElectrode>( ctor_key() );
75 66
     }
76 67
 
77 68
     //--------------------------------------------------------------------------------------
@@ -85,31 +76,11 @@ namespace Lemma {
85 76
 
86 77
     //--------------------------------------------------------------------------------------
87 78
     //       Class:  DCIPElectrode
88
-    //      Method:  Delete
89
-    // Description:  public destructor
90
-    //--------------------------------------------------------------------------------------
91
-    void DCIPElectrode::Delete() {
92
-        this->DetachFrom(this);
93
-    }
94
-
95
-    //--------------------------------------------------------------------------------------
96
-    //       Class:  DCIPElectrode
97
-    //      Method:  Release
98
-    // Description:  destructor (protected)
99
-    //--------------------------------------------------------------------------------------
100
-    void DCIPElectrode::Release() {
101
-        delete this;
102
-    }
103
-
104
-
105
-#ifdef HAVE_YAMLCPP
106
-    //--------------------------------------------------------------------------------------
107
-    //       Class:  DCIPElectrode
108 79
     //      Method:  Serialize
109 80
     //--------------------------------------------------------------------------------------
110 81
     YAML::Node  DCIPElectrode::Serialize (  ) const {
111 82
         YAML::Node node = LemmaObject::Serialize();
112
-        node.SetTag( this->Name );
83
+        node.SetTag( this->GetName() );
113 84
         // FILL IN CLASS SPECIFICS HERE
114 85
         node["Location"] = Location;
115 86
         node["Node_ID"] = Node_ID;
@@ -117,19 +88,16 @@ namespace Lemma {
117 88
         return node;
118 89
     }		// -----  end of method DCIPElectrode::Serialize  -----
119 90
 
120
-
121 91
     //--------------------------------------------------------------------------------------
122 92
     //       Class:  DCIPElectrode
123 93
     //      Method:  DeSerialize
124 94
     //--------------------------------------------------------------------------------------
125
-    DCIPElectrode* DCIPElectrode::DeSerialize ( const YAML::Node& node  ) {
126
-        DCIPElectrode* Object = new DCIPElectrode(node);
127
-        Object->AttachTo(Object);
128
-        DESERIALIZECHECK( node, Object )
129
-        return Object ;
95
+    std::shared_ptr<DCIPElectrode> DCIPElectrode::DeSerialize ( const YAML::Node& node  ) {
96
+        if ( node.Tag() != DCIPElectrode::CName ) {
97
+            throw  DeSerializeTypeMismatch( DCIPElectrode::CName, node.Tag());
98
+        }
99
+        return std::make_shared< DCIPElectrode > ( node, ctor_key() );
130 100
     }		// -----  end of method DCIPElectrode::DeSerialize  -----
131
-#endif
132
-
133 101
 
134 102
     //--------------------------------------------------------------------------------------
135 103
     //       Class:  DCIPElectrode

+ 30
- 73
Modules/DCIP/src/DCSurvey.cpp Dosyayı Görüntüle

@@ -10,31 +10,21 @@
10 10
 /**
11 11
  * @file
12 12
  * @date      10/08/2014 01:52:04 PM
13
- * @version   $Id$
14 13
  * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
14
+ * @email     Trevor.Irons@lemmasoftware.org
15
+ * @copyright Copyright (c) 2014, 2018 Trevor Irons
18 16
  */
19 17
 
20 18
 #include	"DCSurvey.h"
21 19
 
22 20
 namespace Lemma {
23 21
 
24
-
25 22
     // ====================  FRIEND METHODS  =====================
26 23
 
27
-    #ifdef HAVE_YAMLCPP
28 24
     std::ostream &operator << (std::ostream &stream, const DCSurvey &ob) {
29
-        stream << ob.Serialize()  << "\n---\n"; // End of doc --- a direct stream should encapsulate object
30
-        return stream;
31
-    }
32
-    #else
33
-    std::ostream &operator<<(std::ostream &stream, const DCSurvey &ob) {
34
-        stream << *(LemmaObject*)(&ob);
25
+        stream << ob.Serialize()  << "\n";
35 26
         return stream;
36 27
     }
37
-    #endif
38 28
 
39 29
     // ====================  LIFECYCLE     =======================
40 30
 
@@ -43,7 +33,7 @@ namespace Lemma {
43 33
     //      Method:  DCSurvey
44 34
     // Description:  constructor (protected)
45 35
     //--------------------------------------------------------------------------------------
46
-    DCSurvey::DCSurvey (const std::string& name) : LemmaObject(name) {
36
+    DCSurvey::DCSurvey (const ctor_key& key) : LemmaObject(key) {
47 37
 
48 38
     }  // -----  end of method DCSurvey::DCSurvey  (constructor)  -----
49 39
 
@@ -52,8 +42,7 @@ namespace Lemma {
52 42
     //      Method:  DCSurvey
53 43
     // Description:  DeSerializing constructor (protected)
54 44
     //--------------------------------------------------------------------------------------
55
-    #ifdef HAVE_YAMLCPP
56
-    DCSurvey::DCSurvey (const YAML::Node& node) : LemmaObject(node) {
45
+    DCSurvey::DCSurvey (const YAML::Node& node, const ctor_key& key) : LemmaObject(node, key) {
57 46
 
58 47
         if (node.Tag() != "DCSurvey") {
59 48
             throw std::runtime_error("DCSurvey->DeSerialize cannot deserialize non-DCSurvey");
@@ -63,10 +52,9 @@ namespace Lemma {
63 52
         for(YAML::const_iterator it=node["Electrodes"].begin(); it!=node["Electrodes"].end(); ++it) {
64 53
             std::string e = it->first.as<std::string>();
65 54
             Electrodes.push_back( DCIPElectrode::DeSerialize( node["Electrodes"][e] ) );
66
-            Electrodes[Electrodes.size()-1]->AttachTo(this);
67 55
             eMap[ node["Electrodes"][Electrodes.size()-1] ] = Electrodes.size() -1 ;
68 56
             OrderedElectrodeLabels.push_back(e);
69
-            ElectrodeLabelMap[e] = std::pair<DCIPElectrode*, int>(Electrodes[Electrodes.size()-1], Electrodes.size()-1);
57
+            ElectrodeLabelMap[e] = std::pair< std::shared_ptr<DCIPElectrode>, int>(Electrodes[Electrodes.size()-1], Electrodes.size()-1);
70 58
         }
71 59
 
72 60
         //std::cout << "J-0\n" << node["Injections"]["J-0"] << std::endl;
@@ -93,17 +81,14 @@ namespace Lemma {
93 81
         }
94 82
 
95 83
     }  // -----  end of method DCSurvey::DCSurvey  (constructor)  -----
96
-    #endif
97 84
 
98 85
     //--------------------------------------------------------------------------------------
99 86
     //       Class:  DCSurvey
100 87
     //      Method:  New()
101 88
     // Description:  public constructor
102 89
     //--------------------------------------------------------------------------------------
103
-    DCSurvey* DCSurvey::New() {
104
-        DCSurvey*  Obj = new DCSurvey("DCSurvey");
105
-        Obj->AttachTo(Obj);
106
-        return Obj;
90
+    std::shared_ptr<DCSurvey> DCSurvey::NewSP() {
91
+        return std::make_shared<DCSurvey>( ctor_key() );
107 92
     }
108 93
 
109 94
     //--------------------------------------------------------------------------------------
@@ -117,35 +102,15 @@ namespace Lemma {
117 102
 
118 103
     //--------------------------------------------------------------------------------------
119 104
     //       Class:  DCSurvey
120
-    //      Method:  Delete
121
-    // Description:  public destructor
122
-    //--------------------------------------------------------------------------------------
123
-    void DCSurvey::Delete() {
124
-        this->DetachFrom(this);
125
-    }
126
-
127
-    //--------------------------------------------------------------------------------------
128
-    //       Class:  DCSurvey
129
-    //      Method:  Release
130
-    // Description:  destructor (protected)
131
-    //--------------------------------------------------------------------------------------
132
-    void DCSurvey::Release() {
133
-        this->PullElectrodes();
134
-        delete this;
135
-    }
136
-
137
-    #ifdef HAVE_YAMLCPP
138
-    //--------------------------------------------------------------------------------------
139
-    //       Class:  DCSurvey
140 105
     //      Method:  Serialize
141 106
     //--------------------------------------------------------------------------------------
142 107
     YAML::Node  DCSurvey::Serialize (  ) const {
143 108
         YAML::Node node = LemmaObject::Serialize();
144
-        node.SetTag( this->Name );
109
+        node.SetTag( this->GetName() );
145 110
         node["NumberOfElectrodes"] = Electrodes.size();
146 111
 
147 112
         // All the electrodes
148
-        for (std::map<std::string, std::pair<DCIPElectrode*, int> >::const_iterator it  = ElectrodeLabelMap.begin();
113
+        for (std::map<std::string, std::pair< std::shared_ptr<DCIPElectrode>, int> >::const_iterator it  = ElectrodeLabelMap.begin();
149 114
                                                                                     it != ElectrodeLabelMap.end(); ++it) {
150 115
             node["Electrodes"][ it->first ] = it->second.first->Serialize();
151 116
         }
@@ -168,38 +133,35 @@ namespace Lemma {
168 133
         return node;
169 134
     }		// -----  end of method DCSurvey::Serialize  -----
170 135
 
171
-
172 136
     //--------------------------------------------------------------------------------------
173 137
     //       Class:  DCSurvey
174 138
     //      Method:  DeSerialize
175 139
     //--------------------------------------------------------------------------------------
176
-    DCSurvey* DCSurvey::DeSerialize ( const YAML::Node& node  ) {
177
-        DCSurvey* Object = new DCSurvey(node);
178
-        Object->AttachTo(Object);
179
-        DESERIALIZECHECK( node, Object )
180
-        return Object ;
140
+    std::shared_ptr<DCSurvey> DCSurvey::DeSerialize ( const YAML::Node& node  ) {
141
+        if ( node.Tag() != DCSurvey::CName ) {
142
+            throw  DeSerializeTypeMismatch( DCSurvey::CName, node.Tag());
143
+        }
144
+        return std::make_shared< DCSurvey > ( node, ctor_key() );
181 145
     }		// -----  end of method DCSurvey::DeSerialize  -----
182
-    #endif
183 146
 
184 147
     //--------------------------------------------------------------------------------------
185 148
     //       Class:  DCSurvey
186 149
     //      Method:  PoundElectrode
187 150
     //--------------------------------------------------------------------------------------
188
-    int DCSurvey::PoundElectrode ( DCIPElectrode* Electrode, const std::string& tag, const int&nodeID ) {
151
+    int DCSurvey::PoundElectrode ( std::shared_ptr<DCIPElectrode> Electrode, const std::string& tag, const int&nodeID ) {
189 152
         Electrodes.push_back(Electrode);
190 153
         if (tag != "NULL") {
191 154
             OrderedElectrodeLabels.push_back(tag);
192 155
             //ElectrodeTagMap[tag] = Electrode;
193
-            ElectrodeLabelMap[tag] = std::pair<DCIPElectrode*, int> (Electrode, Electrodes.size()-1);
156
+            ElectrodeLabelMap[tag] = std::pair< std::shared_ptr<DCIPElectrode>, int> (Electrode, Electrodes.size()-1);
194 157
             Electrode->SetLabel(tag);
195 158
         } else {
196 159
             OrderedElectrodeLabels.push_back( std::string("E") + to_string(Electrodes.size()-1) );
197 160
             //ElectrodeTagMap[std::string("E") + to_string(Electrodes.size()-1)] = Electrode;
198 161
             ElectrodeLabelMap[std::string("E") + to_string(Electrodes.size()-1)] =
199
-                std::pair<DCIPElectrode*, int>(Electrode, Electrodes.size()-1);
162
+                std::pair< std::shared_ptr<DCIPElectrode>, int>(Electrode, Electrodes.size()-1);
200 163
             Electrode->SetLabel( std::string("E") + to_string(Electrodes.size()-1) );
201 164
         }
202
-        Electrode->AttachTo(this);
203 165
         return  static_cast<int>( Electrodes.size() ) ;
204 166
     }		// -----  end of method DCSurvey::PoundElectrode  -----
205 167
 
@@ -207,21 +169,20 @@ namespace Lemma {
207 169
     //       Class:  DCSurvey
208 170
     //      Method:  PoundElectrode
209 171
     //--------------------------------------------------------------------------------------
210
-    DCIPElectrode* DCSurvey::PoundElectrode ( const Vector3r& loc, const std::string& tag, const int& nodeID ) {
211
-        DCIPElectrode* Electrode = DCIPElectrode::New();
172
+    std::shared_ptr<DCIPElectrode> DCSurvey::PoundElectrode ( const Vector3r& loc, const std::string& tag, const int& nodeID ) {
173
+        auto Electrode = DCIPElectrode::NewSP();
212 174
             Electrode->SetLocation( loc );
213 175
         Electrodes.push_back(Electrode);
214 176
         if (tag != "NULL") {
215 177
             OrderedElectrodeLabels.push_back(tag);
216
-            ElectrodeLabelMap[tag] = std::pair<DCIPElectrode*, int> (Electrode, Electrodes.size()-1);
178
+            ElectrodeLabelMap[tag] = std::pair< std::shared_ptr<DCIPElectrode>, int> (Electrode, Electrodes.size()-1);
217 179
             Electrode->SetLabel(tag);
218 180
         } else {
219 181
             OrderedElectrodeLabels.push_back( std::string("E") + to_string(Electrodes.size()-1) );
220 182
             ElectrodeLabelMap[std::string("E") + to_string(Electrodes.size()-1)] =
221
-                std::pair<DCIPElectrode*, int>(Electrode, Electrodes.size()-1);
183
+                std::pair< std::shared_ptr<DCIPElectrode>, int>(Electrode, Electrodes.size()-1);
222 184
             Electrode->SetLabel( std::string("E") + to_string(Electrodes.size()-1) );
223 185
         }
224
-        Electrode->AttachTo(this);
225 186
         return  Electrode;
226 187
     }		// -----  end of method DCSurvey::PoundElectrode  -----
227 188
 
@@ -230,22 +191,21 @@ namespace Lemma {
230 191
     //      Method:  PoundElectrode
231 192
     //--------------------------------------------------------------------------------------
232 193
 #ifdef LEMMAUSEVTK
233
-    DCIPElectrode* DCSurvey::PoundElectrode( const int& nodeID, vtkDataSet* Mesh, const std::string& tag ) {
234
-        DCIPElectrode* Electrode = DCIPElectrode::New();
194
+    std::shared_ptr<DCIPElectrode> DCSurvey::PoundElectrode( const int& nodeID, vtkDataSet* Mesh, const std::string& tag ) {
195
+        auto Electrode = DCIPElectrode::NewSP();
235 196
         double* loc = Mesh->GetPoint(nodeID);
236 197
         Electrode->SetLocation( Vector3r(loc[0], loc[1], loc[2]) );
237 198
         Electrodes.push_back(Electrode);
238 199
         if (tag != "NULL") {
239 200
             OrderedElectrodeLabels.push_back(tag);
240
-            ElectrodeLabelMap[tag] = std::pair<DCIPElectrode*, int> (Electrode, Electrodes.size()-1);
201
+            ElectrodeLabelMap[tag] = std::pair< std::shared_ptr<DCIPElectrode>, int> (Electrode, Electrodes.size()-1);
241 202
             Electrode->SetLabel(tag);
242 203
         } else {
243 204
             OrderedElectrodeLabels.push_back( std::string("E") + to_string(Electrodes.size()-1) );
244 205
             ElectrodeLabelMap[std::string("E") + to_string(Electrodes.size()-1)] =
245
-                std::pair<DCIPElectrode*, int>(Electrode, Electrodes.size()-1);
206
+                std::pair< std::shared_ptr<DCIPElectrode>, int>(Electrode, Electrodes.size()-1);
246 207
             Electrode->SetLabel( std::string("E") + to_string(Electrodes.size()-1) );
247 208
         }
248
-        Electrode->AttachTo(this);
249 209
         return Electrode;
250 210
     }		// -----  end of method DCSurvey::PoundElectrode  -----
251 211
 #endif
@@ -255,9 +215,6 @@ namespace Lemma {
255 215
     //      Method:  PullElectrodes
256 216
     //--------------------------------------------------------------------------------------
257 217
     void DCSurvey::PullElectrodes (  ) {
258
-        for (std::vector<DCIPElectrode*>::iterator it = Electrodes.begin() ; it != Electrodes.end(); ++it) {
259
-            (*it)->DetachFrom(this);
260
-        }
261 218
         Electrodes.clear();
262 219
         OrderedElectrodeLabels.clear();
263 220
         ElectrodeLabelMap.clear();
@@ -274,7 +231,7 @@ namespace Lemma {
274 231
     //       Class:  DCSurvey
275 232
     //      Method:  AddInjection
276 233
     //--------------------------------------------------------------------------------------
277
-    int DCSurvey::AddInjection ( DCIPElectrode* A, DCIPElectrode* B, const Real& J ) {
234
+    int DCSurvey::AddInjection ( std::shared_ptr<DCIPElectrode> A, std::shared_ptr<DCIPElectrode> B, const Real& J ) {
278 235
         bool fA = false;
279 236
         bool fB = false;
280 237
         for (unsigned int i=0; i<Electrodes.size(); ++i) {
@@ -305,7 +262,7 @@ namespace Lemma {
305 262
     //       Class:  DCSurvey
306 263
     //      Method:  AddMeasurement
307 264
     //--------------------------------------------------------------------------------------
308
-    void DCSurvey::AddMeasurement ( const int& iJ, DCIPElectrode* M, DCIPElectrode* N  ) {
265
+    void DCSurvey::AddMeasurement ( const int& iJ, std::shared_ptr<DCIPElectrode> M, std::shared_ptr<DCIPElectrode> N  ) {
309 266
         bool fM = false;
310 267
         bool fN = false;
311 268
         for (unsigned int i=0; i<Electrodes.size(); ++i) {
@@ -335,8 +292,8 @@ namespace Lemma {
335 292
 
336 293
     void DCSurvey::AddMeasurement ( const int& iJ, const std::string& M, const std::string& N ) {
337 294
 
338
-        std::pair<DCIPElectrode*, int> Mp = ElectrodeLabelMap[M];
339
-        std::pair<DCIPElectrode*, int> Np = ElectrodeLabelMap[N];
295
+        std::pair< std::shared_ptr<DCIPElectrode>, int> Mp = ElectrodeLabelMap[M];
296
+        std::pair< std::shared_ptr<DCIPElectrode>, int> Np = ElectrodeLabelMap[N];
340 297
 
341 298
         if (Mp.first == NULL) {
342 299
             throw std::runtime_error( "Injection point M not found" );

+ 2
- 2
Modules/FDEM1D/include/FHTKey101.h Dosyayı Görüntüle

@@ -54,8 +54,8 @@ namespace Lemma {
54 54
         ~FHTKey101 ();
55 55
 
56 56
         /**
57
-         * @copybrief LemmaObject::New()
58
-         * @copydetails LemmaObject::New()
57
+         * \brief   returns shared_ptr with new object
58
+         * \details Use this method as default constructor is locked.
59 59
          */
60 60
         static std::shared_ptr<FHTKey101> NewSP();
61 61
 

+ 0
- 88
Modules/FDEM1D/include/GroundedElectricDipole.h Dosyayı Görüntüle

@@ -1,88 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API.
2
- * More information is available at http://lemmasoftware.org
3
- */
4
-
5
-/* This Source Code Form is subject to the terms of the Mozilla Public
6
- * License, v. 2.0. If a copy of the MPL was not distributed with this
7
- * file, You can obtain one at http://mozilla.org/MPL/2.0/.
8
- */
9
-
10
-/**
11
- * @file
12
- * @date      01/29/2014 06:59:39 AM
13
- * @version   $Id$
14
- * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
18
- */
19
-
20
-
21
-#ifndef  GROUNDEDELECTRICDIPOLE_INC
22
-#define  GROUNDEDELECTRICDIPOLE_INC
23
-
24
-#include "dipolesource.h"
25
-
26
-namespace Lemma {
27
-
28
-    /**
29
-      \ingroup FDEM1D
30
-      \brief   Grounded electric dipole
31
-      \details Used to model an idealised grounded electrid dipole of arbitrary
32
-               polarisation.
33
-     */
34
-    class GroundedElectricDipole : public DipoleSource {
35
-
36
-        friend std::ostream &operator<<(std::ostream &stream,
37
-                const GroundedElectricDipole &ob);
38
-
39
-        public:
40
-
41
-        // ====================  LIFECYCLE     =======================
42
-
43
-        /**
44
-         * @copybrief LemmaObject::New()
45
-         * @copydetails LemmaObject::New()
46
-         */
47
-        static GroundedElectricDipole* New();
48
-
49
-        /**
50
-         *  @copybrief   LemmaObject::Delete()
51
-         *  @copydetails LemmaObject::Delete()
52
-         */
53
-        void Delete();
54
-
55
-        // ====================  OPERATORS     =======================
56
-
57
-        // ====================  OPERATIONS    =======================
58
-
59
-        // ====================  ACCESS        =======================
60
-
61
-        // ====================  INQUIRY       =======================
62
-
63
-        protected:
64
-
65
-        // ====================  LIFECYCLE     =======================
66
-
67
-        /** Default protected constructor, use New */
68
-        GroundedElectricDipole (const std::string& name);
69
-
70
-        /** Default protected destructor, use Delete */
71
-        ~GroundedElectricDipole ();
72
-
73
-        /**
74
-         *  @copybrief   LemmaObject::Release()
75
-         *  @copydetails LemmaObject::Release()
76
-         */
77
-        void Release();
78
-
79
-        private:
80
-
81
-        // ====================  DATA MEMBERS  =========================
82
-
83
-    }; // -----  end of class  GroundedElectricDipole  -----
84
-
85
-}		// -----  end of Lemma  name  -----
86
-
87
-#endif   // ----- #ifndef GROUNDEDELECTRICDIPOLE_INC  -----
88
-

+ 0
- 1
Modules/FDEM1D/include/KernelEM1DBase.h Dosyayı Görüntüle

@@ -24,7 +24,6 @@ namespace Lemma {
24 24
     // ===================================================================
25 25
     //  Class:  KernelEM1DBase
26 26
     /**
27
-      @class
28 27
       \ingroup FDEM1D
29 28
       \brief   Pure virtual base class of KernelEm1D
30 29
       \details Defines interface for HankelTransform classes

+ 0
- 1
Modules/FDEM1D/include/KernelEM1DManager.h Dosyayı Görüntüle

@@ -25,7 +25,6 @@ namespace Lemma {
25 25
     // ===================================================================
26 26
     //  Class:  KernelEM1DManager
27 27
     /**
28
-      @class
29 28
       \ingroup FDEM1D
30 29
       \brief   Keeps track of Kernels for EM1D
31 30
       \details This class keeps track of the various types of kernel terms

+ 0
- 1
Modules/FDEM1D/include/KernelEM1DReflBase.h Dosyayı Görüntüle

@@ -29,7 +29,6 @@ namespace Lemma {
29 29
     // ===================================================================
30 30
     //  Class:  KernelEM1DReflBase
31 31
     /**
32
-      @class
33 32
       \ingroup FDEM1D
34 33
       \brief   Abstract class defining EM1DRefl class.
35 34
       \details Derived classes are template specialized for optimal performance.

+ 0
- 1
Modules/FDEM1D/include/KernelEM1DReflSpec.h Dosyayı Görüntüle

@@ -26,7 +26,6 @@ namespace Lemma {
26 26
     // ===================================================================
27 27
     //  Class:  KernelEM1DReflSpec
28 28
     /**
29
-      @class
30 29
       \ingroup FDEM1D
31 30
       \brief   Specialized version of KernelEM1DReflBase
32 31
       \details Through use of template specialisations, this KernelEm1D

+ 0
- 1
Modules/FDEM1D/include/KernelEM1DSpec.h Dosyayı Görüntüle

@@ -27,7 +27,6 @@ namespace Lemma {
27 27
     // ===================================================================
28 28
     //  Class:  KernelEM1DSpec
29 29
     /**
30
-      @class
31 30
       \ingroup FDEM1D
32 31
       \brief   Optimized version of KernelEm1D
33 32
       \details Through use of template specialisations, this KernelEm1D

+ 0
- 1
Modules/FDEM1D/include/MagneticDipole.h Dosyayı Görüntüle

@@ -25,7 +25,6 @@
25 25
 namespace Lemma {
26 26
 
27 27
 /**
28
-  @class
29 28
   \ingroup FDEM1D
30 29
   \brief   Magnetic Dipole
31 30
   \details Used to model an idealised magnetic dipole of arbitrary

+ 0
- 1
Modules/FDEM1D/include/digitalfilterintegrator.h Dosyayı Görüntüle

@@ -22,7 +22,6 @@ namespace Lemma {
22 22
     // ===================================================================
23 23
     //  Class:  DigitalFilterIntegrator
24 24
     /**
25
-      @class
26 25
       \brief   Reimplimentation of Walt Anderson's digital filtering
27 26
                algorithms which are public domain.
28 27
       \details Walt Anderson wrote several routines for digital filtering

+ 0
- 1
Modules/FDEM1D/include/integrationkernel.h Dosyayı Görüntüle

@@ -21,7 +21,6 @@ namespace Lemma {
21 21
     // ===================================================================
22 22
     //  Class:  IntegrationKernel
23 23
     /**
24
-      @class
25 24
       \brief    Abstract class that computes arguments for numerical
26 25
                 integrators.
27 26
       \details  Needs to provide Argument function, as well as be able to

+ 0
- 1
Modules/FDEM1D/include/inversesolver.h Dosyayı Görüntüle

@@ -25,7 +25,6 @@ namespace Lemma {
25 25
     // ===================================================================
26 26
     //  Class:  InverseSolver
27 27
     /**
28
-      @class  InverseSolver
29 28
       \brief   Abstract class for inverse problem solver.
30 29
       \details General solution of inverse problems.
31 30
      */

+ 0
- 1
Modules/FDEM1D/include/sintransintegrationkernel.h Dosyayı Görüntüle

@@ -21,7 +21,6 @@ namespace Lemma {
21 21
     // ===================================================================
22 22
     //  Class:  SinTransIntegrationKernel
23 23
     /**
24
-      @class
25 24
       \brief    Integration kernel for testing sinine transform.
26 25
       \details  Evaluates sinine at the argument, using lagged convolution.
27 26
                 all of these kernels have exact solutions.

+ 0
- 85
Modules/FDEM1D/src/GroundedElectricDipole.cpp Dosyayı Görüntüle

@@ -1,85 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API.
2
- * More information is available at http://lemmasoftware.org
3
- */
4
-
5
-/* This Source Code Form is subject to the terms of the Mozilla Public
6
- * License, v. 2.0. If a copy of the MPL was not distributed with this
7
- * file, You can obtain one at http://mozilla.org/MPL/2.0/.
8
- */
9
-
10
-/**
11
- * @file
12
- * @date      01/29/2014 07:05:13 AM
13
- * @version   $Id$
14
- * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
18
- */
19
-
20
-#include "GroundedElectricDipole.h"
21
-
22
-
23
-namespace Lemma {
24
-
25
-    // ====================  FRIEND METHODS  =====================
26
-
27
-    std::ostream &operator<<(std::ostream &stream, const GroundedElectricDipole &ob) {
28
-
29
-        stream << *(DipoleSource*)(&ob);
30
-
31
-        return stream;
32
-    }
33
-
34
-    // ====================  LIFECYCLE     =======================
35
-
36
-    //--------------------------------------------------------------------------------------
37
-    //       Class:  GroundedElectricDipole
38
-    //      Method:  GroundedElectricDipole
39
-    // Description:  constructor (protected)
40
-    //--------------------------------------------------------------------------------------
41
-    GroundedElectricDipole::GroundedElectricDipole (const std::string& name) : DipoleSource(name) {
42
-
43
-    }  // -----  end of method GroundedElectricDipole::GroundedElectricDipole  (constructor)  -----
44
-
45
-
46
-    //--------------------------------------------------------------------------------------
47
-    //       Class:  GroundedElectricDipole
48
-    //      Method:  New()
49
-    // Description:  public constructor
50
-    //--------------------------------------------------------------------------------------
51
-    GroundedElectricDipole* GroundedElectricDipole::New() {
52
-        GroundedElectricDipole*  Obj = new GroundedElectricDipole("GroundedElectricDipole");
53
-        Obj->AttachTo(Obj);
54
-        return Obj;
55
-    }
56
-
57
-    //--------------------------------------------------------------------------------------
58
-    //       Class:  GroundedElectricDipole
59
-    //      Method:  ~GroundedElectricDipole
60
-    // Description:  destructor (protected)
61
-    //--------------------------------------------------------------------------------------
62
-    GroundedElectricDipole::~GroundedElectricDipole () {
63
-
64
-    }  // -----  end of method GroundedElectricDipole::~GroundedElectricDipole  (destructor)  -----
65
-
66
-    //--------------------------------------------------------------------------------------
67
-    //       Class:  GroundedElectricDipole
68
-    //      Method:  Delete
69
-    // Description:  public destructor
70
-    //--------------------------------------------------------------------------------------
71
-    void GroundedElectricDipole::Delete() {
72
-        this->DetachFrom(this);
73
-    }
74
-
75
-    //--------------------------------------------------------------------------------------
76
-    //       Class:  GroundedElectricDipole
77
-    //      Method:  Release
78
-    // Description:  destructor (protected)
79
-    //--------------------------------------------------------------------------------------
80
-    void GroundedElectricDipole::Release() {
81
-        delete this;
82
-    }
83
-
84
-}		// -----  end of Lemma  name  -----
85
-

+ 0
- 342
Modules/LemmaCore/examples/utORS.cpp Dosyayı Görüntüle

@@ -1,342 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  utdipolesource.cpp
4
-//
5
-//    Description:
6
-//
7
-//        Version:  0.0
8
-//        Created:  12/02/2009 11:57:14 AM
9
-//       Revision:  none
10
-//       Compiler:  g++ (c++)
11
-//
12
-//         Author:  Trevor Irons (ti)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  United States Geological Survey (USGS)
16
-//
17
-//          Email:  tirons@mines.edu, tirons@usgs.gov
18
-//
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include <iostream>
35
-#include <fstream>
36
-
37
-#include "dipolesource.h"
38
-#include "layeredearth.h"
39
-#include "receiverpoints.h"
40
-#include "emearth1d.h"
41
-#include "WireAntenna.h"
42
-#include "PolygonalWireAntenna.h"
43
-
44
-#if  LEMMAUSEVTK
45
-#include "vtkRenderer.h"
46
-#include "vtkRenderWindow.h"
47
-#include "vtkRenderWindowInteractor.h"
48
-#include "vtkRenderLargeImage.h"
49
-#include "vtkPNGWriter.h"
50
-#include "vtkRectilinearGrid.h"
51
-#include "vtkXMLRectilinearGridWriter.h"
52
-#include "vtkDoubleArray.h"
53
-#include "vtkFieldData.h"
54
-#include "vtkCellData.h"
55
-#endif     // -----  not LEMMA_USE_VTK  -----
56
-
57
-// For testing purposes disable VTK and run scale.sh
58
-//#undef LEMMAUSEVTK
59
-
60
-#include "timer.h"
61
-
62
-using namespace Lemma;
63
-
64
-double randDouble(double low, double high) {
65
-	//srand(time(0));
66
-	double temp;
67
-	/* swap low & high around if the user makes no sense */
68
-	if (low > high)	{
69
-	temp = low;
70
-	low = high;
71
-	high = temp;
72
-	}
73
-	/* calculate the random number & return it */
74
-	temp = (rand() / (static_cast<double>(RAND_MAX) + 1.0))
75
-	* (high - low) + low;
76
-	return temp;
77
-}
78
-
79
-
80
-int main() {
81
-
82
-	// Keep track of time
83
-	jsw_timer timer;
84
-
85
-
86
-	srand(time(0));
87
-
88
-	PolygonalWireAntenna *pa = PolygonalWireAntenna::New();
89
-	pa->SetNumberOfFrequencies(1);
90
-	pa->SetFrequency(0, 540000);
91
-    Real Depth  =   370;  // nominal depth
92
-    Real Width  = 0.14;  // transmitter height
93
-    Real Height = 0.70;//  .14;  //.014;  // transmitter width
94
-
95
-
96
-	pa->SetNumberOfPoints(5);
97
-    /*
98
-    pa->SetPoint(0, Vector3r(       0,       0, Depth));
99
-	pa->SetPoint(1, Vector3r(       0,       0, Depth+Height));
100
-	pa->SetPoint(2, Vector3r(       0,   Width, Depth+Height));
101
-	pa->SetPoint(3, Vector3r(       0,   Width, Depth));
102
-	pa->SetPoint(4, Vector3r(       0,       0, Depth));
103
-    */
104
-
105
-    pa->SetPoint(0, Vector3r(   -Width/2., -Height/2., Depth));
106
-	pa->SetPoint(1, Vector3r(    Width/2., -Height/2., Depth));
107
-	pa->SetPoint(2, Vector3r(    Width/2.,  Height/2., Depth));
108
-	pa->SetPoint(3, Vector3r(   -Width/2.,  Height/2., Depth));
109
-	pa->SetPoint(4, Vector3r(   -Width/2., -Height/2., Depth));
110
-
111
-	pa->SetCurrent(1.);
112
-    pa->SetNumberOfTurns(6);
113
-	//Vector3r rp = Vector3r::Random(3);
114
-	//rp << 150., 10, 0.;
115
-	//rp << -27.1456, 15.2350, -1e-3;
116
-	//rp << randDouble(-35,35), randDouble(-35,35), randDouble(-35,35);
117
-	//rp << 3.22806, -13.1548, 14.9695;
118
-	//rp.setRandom(3);
119
-	//std::cout <<  "rp " << rp.transpose() << std::endl;
120
-	//pa->ApproximateWithElectricDipoles(rp);
121
-
122
-
123
-	// Define model
124
-    Real Sigma = 1.0/20. ; // .05;
125
-	VectorXcr sigma(2);
126
-		sigma << Complex(0.,0), Complex(Sigma,0);
127
-	VectorXr  thick(1);
128
-		thick << 10;
129
-	LayeredEarthEM *earth = LayeredEarthEM::New();
130
-		earth->SetNumberOfLayers(2);
131
-		earth->SetLayerConductivity(sigma);
132
-		//earth->SetLayerThickness(thick);
133
-
134
-	// Receivers
135
-	ReceiverPoints *receivers = ReceiverPoints::New();
136
-		Vector3r loc;
137
-		Real ox    =    -5.*Width - .003373;
138
-		Real oy    =    -3.*Height - .003373;
139
-		Real oz    =    Depth - Height/2. - .003373;
140
-		int nx     =   120; // 60;
141
-		int ny     =   180; //  50;
142
-		int nz     =   100; // 40;
143
-		Real hx    =    11.*Width/nx;
144
-		Real hy    =     7.*Height/ny;
145
-		Real hz    =     1.*Height/nz;
146
-
147
-        receivers->SetNumberOfReceivers(nx*ny*nz);
148
-		int ir = 0;
149
-		for (int iz=0; iz<nz; ++iz) {
150
-		for (int iy=0; iy<ny; ++iy) {
151
-		for (int ix=0; ix<nx; ++ix) {
152
-			loc << ox+ix*hx, oy+iy*hy, oz+iz*hz;
153
-			receivers->SetLocation(ir, loc);
154
-			++ ir;
155
-		}
156
-        }
157
-        }
158
-
159
-	// EmEarth
160
-	EMEarth1D  *EmEarth = EMEarth1D::New();
161
-		//EmEarth->AttachWireAntenna(wire);
162
-		EmEarth->AttachWireAntenna(pa);
163
-		EmEarth->AttachLayeredEarthEM(earth);
164
-		EmEarth->AttachReceiverPoints(receivers);
165
-		EmEarth->SetFieldsToCalculate(E);
166
-        //EmEarth->SetHankelTransformMethod(GAUSSIANQUADRATURE);
167
-        EmEarth->SetHankelTransformMethod(ANDERSON801);
168
-
169
-	// Do calculation
170
-	timer.begin();
171
-	EmEarth->CalculateWireAntennaFields();
172
-	Real paTime = timer.end();
173
-	std::cout << "Polygonal wire antennae time: " << paTime << "\n";
174
-
175
-	//EmEarth->AttachWireAntenna(wire);
176
-	//timer.begin();
177
-	//EmEarth->CalculateWireAntennaFields();
178
-	//Real waTime = timer.end();
179
-	//std::cout << "Fixed wire antennae time: " << waTime << "\n";
180
-/*
181
-	depth = depth2;
182
-	std::fstream real("reale_lay.dat", std::ios::out);
183
-	std::fstream imag("image_lay.dat", std::ios::out);
184
-	for (int iz=0; iz<nz; ++iz) {
185
-		Vector3cr temp = receivers->GetEfield(0,iz);
186
-		real << ox << "\t" << oy << "\t" << depth << "\t"
187
-				<< temp(0).real() << "\t" << temp(1).real()
188
-				<< "\t" << temp(2).real() << std::endl;
189
-		imag << ox << "\t" << oy << "\t" << depth << "\t"
190
-				<< std::imag(temp(0)) << "\t" << std::imag(temp(1))
191
-				<< "\t" << std::imag(temp(2)) << std::endl;
192
-		depth += dx;
193
-	}
194
-	real.close();
195
-	imag.close();
196
-*/
197
-
198
-	//wire->Delete();
199
-#if  LEMMAUSEVTK
200
-
201
-    // Set Coordinates
202
-    vtkDoubleArray *xCoords = vtkDoubleArray::New();
203
-    xCoords->InsertNextValue(ox-hx/2.);
204
-    double xm1 = ox-hx/2.;
205
-    for (int ix=0; ix<nx; ix++) {
206
-        xCoords->InsertNextValue(xm1 + hx);
207
-        xm1 += hx;
208
-    }
209
-
210
-    vtkDoubleArray *yCoords = vtkDoubleArray::New();
211
-    yCoords->InsertNextValue(oy-hy/2.);
212
-    double ym1 = oy-hy/2.;
213
-    for (int iy=0; iy<ny; iy++) {
214
-        yCoords->InsertNextValue(ym1 + hy);
215
-        ym1 += hy;
216
-    }
217
-
218
-    vtkDoubleArray *zCoords = vtkDoubleArray::New();
219
-    zCoords->InsertNextValue(oz-hz/2.);
220
-    double zm1 = oz-hz/2.;
221
-    for (int iz=0; iz<nz; iz++) {
222
-        zCoords->InsertNextValue(zm1 + hz);
223
-        zm1 += hz;
224
-    }
225
-
226
-    vtkDoubleArray *EReal = vtkDoubleArray::New();
227
-    vtkDoubleArray *EImag = vtkDoubleArray::New();
228
-    vtkDoubleArray *Watts = vtkDoubleArray::New();
229
-    EReal->SetNumberOfComponents(3);
230
-    EImag->SetNumberOfComponents(3);
231
-    Watts->SetNumberOfComponents(1);
232
-
233
-    ir = 0;
234
-    Real WattsTotal(0);
235
-    Real WattsInterior(0);
236
-    for (int iz=0; iz<nz; ++iz) {
237
-    for (int iy=0; iy<ny; ++iy) {
238
-    for (int ix=0; ix<nx; ++ix) {
239
-        //sigmaArray->InsertTuple1(i,  sigma[ix][iy][iz] );
240
-		Vector3cr E = receivers->GetEfield(0, ir);
241
-        EReal-> InsertTuple3(ir, real(E(0)), real(E(1)), real(E(2)));
242
-        EImag-> InsertTuple3(ir, imag(E(0)), imag(E(1)), imag(E(2)));
243
-        //std::cout << std::abs(ox+ix*hx) << "\t"  <<  Width/2. << endl; // && std::abs(oy+iy*hy) > Height/2. ) { // && std::abs(oz+iz*hz - Depth) > Width/2. ) {
244
-        //if ( std::abs( ox+ix*hx ) < Width/2. && std::abs(oy+iy*hy) < Height/2. && std::abs(oz+iz*hz - Depth) < Width/2. ) {
245
-        if ( std::sqrt( std::pow(ox+ix*hx,2)  + std::pow(oz+iz*hz - Depth, 2) ) < .085 && std::abs(oy+iy*hy) < Height/2. ) {
246
-            Watts-> InsertTuple1(ir,  1e-20 );
247
-            WattsInterior += .5*  (( pow((std::abs(E(0)) + std::abs(E(1)) + std::abs(E(2))), 2)*Sigma)*hx*hy*hz );
248
-        } else {
249
-            Watts-> InsertTuple1(ir, .5* (pow( (std::abs(E(0)) + std::abs(E(1)) + std::abs(E(2))), 2)*Sigma)*hx*hy*hz );
250
-            //Watts-> InsertTuple1(ir,  1e-20 );
251
-            WattsTotal += .5*  (( pow((std::abs(E(0)) + std::abs(E(1)) + std::abs(E(2))), 2)*Sigma)*hx*hy*hz );
252
-        }
253
-		++ ir;
254
-    }
255
-    }
256
-    }
257
-    std::cout << "Total Power: " << Sigma << "\t" << WattsTotal << "\t" << WattsInterior << endl;
258
-
259
-    EReal->SetName("E_real");
260
-    EImag->SetName("E_imag");
261
-    Watts->SetName("Power");
262
-
263
-    vtkRectilinearGrid *rgrid = vtkRectilinearGrid::New();
264
-        rgrid->SetDimensions(nx+1,ny+1,nz+1);
265
-        rgrid->SetXCoordinates(xCoords);
266
-        rgrid->SetYCoordinates(yCoords);
267
-        rgrid->SetZCoordinates(zCoords);
268
-
269
-        rgrid->GetCellData()->AddArray(EReal);
270
-        rgrid->GetCellData()->AddArray(EImag);
271
-        rgrid->GetCellData()->AddArray(Watts);
272
-        //rgrid->Update();
273
-
274
-    vtkXMLRectilinearGridWriter *gridWrite = vtkXMLRectilinearGridWriter::New();
275
-        gridWrite->SetInputData(rgrid);
276
-        gridWrite->SetFileName("ors.vtr");
277
-        gridWrite->Write();
278
-        //gridWrite->Update();
279
-
280
-#endif
281
-	EmEarth->Delete();
282
-	receivers->Delete();
283
-	earth->Delete();
284
-
285
-#if  LEMMAUSEVTKX
286
-	// Create the usual rendering stuff.
287
-	vtkRenderer           *renderer = vtkRenderer::New();
288
-	vtkRenderWindow         *renWin = vtkRenderWindow::New();
289
-	vtkRenderWindowInteractor *iren = vtkRenderWindowInteractor::New();
290
-
291
-	std::cout << "wire antennae approximating " << std::endl;
292
-	loc << 0, .5*Width, Depth+.5*Height;
293
-	pa->ApproximateWithElectricDipoles(loc);
294
-    std::cout <<  "Wire approximated with " << pa->GetNumberOfDipoles() << std::endl;
295
-
296
-    vtkActor **pdipActors = new vtkActor*[pa->GetNumberOfDipoles()];
297
-	for (int id=0; id<pa->GetNumberOfDipoles(); ++id) {
298
-		pdipActors[id] = pa->GetVtkActor(id);
299
-		renderer->AddActor(pdipActors[id]);
300
-	}
301
-
302
-    /*
303
-    vtkActor **dipActors = new vtkActor*[wire->GetNumberOfDipoles()];
304
-	for (int id=0; id<wire->GetNumberOfDipoles(); ++id) {
305
-		dipActors[id] = wire->GetVtkActor(id);
306
-		renderer->AddActor(dipActors[id]);
307
-	}
308
-    */
309
-
310
-	renderer->SetBackground(1,1,1);
311
-
312
-	// Render the window
313
-	renWin->AddRenderer(renderer);
314
-	renWin->SetWindowName("Wire antennae");
315
-
316
-	iren->SetRenderWindow(renWin);
317
-	iren->Initialize();
318
-	iren->Start();
319
-	iren->Render();
320
-
321
-    #if 0
322
-	cout << "Enter File name?: ";
323
-	std::string pngName;
324
-	std::cin >> pngName;
325
-	vtkPNGWriter *pngwrite = vtkPNGWriter::New();
326
-	vtkRenderLargeImage *renlarge = vtkRenderLargeImage::New();
327
-	renlarge->SetInput(renderer);
328
-	renlarge->SetMagnification(2);
329
-	pngwrite->SetInputConnection(renlarge->GetOutputPort());
330
-	pngName.append(".png");
331
-	pngwrite->SetFileName(pngName.c_str());
332
-	pngwrite->Write();
333
-    #endif
334
-
335
-#endif     // -----  not LEMMA_USE_VTK  -----
336
-
337
-
338
-	//std::cout << *pa << std::endl;
339
-	//pa->Delete();
340
-
341
-	return 0;
342
-}

+ 0
- 34
Modules/LemmaCore/examples/utQWEKey.cpp Dosyayı Görüntüle

@@ -1,34 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API.
2
- * More information is available at http://lemmasoftware.org
3
- */
4
-
5
-/* This Source Code Form is subject to the terms of the Mozilla Public
6
- * License, v. 2.0. If a copy of the MPL was not distributed with this
7
- * file, You can obtain one at http://mozilla.org/MPL/2.0/.
8
- */
9
-
10
-/**
11
- * @file
12
- * @date      02/12/2014 01:01:29 PM
13
- * @version   $Id$
14
- * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
18
- */
19
-
20
-#include "QWEKey.h"
21
-using namespace Lemma;
22
-
23
-int main() {
24
-
25
-    // TODO chech
26
-
27
-    QWEKey* QWE = QWEKey::New();
28
-    QWE->TestPrivate( 5 );
29
-    QWE->Delete();
30
-
31
-    return 0;
32
-}
33
-
34
-

+ 0
- 86
Modules/LemmaCore/examples/utSerialize.cpp Dosyayı Görüntüle

@@ -1,86 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API.
2
- * More information is available at http://lemmasoftware.org
3
- */
4
-
5
-/* This Source Code Form is subject to the terms of the Mozilla Public
6
- * License, v. 2.0. If a copy of the MPL was not distributed with this
7
- * file, You can obtain one at http://mozilla.org/MPL/2.0/.
8
- */
9
-
10
-/**
11
- * @file
12
- * @date      09/29/2014 01:31:26 PM
13
- * @version   $Id$
14
- * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
18
- */
19
-
20
-#include "Lemma"
21
-
22
-using namespace Lemma;
23
-
24
-#ifdef  HAVE_YAMLCPP
25
-#include "yaml-cpp/yaml.h"
26
-
27
-int main() {
28
-
29
-    std::ofstream ofstr("output.yaml");
30
-    //ofstr << "%YAML 1.2\n" << "---\n";
31
-    //ofstr << "LEMMA_CLASSES:\n";
32
-
33
-    // This works for individual classes or even groups of unrelated classes. But
34
-    // How should references work? One option would be to hack YAML and allow for references
35
-    // across 'Docs'. This is maybe undesireable, as then it's not valid YAML anymore.
36
-    // OR we could have some other kind of IDENTIFIER that could be used and Connections could be
37
-    // made AFTER the whole file is processed?
38
-
39
-    // Alternative is each class is written to it's own file. And then implicit on the Serialize function, the file tags are written
40
-    // into the YAML instead of the pointer. Alternatively, tags could do this too.
41
-
42
-    // Or file could be saved as pointer.yaml
43
-
44
-    // *
45
-    // * Or a file contains all the subclasses it point to. So that it's self-enclosed. This is nice as it's quite
46
-    // * flexible. The only downwside is possible repeat of classes. Basically if the API is careful though, only 1
47
-    // * instance will need to be serialized.
48
-    // *
49
-
50
-
51
-    TEMTransmitter* Seq = TEMTransmitter::New();
52
-        Seq->SetRepFrequency( 20, KHZ );
53
-        VectorXr Times (18);
54
-        VectorXr Amps (18);
55
-        Times << 0.0, 0.03051, 0.10267, 0.19408, 0.19889, 0.21332, 0.74249, 1.3775, 1.83452, 2.52245, \
56
-                3.191132, 3.9031135, 4.0, 4.00484486, 4.123904, 4.200182, 4.20732, 4.212946;
57
-        Amps << 0.0, 14.71872, 62.34372, 114.84372, 117.84372, 118.96872, 118.96872, 118.96872, 118.96872,\
58
-                118.59372, 119.34372, 120.0, 120.0, 117.94176, 47.60364, 0.8905848, 0.1203888, 0.0;
59
-        Seq->SetWaveform(Times, Amps, MILLISEC);
60
-    // OK dump to disk
61
-    ofstr << *Seq ;
62
-    ofstr.close();
63
-    Seq->Delete();
64
-
65
-
66
-    // OK now load
67
-    std::ifstream ifstr("output.yaml");
68
-    std::vector<YAML::Node> nodes = YAML::LoadAll(ifstr);
69
-
70
-    TEMTransmitter* Seq2 = TEMTransmitter::DeSerialize( nodes[0] );
71
-    std::cout << "Loaded\n" << *Seq2;
72
-    Seq2->Delete();
73
-    ifstr.close();
74
-
75
-    //YAML::Node nodes = YAML::LoadFile("output.yaml");
76
-    //std::cout << nodes[0] << std::endl;
77
-    //std::cout << nodes[1] << std::endl;
78
-
79
-    exit(EXIT_SUCCESS);
80
-}
81
-
82
-#else
83
-int main() {
84
-
85
-}
86
-#endif

+ 0
- 197
Modules/LemmaCore/examples/utTEMSurvey.cpp Dosyayı Görüntüle

@@ -1,197 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API.
2
- * More information is available at http://lemmasoftware.org
3
- */
4
-
5
-/* This Source Code Form is subject to the terms of the Mozilla Public
6
- * License, v. 2.0. If a copy of the MPL was not distributed with this
7
- * file, You can obtain one at http://mozilla.org/MPL/2.0/.
8
- */
9
-
10
-/**
11
- * @file
12
- * @date      10/06/2014 10:37:30 AM
13
- * @version   $Id$
14
- * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
18
- */
19
-
20
-#include "Lemma"
21
-using namespace Lemma;
22
-
23
-int main() {
24
-
25
-    // Each pulse sequence functions as an autonomous transmitter. A record may contain multiple transmitters (moments).
26
-    // There is some small overhead for wire loop locations, but generality is retained doing this, as well as monitoring of
27
-    // slight changes in geometry for both pulses.
28
-    TEMTransmitter* TxHM = TEMTransmitter::New();
29
-        TxHM->SetRepFrequency( 20, KHZ );
30
-        VectorXr Times (18);
31
-        VectorXr Amps (18);
32
-        Times << 0.0, 0.03051, 0.10267, 0.19408, 0.19889, 0.21332, 0.74249, 1.3775, 1.83452, 2.52245, \
33
-                3.191132, 3.9031135, 4.0, 4.00484486, 4.123904, 4.200182, 4.20732, 4.212946;
34
-        Amps << 0.0, 14.71872, 62.34372, 114.84372, 117.84372, 118.96872, 118.96872, 118.96872, 118.96872,\
35
-                118.59372, 119.34372, 120.0, 120.0, 117.94176, 47.60364, 0.8905848, 0.1203888, 0.0;
36
-        TxHM->SetWaveform( Times, Amps, MILLISEC );
37
-        // Define wire loop
38
-        TxHM->SetNumberOfPoints(8);
39
-        TxHM->SetPoint(0, Vector3r( -16.10,    2.13,  -34));
40
-        TxHM->SetPoint(1, Vector3r(  -7.51,   10.72,  -34));
41
-        TxHM->SetPoint(2, Vector3r(   7.51,   10.72,  -34));
42
-        TxHM->SetPoint(3, Vector3r(  14.92,    3.31,  -34));
43
-        TxHM->SetPoint(4, Vector3r(  14.92,   -3.31,  -34));
44
-        TxHM->SetPoint(5, Vector3r(   7.51,  -10.72,  -34));
45
-        TxHM->SetPoint(6, Vector3r(  -7.51,  -10.72,  -34));
46
-        TxHM->SetPoint(7, Vector3r( -16.10,   -2.13,  -34));
47
-        TxHM->SetNumberOfTurns(8);
48
-
49
-    // Each Transmitter needs its own `Receiver(s)', the only difference may be the time gates, but that's OK.
50
-    //     It's a minor amount of overhead for greatly improved genearality. As sometimes different gates are
51
-    //     masked.
52
-    TEMInductiveReceiver* RxHM = TEMInductiveReceiver::New();
53
-        RxHM->SetComponent( ZCOMPONENT );      // What about Overloaded to take (X), (X,Y), or (X,Y,Z) or what about tilt?
54
-        RxHM->SetMoment( 1 );                  // Normalized
55
-        RxHM->SetReferenceTime( 4., MILLISEC );
56
-        RxHM->SetRxLocation( (Vector3r() << -16.80, 0, -36.00).finished() );
57
-
58
-        // Gate Centres  ms
59
-        VectorXr centres (37);
60
-        centres << 7.15000000e-04,   2.21500000e-03,   4.21500000e-03,   6.21500000e-03,
61
-                   8.21500000e-03,   1.02150000e-02,   1.22150000e-02,   1.47150000e-02,
62
-                   1.82150000e-02,   2.27150000e-02,   2.82150000e-02,   3.52150000e-02,
63
-                   4.42150000e-02,   5.57150000e-02,   7.02150000e-02,   8.82150000e-02,
64
-                   1.10715000e-01,   1.38715000e-01,   1.74215000e-01,   2.19715000e-01,
65
-                   2.76715000e-01,   3.48715000e-01,   4.39715000e-01,   5.53715000e-01,
66
-                   6.97715000e-01,   8.79215000e-01,   1.10771500e+00,   1.39621500e+00,
67
-                   1.76021500e+00,   2.21871500e+00,   2.79671500e+00,   3.52571500e+00,
68
-                   4.44471500e+00,   5.60321500e+00,   7.06321500e+00,   8.90421500e+00,
69
-                   1.10667200e+01;
70
-        //centres.array() += 4.;
71
-
72
-        // Gate Widths  ms
73
-        VectorXr widths (37);
74
-        widths <<   4.30000000e-04,   1.43000000e-03,   3.43000000e-03,   5.43000000e-03,
75
-                    7.43000000e-03,   9.43000000e-03,   1.14300000e-02,   1.34300000e-02,
76
-                    1.64300000e-02,   2.04300000e-02,   2.54300000e-02,   3.14300000e-02,
77
-                    3.94300000e-02,   4.94300000e-02,   6.24300000e-02,   7.84300000e-02,
78
-                    9.84300000e-02,   1.23430000e-01,   1.54430000e-01,   1.94430000e-01,
79
-                    2.45430000e-01,   3.08430000e-01,   3.89430000e-01,   4.90430000e-01,
80
-                    6.17430000e-01,   7.78430000e-01,   9.80430000e-01,   1.23543000e+00,
81
-                    1.55743000e+00,   1.96343000e+00,   2.47443000e+00,   3.11943000e+00,
82
-                    3.93243000e+00,   4.95743000e+00,   6.24943000e+00,   7.87743000e+00,
83
-                    9.93143000e+00;
84
-
85
-        RxHM->SetWindows(centres, widths, MILLISEC);
86
-
87
-    TEMTransmitter* TxLM = TEMTransmitter::New();
88
-        TxLM->SetRepFrequency( 20, KHZ );
89
-        VectorXr TimesLM (18);
90
-        VectorXr AmpsLM (18);
91
-
92
-        TimesLM << -8.00000E-004, -7.86965E-004, -7.66493E-004, -7.23688E-004,
93
-                   -6.39938E-004, -5.16174E-004, -3.93340E-004, -2.63993E-004,
94
-                   -1.43952E-004, -7.15990E-006, -2.50712E-006,  0.00000E+000,
95
-                    2.19597E-007,  1.47193E-006,  3.34398E-006,  4.68669E-006,
96
-                    5.96484E-006,  7.04934E-006;
97
-        TimesLM.array() = TimesLM.array() + 8e-4;  // Valgrind Hack += yields error. Correct for SkyTEM convention
98
-
99
-
100
-        AmpsLM <<  0.00000E+000,  3.67188E-002,  6.17188E-002,  1.17969E-001,
101
-                   2.14844E-001,  3.28906E-001,	 4.75781E-001,  6.30469E-001,
102
-                   7.82031E-001,  9.92969E-001,	 1.00000E+000,  1.00000E+000,
103
-                   9.63459E-001,  6.01030E-001,  2.29652E-001,  8.64702E-002,
104
-                   2.53196E-002,  0.00000E+000;
105
-        AmpsLM.array() = AmpsLM.array() * 8.;   // Also correct for SkyTEM convention in .geo file
106
-
107
-        TxLM->SetWaveform( TimesLM, AmpsLM, SEC );
108
-        // Define wire loop
109
-        TxLM->SetNumberOfPoints(8);
110
-        TxLM->SetPoint(0, Vector3r( -16.10,    2.13,  -34));
111
-        TxLM->SetPoint(1, Vector3r(  -7.51,   10.72,  -34));
112
-        TxLM->SetPoint(2, Vector3r(   7.51,   10.72,  -34));
113
-        TxLM->SetPoint(3, Vector3r(  14.92,    3.31,  -34));
114
-        TxLM->SetPoint(4, Vector3r(  14.92,   -3.31,  -34));
115
-        TxLM->SetPoint(5, Vector3r(   7.51,  -10.72,  -34));
116
-        TxLM->SetPoint(6, Vector3r(  -7.51,  -10.72,  -34));
117
-        TxLM->SetPoint(7, Vector3r( -16.10,   -2.13,  -34));
118
-        TxLM->SetNumberOfTurns(8);
119
-
120
-
121
-    TEMInductiveReceiver* RxLM = TEMInductiveReceiver::New();
122
-        RxLM->SetComponent( ZCOMPONENT );      // What about Overloaded to take (X), (X,Y), or (X,Y,Z) or what about tilt?
123
-        RxLM->SetMoment( 1 );                  // Normalized
124
-        RxLM->SetReferenceTime( 8e-4, SEC );
125
-        RxLM->SetRxLocation( (Vector3r() << -16.80, 0, -36.00).finished() );
126
-
127
-        // Gate Centres  ms
128
-        VectorXr centresLM (26);
129
-            centresLM << 7.150000E-07, 2.215000E-06, 4.215000E-06, 6.215000E-06, 8.215000E-06,
130
-                         1.021500E-05, 1.221500E-05, 1.471500E-05, 1.821500E-05, 2.271500E-05,
131
-                         2.821500E-05, 3.521500E-05, 4.421500E-05, 5.571500E-05, 7.021500E-05,
132
-                         8.821500E-05, 1.107150E-04, 1.387150E-04, 1.742150E-04, 2.197150E-04,
133
-                         2.767150E-04, 3.487150E-04, 4.397150E-04, 5.537150E-04, 6.977150E-04,
134
-                         8.792150E-04;
135
-
136
-        VectorXr widthsLM (26);
137
-            widthsLM << 5.700000E-07, 1.570000E-06, 1.570000E-06, 1.570000E-06, 1.570000E-06,
138
-                        1.570000E-06, 1.570000E-06, 2.570000E-06, 3.570000E-06, 4.570000E-06,
139
-                        5.570000E-06, 7.570000E-06, 9.570000E-06, 1.257000E-05, 1.557000E-05,
140
-                        1.957000E-05, 2.457000E-05, 3.057000E-05, 3.957000E-05, 5.057000E-05,
141
-                        6.257000E-05, 8.057000E-05, 1.005700E-04, 1.265700E-04, 1.605700E-04,
142
-                        2.015700E-04;
143
-
144
-        RxLM->SetWindows(centresLM, widthsLM, SEC);
145
-
146
-
147
-
148
-    // Specifies survey, this is the Glue Class, the top of the structure, etc.
149
-    TEMSurvey* Survey = TEMSurvey::New();
150
-        Survey->SetNumberOfLines(1);  // Flight lines or
151
-                                      // Internally each line is a class? But that's sort of hidden to the
152
-                                      // end user. Having each line seperate is nice for constrained inversion, where
153
-                                      // each line is a nice thing to deal with.
154
-        Survey->GetLine(0)->SetNumberOfRecords(1);    // Each Record then contains everything needed for modelling response curve(s)
155
-        Survey->GetLine(0)->GetRecord(0)->SetNumberOfPulseSequences( 1 );
156
-        Survey->GetLine(0)->GetRecord(0)->SetTransmitterReceiverPair( 0, TxHM, RxHM );
157
-        //Survey->GetLine(0)->GetRecord(0)->SetTransmitterReceiverPair( 1, TxHM, RxHM );
158
-
159
-
160
-    LayeredEarthEM* Earth = LayeredEarthEM::New();
161
-        Earth->SetNumberOfLayers(31);
162
-        Earth->SetLayerThickness( (VectorXr(29) <<  5.00E+00,  5.40E+00,
163
-             5.80E+00, 6.30E+00, 6.80E+00, 7.30E+00, 7.80E+00, 8.50E+00,
164
-             9.10E+00, 9.80E+00, 1.06E+01, 1.14E+01, 1.23E+01, 1.33E+01,
165
-             1.43E+01, 1.54E+01, 1.66E+01, 1.79E+01, 1.93E+01, 2.08E+01,
166
-             2.25E+01, 2.42E+01, 2.61E+01, 2.81E+01, 3.03E+01, 3.27E+01,
167
-             3.52E+01, 3.80E+01, 4.10E+01).finished() );
168
-
169
-        VectorXcr rho = ( (VectorXcr(31) << 0, 1.54E+01, 4.21E+01,
170
-            9.25E+01, 1.26E+02, 1.17E+02, 7.57E+01, 3.21E+01, 1.40E+01, 1.96E+01,
171
-            2.67E+01, 2.56E+01, 2.00E+01, 1.86E+01, 2.31E+01, 2.97E+01, 3.50E+01,
172
-            3.79E+01, 3.75E+01, 3.32E+01, 2.52E+01, 1.57E+01, 8.38E+00, 5.38E+00,
173
-            5.49E+00, 6.34E+00, 7.07E+00, 7.81E+00, 8.67E+00, 9.59E+00, 1.05E+01
174
-        ).finished() ); // 200 Ohm-m half space
175
-
176
-        Earth->SetLayerConductivity( 1./rho.array() );
177
-        // ALL SET UP
178
-        std::cout << *Survey << std::endl;
179
-
180
-        // OK do your thinc
181
-        //DataTEM* data =
182
-        Survey->ForwardModel( Earth );
183
-
184
-
185
-    // Clean up
186
-
187
-
188
-
189
-//     //Survey->Delete();
190
-//     Earth->Delete();
191
-//
192
-//     TxHM->Delete();
193
-//     RxHM->Delete();
194
-//     TxLM->Delete();
195
-//     RxLM->Delete();
196
-
197
-}

+ 0
- 168
Modules/LemmaCore/examples/utXMLParse.cpp Dosyayı Görüntüle

@@ -1,168 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API.
2
- * More information is available at http://lemmasoftware.org
3
- */
4
-
5
-/* This Source Code Form is subject to the terms of the Mozilla Public
6
- * License, v. 2.0. If a copy of the MPL was not distributed with this
7
- * file, You can obtain one at http://mozilla.org/MPL/2.0/.
8
- */
9
-
10
-/**
11
- * @file
12
- * @date      04/03/2014 01:08:28 PM
13
- * @version   $Id$
14
- * @author    Trevor Irons (ti)
15
- * @email     Trevor.Irons@xri-geo.com
16
- * @copyright Copyright (c) 2014, XRI Geophysics, LLC
17
- * @copyright Copyright (c) 2014, Trevor Irons
18
- */
19
-
20
-#include "Lemma"
21
-#ifdef TINYXMLSUPPORT
22
-#include "tinyxml2.h"
23
-
24
-#include <ctime>
25
-using namespace tinyxml2;
26
-using namespace Lemma;
27
-
28
-void ParseTEM( XMLElement* element );
29
-
30
-template <typename T>
31
-std::vector<T> ReadLine( const int& nr, const std::string& line ) ;
32
-
33
-int main(int argc, char **argv) {
34
-
35
-    if ( argc > 1 ) {
36
-		XMLDocument* doc = new XMLDocument();
37
-		clock_t startTime = clock();
38
-		doc->LoadFile( argv[1] );
39
-		clock_t loadTime = clock();
40
-		int errorID = doc->ErrorID();
41
-
42
-        // Get some info
43
-        //static const char* xml = "<element/>";
44
-        //doc->Parse( xml );
45
-        //XMLNode* titleElement = doc->FirstChild(); //Element()->FirstChildElement( "PLAY" )->FirstChildElement( "TITLE" );
46
-        XMLElement* titleElement = doc->FirstChildElement( ); //->FirstChildElement( "TITLE" );
47
-        //const char* title = titleElement->Value(); //GetText();
48
-        const char* title = titleElement->Value(); //GetText();
49
-
50
-        printf( "Test file '%s' loaded. ErrorID=%d\n", argv[1], errorID );
51
-        printf( "Name of FirstChildElement: %s\n", title );
52
-
53
-        if (strcmp ( titleElement->Value(), "NGXFile" ) != 0) {
54
-            std::cout <<"NGX file was not detected!" << std::endl;
55
-            exit(EXIT_FAILURE);
56
-        } else {
57
-            //std::cout <<
58
-            //titleElement->FirstAttribute() ;//"type");// << std::endl;;
59
-            if (strcmp(  titleElement->FindAttribute("type")->Value(),"tem") == 0) {
60
-                // Parse TEM file
61
-                ParseTEM( titleElement );
62
-            } else {
63
-                std::cout << "No parser for NGX filetype " << titleElement->FindAttribute("type")->Value() << std::endl;
64
-                std::cout << "YOU should write one!\n";
65
-                exit(EXIT_FAILURE);
66
-            }
67
-
68
-        }
69
-
70
-		delete doc; doc = 0;
71
-
72
-        clock_t deleteTime = clock();
73
-		if ( !errorID ) {
74
-			printf( "========================================================\n");
75
-			printf( "Load time=%u\n",   (unsigned)(loadTime - startTime) );
76
-			printf( "Delete time=%u\n", (unsigned)(deleteTime - loadTime) );
77
-			printf( "Total time=%u\n",  (unsigned)(deleteTime - startTime) );
78
-		}
79
-
80
-
81
-		exit(0);
82
-	} else {
83
-        std::cout << "Enter NGX.x file to parse\n";
84
-    }
85
-}
86
-
87
-void ParseTEM( XMLElement* element ) {
88
-
89
-    std::cout << "This is a NGX.t file" << std::endl;
90
-
91
-
92
-    if (strcmp( element->FindAttribute("version")->Value(),"0.1") == 0) {
93
-        std::cout << "Version 0.1 detected" << std::endl;
94
-    } else {
95
-        std::cout << "Unsupported NGX.t version" << std::endl;
96
-    }
97
-
98
-    // system description
99
-    std::cout << "System description" << std::endl;
100
-    std::cout << element->FirstChildElement("system")->FirstChildElement("name")->GetText() << std::endl;
101
-    XMLElement* system = element->FirstChildElement("system");
102
-        int ntx = atoi(system->FirstChildElement("transmitters")->FindAttribute("num")->Value());
103
-        std::cout << "numTx = " << ntx << std::endl;
104
-        // OK Parse Transmitter(s)
105
-        XMLElement* tx = system->FirstChildElement("transmitters")->FirstChildElement("transmitter");
106
-        //    std::cout << "Tx id = " << tx->FindAttribute("id")->Value() << std::endl;
107
-        //std::cout << tx->FirstChildElement("loop.coordinates")->FindAttribute("npoint")->Value();//->FirstChildElement("northingPoints")->Value() << std::endl;
108
-        //std::cout << tx->FirstChildElement("loop.coordinates")->FirstChildElement("northing.points")->GetText();//->FirstChildElement("northingPoints")->Value() << std::endl;
109
-        for (int it=0; it<ntx; ++it) {
110
-            std::cout << "\nTransmitter " << it << std::endl;
111
-            if (it > 0) tx = tx->NextSiblingElement();
112
-            int npoints = atoi(tx->FirstChildElement("loop.coordinates")->FindAttribute("npoint")->Value());
113
-
114
-            std::cout << "points= " << npoints; // tx->FirstChildElement("loop.coordinates")->FindAttribute("npoint")->Value();//->FirstChildElement("northingPoints")->Value() << std::endl;
115
-            std::vector<Real> LP = ReadLine<Real>( npoints, std::string(tx->FirstChildElement("loop.coordinates")->FirstChildElement("northing.points")->GetText()) );
116
-            for (int ii=0; ii<npoints; ++ii) std::cout << "\t"<< LP[ii] ;
117
-            //std::cout << tx->FirstChildElement("loop.coordinates")->FirstChildElement("northing.points")->GetText();//->FirstChildElement("northingPoints")->Value() << std::endl;
118
-            //std::cout << tx->FirstChildElement("loop.coordinates")->FirstChildElement("easting.points")->GetText();//->FirstChildElement("northingPoints")->Value() << std::endl;
119
-        }
120
-    std::cout << "\nEND system description\n";
121
-
122
-}
123
-
124
-
125
-template <typename T>
126
-std::vector<T> ReadLine( const int& nr, const std::string& line ) {
127
-
128
-    std::vector<T>   lineData;
129
-    std::stringstream  lineStream(line);
130
-
131
-    T value;
132
-    while(lineStream >> value) {
133
-        lineData.push_back(value);
134
-    }
135
-    return lineData;
136
-}
137
-#else
138
-
139
-int main() {
140
-    std::cout << "you have to compile lemma with external tinyxml library to use this" << std::endl;
141
-}
142
-
143
-#endif
144
-
145
-    //--------------------------------------------------------------------------------------
146
-    //       Class:  ASCIIParser
147
-    //      Method:  ReadInts
148
-    //--------------------------------------------------------------------------------------
149
-//     std::vector<int> ReadInts ( const int& nr ) {
150
-//         std::string buf;
151
-//         char *dump = new char[BufferSize];
152
-//         std::vector<int> vals(0);
153
-//         while (input >> buf) {
154
-//             if (buf.substr(0, CommentString.size()) == CommentString) {
155
-//                 input.getline(dump, BufferSize);
156
-//             } else {
157
-//                 vals.push_back( atoi(buf.c_str() ));
158
-//             }
159
-//             if (static_cast<int>(vals.size()) == nr) {
160
-//                 delete [] dump;
161
-//                 return vals;
162
-//             }
163
-//
164
-//         }
165
-//         delete [] dump;
166
-//         return vals;
167
-//     }		// -----  end of method ASCIIParser::ReadInts  -----
168
-

+ 0
- 67
Modules/LemmaCore/examples/utYAMLconfig.cpp Dosyayı Görüntüle

@@ -1,67 +0,0 @@
1
-#ifdef HAVE_YAMLCPP
2
-
3
-#include "yaml-cpp/yaml.h"
4
-#include "yaml-cpp/eventhandler.h"
5
-#include <fstream>
6
-#include <iostream>
7
-#include <vector>
8
-
9
-struct Params {
10
-	bool hasFile;
11
-	std::string fileName;
12
-};
13
-
14
-Params ParseArgs(int argc, char **argv) {
15
-	Params p;
16
-
17
-	std::vector<std::string> args(argv + 1, argv + argc);
18
-
19
-	return p;
20
-}
21
-
22
-class NullEventHandler: public YAML::EventHandler
23
-{
24
-public:
25
-	virtual void OnDocumentStart(const YAML::Mark&) {}
26
-	virtual void OnDocumentEnd() {}
27
-
28
-	virtual void OnNull(const YAML::Mark&, YAML::anchor_t) {}
29
-	virtual void OnAlias(const YAML::Mark&, YAML::anchor_t) {}
30
-	virtual void OnScalar(const YAML::Mark&, const std::string&, YAML::anchor_t, const std::string&) {}
31
-
32
-	virtual void OnSequenceStart(const YAML::Mark&, const std::string&, YAML::anchor_t) {}
33
-	virtual void OnSequenceEnd() {}
34
-
35
-	virtual void OnMapStart(const YAML::Mark&, const std::string&, YAML::anchor_t) {}
36
-	virtual void OnMapEnd() {}
37
-};
38
-
39
-void parse(std::istream& input)
40
-{
41
-	try {
42
-		YAML::Node doc = YAML::Load(input);
43
-		std::cout << doc << "\n";
44
-	} catch(const YAML::Exception& e) {
45
-		std::cerr << e.what() << "\n";
46
-	}
47
-}
48
-
49
-int main(int argc, char **argv)
50
-{
51
-	Params p = ParseArgs(argc, argv);
52
-
53
-	if(argc > 1) {
54
-		std::ifstream fin;
55
-		fin.open(argv[1]);
56
-		parse(fin);
57
-	} else {
58
-		parse(std::cin);
59
-	}
60
-
61
-	return 0;
62
-}
63
-#else
64
-int main() {
65
-}
66
-#endif
67
-

+ 0
- 84
Modules/LemmaCore/examples/utgaussquad.cpp Dosyayı Görüntüle

@@ -1,84 +0,0 @@
1
-// ===========================================================================
2
-// 
3
-//       Filename:  utqaussquad.cpp
4
-// 
5
-//    Description:  Test for gaussian quadrature algorithm
6
-// 
7
-//        Version:  0.0
8
-//        Created:  10/05/2010 08:54:26 AM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++
11
-// 
12
-//         Author:  M. Andy Kass (MAK)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  Broken Spoke Development, LLC
16
-//
17
-//          Email:  mkass@numericalgeo.com
18
-// 
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include "Lemma"
35
-using namespace Lemma;
36
-using namespace std;
37
-
38
-#ifdef LEMMAUSEVTK
39
-#include "matplot.h"
40
-using namespace matplot;
41
-#endif
42
-
43
-int main() {
44
-
45
-	int N = 600;
46
-	int upb = 5;
47
-	int lowb = -1;
48
-	VectorXr func(N);
49
-	VectorXr wx(N);
50
-	Real integrationres,actres;
51
-
52
-	gaussianquadrature *lgqw = gaussianquadrature::New();
53
-	lgqw->SetFreqs(N,upb,lowb);
54
-	lgqw->CalcAW();
55
-
56
-	wx=lgqw->GetAbscissae();
57
-	func=cos(wx.array());
58
-//	for (int ii=0;ii<N;++ii) {
59
-//		cout << wx(ii) << "  " << func(ii) << endl;
60
-//	}
61
-
62
-	lgqw->SetFunc(func);
63
-	lgqw->Integrate();
64
-	integrationres=lgqw->GetResult();
65
-
66
-	actres = -sin((Real)upb)+sin((Real)lowb);
67
-	
68
-	cout << "Gaussian Quadrature Result: " << integrationres << endl;
69
-	cout << "Actual Result: " << actres << endl;
70
-	
71
-		
72
-	//Plot things
73
-	#ifdef LEMMAUSEVTK
74
-	double colour1[3] = {0.0,0.0,1.0};
75
-
76
-	Plot2D_VTK p1("X", "Y", 800,600);
77
-	p1.plot(wx,func,colour1,".-");
78
-	p1.show();
79
-
80
-	#endif
81
-
82
-	return EXIT_SUCCESS;
83
-}
84
-

+ 0
- 258
Modules/LemmaCore/examples/utgmrprint.cpp Dosyayı Görüntüle

@@ -1,258 +0,0 @@
1
-// ===========================================================================
2
-//   This file is distributed with Lemma,
3
-//
4
-//       Filename:  utsnmrinversion1d.cpp
5
-//
6
-//        Created:  10/07/2010 08:57:04 AM
7
-//       Compiler:  Tested with g++, icpc, and MSVC 2010
8
-//
9
-//         Author:  Trevor Irons (ti)
10
-//
11
-//   Organisation:  Colorado School of Mines (CSM)
12
-//                  United States Geological Survey (USGS)
13
-//
14
-//          Email:  tirons@mines.edu, tirons@usgs.gov
15
-//
16
-//  This program is free software: you can redistribute it and/or modify
17
-//  it under the terms of the GNU General Public License as published by
18
-//  the Free Software Foundation, either version 3 of the License, or
19
-//  (at your option) any later version.
20
-//
21
-//  This program is distributed in the hope that it will be useful,
22
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
23
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
24
-//  GNU General Public License for more details.
25
-//
26
-//  You should have received a copy of the GNU General Public License
27
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
28
-//
29
-// ===========================================================================
30
-
31
-/**
32
-  @file
33
-  @author   Trevor Irons
34
-  @date     10/07/2010
35
-  @version   0.0
36
- **/
37
-
38
-#ifdef LEMMAUSEVTK
39
-#include "vtkRenderer.h"
40
-#include "vtkRenderWindow.h"
41
-#include "vtkRenderWindowInteractor.h"
42
-#include "vtkPNGWriter.h"
43
-#include "vtkRenderLargeImage.h"
44
-#endif
45
-
46
-#include "receiverpoints.h"
47
-#include "emearth1d.h"
48
-#include "PolygonalWireAntenna.h"
49
-
50
-using namespace Lemma;
51
-
52
-std::vector<Real>  readinpfile(const std::string& fname);
53
-
54
-int main(int argc, char** argv) {
55
-
56
-    std::cout <<
57
-    "\n"
58
-    << "hantenna - a programme for computing the h field from polygonal wire\n"
59
-    << "loop sources \n\n"
60
-    << "The following copyrights apply to this application:\n"
61
-    << "Copyright (C) 2009, 2010, 2011, 2012 Colorado School of Mines\n"
62
-    << "Copyright (C) 2009, 2010, 2011, 2012 Trevor Irons\n"
63
-    << "Copyright (C) 2011 Broken Spoke Development, LLC\n\n"
64
-    << "hantenna was built using Lemma (Lemma is an Electromagnetics Modelling API)\n"
65
-    << "More information may be found at https://lemmasoftware.org\n\n"
66
-    << "This program is free software: you can redistribute it and/or modify\n"
67
-    << "it under the terms of the GNU General Public License as published by\n"
68
-    << "the Free Software Foundation, either version 3 of the License, or\n"
69
-    << "(at your option) any later version.\n\n"
70
-
71
-    << "This program is distributed in the hope that it will be useful,\n"
72
-    << "but WITHOUT ANY WARRANTY; without even the implied warranty of\n"
73
-    << "MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the\n"
74
-    << "GNU General Public License for more details.\n\n"
75
-
76
-    << "You should have received a copy of the GNU General Public License\n"
77
-    << "along with this program.  If not, see <http://www.gnu.org/licenses/>.\n\n";
78
-
79
-    if (argc < 4) {
80
-        std::cout << "usage: hantenna.exe  trans.inp cond.inp points.inp \n";
81
-        exit(0);
82
-    }
83
-
84
-    std::vector<Real> Trans   = readinpfile(std::string(argv[1]));
85
-    std::vector<Real> CondMod = readinpfile(std::string(argv[2]));
86
-    std::vector<Real> Points  = readinpfile(std::string(argv[3]));
87
-
88
-    //////////////////////////////////////
89
-    // Define transmitter
90
-    PolygonalWireAntenna* trans = PolygonalWireAntenna::New();
91
-        trans->SetNumberOfPoints((int)(Trans[0]));
92
-        int ip=1;
93
-        for ( ; ip<=(int)(Trans[0])*2; ip+=2) {
94
-            trans->SetPoint(ip/2, Vector3r (Trans[ip], Trans[ip+1], -1e-3));
95
-        }
96
- 	    trans->SetNumberOfFrequencies(1);
97
- 	    trans->SetFrequency(0, Trans[ip]);
98
-        trans->SetCurrent(Trans[ip+1]);
99
-
100
-	// Receivers
101
- 	ReceiverPoints *receivers = ReceiverPoints::New();
102
-        int nx = (int)Points[0];
103
-        int ny = (int)Points[1];
104
-        int nz = (int)Points[2];
105
-        Real ox = Points[3];
106
-        Real oy = Points[4];
107
-        Real oz = Points[5];
108
-     	Vector3r loc;
109
-        VectorXr dx(nx-1); // TODO map the dx, dy, dz vectors
110
-        VectorXr dy(ny-1);
111
-        VectorXr dz(nz-1);
112
-        ip = 6;
113
-        int ir = 0;
114
-        for ( ; ip <6+nx-1; ++ip) {
115
-            dx[ir] = Points[ip];
116
-            ++ir;
117
-        }
118
-        ir = 0;
119
-        for ( ; ip <6+ny-1+nx-1; ++ip) {
120
-            dy[ir] = Points[ip];
121
-            ++ir;
122
-        }
123
-        ir = 0;
124
-        for ( ; ip <6+nz-1+ny-1+nx-1; ++ip) {
125
-            dz[ir] = Points[ip];
126
-            ++ir;
127
-        }
128
- 		receivers->SetNumberOfReceivers(nx*ny*nz);
129
- 		ir = 0;
130
-        Real pz  = oz;
131
- 		for (int iz=0; iz<nz; ++iz) {
132
- 		    Real py    =  oy;
133
- 		    for (int iy=0; iy<ny; ++iy) {
134
- 		        Real px    =  ox;
135
- 		        for (int ix=0; ix<nx; ++ix) {
136
- 			        loc << px, py, pz;
137
- 			        receivers->SetLocation(ir, loc);
138
- 			        if (ix < nx-1) px += dx[ix];
139
- 			        ++ ir;
140
-     	        }
141
-                if (iy<ny-1) py += dy[iy];
142
-            }
143
-            if (iz<nz-1) pz += dz[iz];
144
-        }
145
-
146
-    ////////////////////////////////////
147
-    // Define model
148
-    LayeredEarthEM *earth = LayeredEarthEM::New();
149
-    VectorXcr sigma;
150
-    VectorXr  thick;
151
- 	earth->SetNumberOfLayers(CondMod[0]+1);
152
- 	sigma.resize(CondMod[0]+1); sigma(0) = 0; // airlayer
153
-    thick.resize(CondMod[0]-1);
154
-    int ilay=1;
155
-    for ( ; ilay/2<CondMod[0]-1; ilay+=2) {
156
-        sigma(ilay/2+1) =  1./CondMod[ilay];
157
-        thick(ilay/2) =  CondMod[ilay+1];
158
-    }
159
-    sigma(ilay/2+1) = 1./ CondMod[ilay];
160
-	earth->SetLayerConductivity(sigma);
161
-    if (thick.size() > 0) earth->SetLayerThickness(thick);
162
-
163
-	EMEarth1D  *EmEarth = EMEarth1D::New();
164
-		EmEarth->AttachWireAntenna(trans);
165
-		EmEarth->AttachLayeredEarthEM(earth);
166
-		EmEarth->AttachReceiverPoints(receivers);
167
-		EmEarth->SetFieldsToCalculate(H);
168
-        EmEarth->CalculateWireAntennaFields();
169
-
170
-    #ifdef LEMMAUSEVTK
171
-	vtkRenderer           *renderer = vtkRenderer::New();
172
-	vtkRenderWindow         *renWin = vtkRenderWindow::New();
173
-	vtkRenderWindowInteractor *iren = vtkRenderWindowInteractor::New();
174
-    trans->ApproximateWithElectricDipoles( (VectorXr (3) << 0,0,0).finished() );
175
-	vtkActor **dipActors = new vtkActor*[trans->GetNumberOfDipoles()];
176
-	for (int id=0; id<trans->GetNumberOfDipoles(); ++id) {
177
-		dipActors[id] = trans->GetVtkActor(id);
178
-		renderer->AddActor(dipActors[id]);
179
-	}
180
-    vtkActor *hfield  = receivers->GetVtkGlyphActor (HFIELDREAL, 3, 1e2, 0);
181
- 	vtkActor *hfieldi = receivers->GetVtkGlyphActor (HFIELDIMAG, 3, 1e2, 0);
182
-    hfieldi->GetProperty()->SetColor(1,0,1);
183
- 	hfield->GetProperty()->SetColor(0,1,0);
184
- 	renderer->AddActor(hfield);
185
- 	renderer->AddActor(hfieldi);
186
-	renderer->SetBackground(0,0,0);
187
-	// Render the window
188
-	renWin->AddRenderer(renderer);
189
-	iren->SetRenderWindow(renWin);
190
-	iren->Initialize();
191
-	iren->Start();
192
-	iren->Render();
193
-	cout << "Enter File name?: ";
194
-	std::string pngName;
195
-	std::cin >> pngName;
196
-	vtkPNGWriter *pngwrite = vtkPNGWriter::New();
197
-	vtkRenderLargeImage *renlarge = vtkRenderLargeImage::New();
198
-	renlarge->SetInput(renderer);
199
-	renlarge->SetMagnification(2);
200
-	pngwrite->SetInputConnection(renlarge->GetOutputPort());
201
-	pngName.append(".png");
202
-	pngwrite->SetFileName(pngName.c_str());
203
-	pngwrite->Write();
204
-	iren->Delete();
205
-	renWin->Delete();
206
-	renderer->Delete();
207
-    #endif
208
-
209
-    ////////////////////////////////////
210
-    // Report
211
- 	std::fstream hreal("hfield.dat", std::ios::out);
212
-    hreal << *trans << std::endl;
213
-    hreal << *earth << std::endl;
214
-    hreal << "Right hand coordinate system, z is positive down\n";
215
-    hreal << "x[m]\ty[m]\tz[m]\tHx[A/m]\tHy[A/m]\tHz[A/m]\n";
216
-    hreal.precision(8);
217
-    int i=0;
218
-	for (int iz=0; iz<nz; ++iz) {
219
-	for (int iy=0; iy<ny; ++iy) {
220
-	for (int ix=0; ix<nx; ++ix) {
221
-        hreal << receivers->GetLocation(i).transpose() << "\t";
222
- 		hreal << std::real(receivers->GetHfield(0, i).transpose()[0]) << "\t";
223
- 		hreal << std::imag(receivers->GetHfield(0, i).transpose()[0]) << "\t";
224
- 		hreal << std::real(receivers->GetHfield(0, i).transpose()[1]) << "\t";
225
- 		hreal << std::imag(receivers->GetHfield(0, i).transpose()[1]) << "\t";
226
- 		hreal << std::real(receivers->GetHfield(0, i).transpose()[2]) << "\t";
227
- 		hreal << std::imag(receivers->GetHfield(0, i).transpose()[2]) << "\n";
228
-        ++i;
229
-    }
230
-    }
231
-    }
232
-    hreal.close();
233
-
234
-    // Clean up
235
-    EmEarth->Delete();
236
-    earth->Delete();
237
-    receivers->Delete();
238
-    trans->Delete();
239
-}
240
-
241
-std::vector<Real>  readinpfile(const std::string& fname) {
242
-    std::string buf;
243
-    char dump[255];
244
-    std::vector<Real> vals;
245
-    std::fstream input(fname.c_str(), std::ios::in);
246
-    if (input.fail()) {
247
-        std::cerr << "Input file " << fname << " failed to open\n";
248
-        exit(EXIT_FAILURE);
249
-    }
250
-    while (input >> buf) {
251
-        if (buf.substr(0,2) == "//") {
252
-            input.getline(dump, 255);
253
-        } else {
254
-            vals.push_back( atof(buf.c_str() ));
255
-        }
256
-    }
257
-    return vals;
258
-}

+ 0
- 93
Modules/LemmaCore/examples/uthankel2.cpp Dosyayı Görüntüle

@@ -1,93 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  uthankel2.cpp
4
-//
5
-//    Description:
6
-//
7
-//        Version:  0.0
8
-//        Created:  05/14/2010 10:26:59 AM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++, icpc, and MSVC 2000
11
-//
12
-//         Author:  Trevor Irons (ti)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  United States Geological Survey (USGS)
16
-//
17
-//          Email:  tirons@mines.edu, tirons@usgs.gov
18
-//
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include "hankeltransformhankel2.h"
35
-#include "hankeltransformgaussianquadrature.h"
36
-#include "kernelem1d.h"
37
-#include "layeredearthem.h"
38
-
39
-using namespace Lemma;
40
-
41
-int main() {
42
-
43
-	// Define model
44
-	LayeredEarthEM *Earth = LayeredEarthEM::New();
45
-		VectorXcr sigma(3);
46
-		sigma << 0., .1, 0.01;
47
-		VectorXr  thick(1);
48
-		thick << 10;
49
-		Earth->SetNumberOfLayers(3);
50
-		Earth->SetLayerConductivity(sigma);
51
-		Earth->SetLayerThickness(thick);
52
-
53
-	// Source
54
-	// Test with a single dipole
55
-	DipoleSource *dipole = DipoleSource::New();
56
-		dipole->SetMoment(2);
57
-		dipole->SetType(MAGNETICDIPOLE);
58
-		dipole->SetPolarisation(ZPOLARISATION);
59
-		dipole->SetLocation(0,0,0);
60
-		dipole->SetNumberOfFrequencies(1);
61
-		dipole->SetFrequency(0,1000);
62
-		dipole->SetPhase(0);
63
-
64
-	KernelEm1D *Kernel = KernelEm1D::New();
65
-		Kernel->Initialise(Earth);
66
-		Kernel->SetUpSource(dipole, 0);
67
-		Kernel->SetUpReceiver(-0.4);
68
-    //std::vector< KernelEm1DBase* > KernelVec;
69
-    //    KernelVec.push_back( )
70
-
71
-	std::cout.precision(10);
72
-
73
-	Hankel2 *dig = Hankel2::New();
74
-//         dig->ComputeRelated(.23 , Kernel);
75
-//  		std::cout << "  dig->Zgauss "
76
-//  				  << dig->Zgauss(0, TE, 0, 100.,
77
-//  								  1000.*std::sqrt(MU0*EPSILON0), Kernel)
78
-//  			      << std::endl;
79
-
80
-// 	HankelTransformGaussianQuadrature *gauss =
81
-// 			HankelTransformGaussianQuadrature::New();
82
-// 		std::cout << "gauss->Zgauss "
83
-// 				  << gauss->Zgauss(0, TE, 0, 100.,
84
-// 								  1000.*std::sqrt(MU0*EPSILON0), Kernel)
85
-// 			      << std::endl;
86
-
87
-	Earth->Delete();
88
-	dig->Delete();
89
-	//gauss->Delete();
90
-    dipole->Delete();
91
-	Kernel->Delete();
92
-	return EXIT_SUCCESS;
93
-}

+ 0
- 257
Modules/LemmaCore/examples/uthantenna.cpp Dosyayı Görüntüle

@@ -1,257 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  hantenna.cpp
4
-//
5
-//        Created:  10/07/2010 08:57:04 AM
6
-//       Modified:  14 Aug 2012
7
-//       Compiler:  Tested with g++, icpc, and MSVC 2010
8
-//
9
-//         Author:  Trevor Irons (ti)
10
-//
11
-//       Copyright (C) 2011    Broken Spoke Development, LLC
12
-//       Copyright (C) 2012    Trevor Irons
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//
16
-//          Email:  tirons@mines.edu
17
-//
18
-//  This program is free software: you can redistribute it and/or modify
19
-//  it under the terms of the GNU General Public License as published by
20
-//  the Free Software Foundation, either version 3 of the License, or
21
-//  (at your option) any later version.
22
-//
23
-//  This program is distributed in the hope that it will be useful,
24
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
25
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
26
-//  GNU General Public License for more details.
27
-//
28
-//  You should have received a copy of the GNU General Public License
29
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
30
-//
31
-// ===========================================================================
32
-
33
-/**
34
-  @file
35
-  @author   Trevor Irons
36
-  @date     10/07/2010
37
-  @version  $Revision: 208 $
38
-  $Id$
39
- **/
40
-
41
-#include "receiverpoints.h"
42
-#include "emearth1d.h"
43
-#include "PolygonalWireAntenna.h"
44
-#ifdef LEMMAUSEOMP
45
-#include "omp.h"
46
-#endif
47
-
48
-#include "timer.h"
49
-
50
-using namespace Lemma;
51
-
52
-std::vector<Real>  readinpfile(const std::string& fname);
53
-
54
-std::vector<std::string>  readinpfile2(const std::string& fname);
55
-
56
-int main(int argc, char** argv) {
57
-
58
-    std::cout <<
59
-    "\n"
60
-    << "hantenna- $Date: 2015-01-26 10:11:24 -0700 (Mon, 26 Jan 2015) $ $Revision: 208 $\n\n"
61
-    << "hantenna is a programme for computing the h field from polygonal wire\n"
62
-    << "loop sources \n\n"
63
-    << "hantenna was built using Lemma (Lemma is an Electromagnetics Modelling API)\n"
64
-    << "Lemma is Free and Open Source Software (FOSS) and is released under\n"
65
-    << "the MPL, it is covered by the following copyrights:\n"
66
-    << "Copyright (C) 2009, 2010, 2011, 2012      Colorado School of Mines\n"
67
-    << "Copyright (C) 2009, 2010, 2011, 2012      Trevor P. Irons\n"
68
-    << "Copyright (C) 2011, 2012                  M. Andy Kass\n\n"
69
-    << "More information may be found at: https://lemmasoftware.org\n"
70
-    << "                                  info@lemmasoftware.org\n\n"
71
-    << "=====================================================================\n"
72
-    << "This programme is part of Lemma, a geophysical modelling and inversion API \n"
73
-    << "This Source Code Form is subject to the terms of the Mozilla Public\n"
74
-    << "License, v. 2.0. If a copy of the MPL was not distributed with this\n"
75
-    << "file, You can obtain one at http://mozilla.org/MPL/2.0/. \n"
76
-    << "=====================================================================\n\n\n";
77
-
78
-    if (argc < 5) {
79
-        std::cout << "usage: hantenna.exe  trans.inp cond.inp points.inp config.inp \n";
80
-        exit(0);
81
-    }
82
-
83
-    #ifdef LEMMAUSEOMP
84
-    std::cout << "OpenMP is using " << omp_get_max_threads() << " threads" << std::endl;
85
-    #endif
86
-
87
-    std::vector<Real> Trans   = readinpfile(std::string(argv[1]));
88
-    std::vector<Real> CondMod = readinpfile(std::string(argv[2]));
89
-    std::vector<Real> Points  = readinpfile(std::string(argv[3]));
90
-    std::vector<std::string> config  = readinpfile2(std::string(argv[4]));
91
-
92
-    //////////////////////////////////////
93
-    // Define transmitter
94
-    PolygonalWireAntenna* trans = PolygonalWireAntenna::New();
95
-        trans->SetNumberOfPoints((int)(Trans[0]));
96
-        int ip=1;
97
-        for ( ; ip<=(int)(Trans[0])*2; ip+=2) {
98
-            trans->SetPoint(ip/2, Vector3r (Trans[ip], Trans[ip+1], -1e-3));
99
-        }
100
- 	    trans->SetNumberOfFrequencies(1);
101
- 	    trans->SetFrequency(0, Trans[ip]);
102
-        trans->SetCurrent(Trans[ip+1]);
103
-        trans->SetMinDipoleRatio(atof(config[1].c_str()));
104
-        trans->SetMinDipoleMoment(atof(config[2].c_str()));
105
-        trans->SetMaxDipoleMoment(atof(config[3].c_str()));
106
-
107
-	// Receivers
108
- 	ReceiverPoints *receivers = ReceiverPoints::New();
109
-        int nx = (int)Points[0];
110
-        int ny = (int)Points[1];
111
-        int nz = (int)Points[2];
112
-        Real ox = Points[3];
113
-        Real oy = Points[4];
114
-        Real oz = Points[5];
115
-     	Vector3r loc;
116
-        VectorXr dx(nx-1);
117
-        VectorXr dy(ny-1);
118
-        VectorXr dz(nz-1);
119
-        ip = 6;
120
-        int ir = 0;
121
-        for ( ; ip <6+nx-1; ++ip) {
122
-            dx[ir] = Points[ip];
123
-            ++ir;
124
-        }
125
-        ir = 0;
126
-        for ( ; ip <6+ny-1+nx-1; ++ip) {
127
-            dy[ir] = Points[ip];
128
-            ++ir;
129
-        }
130
-        ir = 0;
131
-        for ( ; ip <6+nz-1+ny-1+nx-1; ++ip) {
132
-            dz[ir] = Points[ip];
133
-            ++ir;
134
-        }
135
- 		receivers->SetNumberOfReceivers(nx*ny*nz);
136
- 		ir = 0;
137
-        Real pz  = oz;
138
- 		for (int iz=0; iz<nz; ++iz) {
139
- 		    Real py    =  oy;
140
- 		    for (int iy=0; iy<ny; ++iy) {
141
- 		        Real px    =  ox;
142
- 		        for (int ix=0; ix<nx; ++ix) {
143
- 			        loc << px, py, pz;
144
- 			        receivers->SetLocation(ir, loc);
145
- 			        if (ix < nx-1) px += dx[ix];
146
- 			        ++ ir;
147
-     	        }
148
-                if (iy<ny-1) py += dy[iy];
149
-            }
150
-            if (iz<nz-1) pz += dz[iz];
151
-        }
152
-
153
-    ////////////////////////////////////
154
-    // Define model
155
-    LayeredEarthEM *earth = LayeredEarthEM::New();
156
-    VectorXcr sigma;
157
-    VectorXr  thick;
158
- 	earth->SetNumberOfLayers(CondMod[0]+1);
159
- 	sigma.resize(CondMod[0]+1); sigma(0) = 0; // airlayer
160
-    thick.resize(CondMod[0]-1);
161
-    int ilay=1;
162
-    for ( ; ilay/2<CondMod[0]-1; ilay+=2) {
163
-        sigma(ilay/2+1) =  1./CondMod[ilay];
164
-        thick(ilay/2) =  CondMod[ilay+1];
165
-    }
166
-    sigma(ilay/2+1) = 1./ CondMod[ilay];
167
-	earth->SetLayerConductivity(sigma);
168
-    if (thick.size() > 0) earth->SetLayerThickness(thick);
169
-
170
-	EMEarth1D  *EmEarth = EMEarth1D::New();
171
-		EmEarth->AttachWireAntenna(trans);
172
-		EmEarth->AttachLayeredEarthEM(earth);
173
-		EmEarth->AttachReceiverPoints(receivers);
174
-		EmEarth->SetFieldsToCalculate(H);
175
-        EmEarth->SetHankelTransformMethod(string2Enum<HANKELTRANSFORMTYPE>(config[0]));
176
-        EmEarth->SetHankelTransformMethod(FHTKEY201);
177
-
178
-	// Keep track of time
179
-	jsw_timer timer;
180
-  	timer.begin();
181
-    clock_t launch = clock();
182
-    EmEarth->CalculateWireAntennaFields(true);    // true=status bar
183
-	Real paTime = timer.end();
184
-
185
-    std::cout << "\n\n===========================================\ncalc. real time: " << paTime/60. << "\t[m]\n";
186
-
187
-    std::cout << "calc. user time: " <<  (clock()-launch)/CLOCKS_PER_SEC/60.   << "\t[CPU m]"
188
-		 << std::endl;
189
-
190
-    ////////////////////////////////////
191
-    // Report
192
- 	std::fstream hrep("hfield.yaml", std::ios::out);
193
-    std::fstream hreal("hfield.dat", std::ios::out);
194
-
195
-    hrep << *EmEarth << std::endl;
196
-    hrep.close();
197
-    //hreal << *trans << std::endl;
198
-    //hreal << *earth << std::endl;
199
-
200
-    hreal << "// Right hand coordinate system, z is positive down\n";
201
-    hreal << "// x[m]\ty[m]\tz[m]\tHx[A/m]\tHy[A/m]\tHz[A/m]\n";
202
-    hreal.precision(8);
203
-    int i=0;
204
-	for (int iz=0; iz<nz; ++iz) {
205
-	for (int iy=0; iy<ny; ++iy) {
206
-	for (int ix=0; ix<nx; ++ix) {
207
-        hreal << receivers->GetLocation(i).transpose() << "\t";
208
- 		hreal << receivers->GetHfield(0, i).transpose() << "\n";
209
-        ++i;
210
-    }
211
-    }
212
-    }
213
-    hreal.close();
214
-    // Clean up
215
-    EmEarth->Delete();
216
-    earth->Delete();
217
-    receivers->Delete();
218
-    trans->Delete();
219
-}
220
-
221
-std::vector<Real>  readinpfile(const std::string& fname) {
222
-    std::string buf;
223
-    char dump[255];
224
-    std::vector<Real> vals;
225
-    std::fstream input(fname.c_str(), std::ios::in);
226
-    if (input.fail()) {
227
-        std::cerr << "Input file " << fname << " failed to open\n";
228
-        exit(EXIT_FAILURE);
229
-    }
230
-    while (input >> buf) {
231
-        if (buf.substr(0,2) == "//") {
232
-            input.getline(dump, 255);
233
-        } else {
234
-            vals.push_back( atof(buf.c_str() ));
235
-        }
236
-    }
237
-    return vals;
238
-}
239
-
240
-std::vector<std::string>  readinpfile2(const std::string& fname) {
241
-    std::string buf;
242
-    char dump[255];
243
-    std::vector<std::string> vals;
244
-    std::fstream input(fname.c_str(), std::ios::in);
245
-    if (input.fail()) {
246
-        std::cerr << "Input file " << fname << " failed to open\n";
247
-        exit(EXIT_FAILURE);
248
-    }
249
-    while (input >> buf) {
250
-        if (buf.substr(0,2) == "//") {
251
-            input.getline(dump, 255);
252
-        } else {
253
-            vals.push_back( std::string(buf.c_str() ));
254
-        }
255
-    }
256
-    return vals;
257
-}

+ 0
- 218
Modules/LemmaCore/examples/utlogbarriercg.cpp Dosyayı Görüntüle

@@ -1,218 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  utlogbarriercg.cpp
4
-//
5
-//        Created:  12/29/2010 09:40:23 AM
6
-//       Compiler:  Tested with g++, icpc, and MSVC 2010
7
-//
8
-//         Author:  Trevor Irons (ti)
9
-//
10
-//   Organisation:  Colorado School of Mines (CSM)
11
-//                  United States Geological Survey (USGS)
12
-//
13
-//          Email:  tirons@mines.edu, tirons@usgs.gov
14
-//
15
-//  This program is free software: you can redistribute it and/or modify
16
-//  it under the terms of the GNU General Public License as published by
17
-//  the Free Software Foundation, either version 3 of the License, or
18
-//  (at your option) any later version.
19
-//
20
-//  This program is distributed in the hope that it will be useful,
21
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
22
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
23
-//  GNU General Public License for more details.
24
-//
25
-//  You should have received a copy of the GNU General Public License
26
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
27
-//
28
-// ===========================================================================
29
-
30
-/**
31
-  @file
32
-  @author   Trevor Irons
33
-  @date     12/29/2010
34
-  @version   0.0
35
- **/
36
-
37
-#include "LemmaObject.h"
38
-//#include "logbarriercg.h"
39
-//#include "datasnmr.h"
40
-#include <ctime>
41
-
42
-#ifdef HAVEBOOSTRANDOM
43
-#include <boost/random.hpp>
44
-#include <boost/random/normal_distribution.hpp>
45
-#endif
46
-
47
-using namespace std;
48
-using namespace Lemma;
49
-
50
-MatrixXr BuildG(const Real& T2, const Real& Larmor, const Real& T,
51
-        const Real& dt, const VectorXr& nT2Bins, const Real& scale);
52
-
53
-MatrixXr BuildGw(const Real& T2, const Real& Larmor, const Real& T,
54
-        const Real& dt, const VectorXr& nT2Bins, const Real& scale,
55
-        const VectorXr& freqs);
56
-
57
-/// test driver program for log-barrier optimization algorithm
58
-int main() {
59
-    return 0;
60
-}
61
-
62
-#ifdef AA
63
-    // Parameters
64
-    Real T2(.200);
65
-    Real Larmor(2000); // Hz
66
-    Real wL = 2.*PI * Larmor;
67
-    Real T(.6);
68
-    Real dt(1e-4);
69
-    int  nT2(20);
70
-    Real T2Low(.020);
71
-    Real T2Hi(.220);
72
-
73
-    // T2 bins
74
-    VectorXr T2Bins = VectorXr::LinSpaced(nT2, T2Low, T2Hi);
75
-
76
-    // Build true model
77
-    VectorXr m = VectorXr::Zero(T2Bins.size());
78
-    //m[4]  = .15;
79
-    //m[5]  = .15;
80
-    //m[6]  = .15;
81
-    m[7]  = .15;
82
-    m[8]  = .15;
83
-    m[11] = .15;
84
-    m[12] = .15;
85
-    m[13] = .15;
86
-    m[14] = .15;
87
-
88
-    // Build G
89
-    srand ( std::time(NULL) );
90
-    Real scale = 1e-4*std::abs(VectorXr::Random(1)[0]);
91
-    MatrixXr G = BuildG(T2, wL, T, dt, T2Bins, scale);
92
-
93
-    #ifdef HAVEBOOSTRANDOM
94
-    Real mean = 0;
95
-    Real variance = scale*.05*(.5+.15);
96
-    boost::mt19937 randgen(static_cast<unsigned int> (std::time(0)));
97
-    boost::normal_distribution<Real> noise(mean, variance);
98
-    boost::variate_generator<boost::mt19937, boost::normal_distribution<Real> > nD(randgen, noise);
99
-    VectorXr noisy = G*m;
100
-//     for (int i=0; i < noisy.size(); ++i) {
101
-//        noisy(i) += nD();
102
-//     }
103
-    #else
104
-    VectorXr d = G * m;
105
-    VectorXr noisy = d.array();// + .05*( .5 + .15 ) *Eigen::ArrayXd::Random(d.size());
106
-    #endif
107
-
108
-    // Clean Data, and 10% random noise data
109
-    VectorXr RefMod = VectorXr::Zero(m.size());
110
-
111
-    // todo let alpha's be set.
112
-    Real alpha_s  =  .0;
113
-    Real alpha_t2 = 1.0;
114
-    Eigen::SparseMatrix<Real> Wd (G.rows(), G.rows());
115
-    Eigen::SparseMatrix<Real> Wm (G.cols(), G.cols());
116
-
117
-    /////////////////
118
-    // Model objective function
119
-    int ii = 0;
120
-    for (int iT2=0; iT2<nT2; ++iT2) {
121
-        Wm.coeffRef(ii, ii) += alpha_s - alpha_t2;
122
-        if (iT2 < nT2-1) {
123
-            Wm.coeffRef(ii, ii+1) += alpha_t2;
124
-        }
125
-        ++ii;
126
-    }
127
-    Wm.finalize();
128
-    std::fstream  WmOut( "wmMatrix.dat" , std::ios::out);
129
-    WmOut << Wm << std::endl;
130
-    WmOut.close();
131
-
132
-    // Data objective function
133
-    /// @todo add measure of suspected std dev to this.
134
-    for (int id=0; id<G.rows(); ++id) {
135
-        Wd.coeffRef(id, id) = 1.; // 1/sigma(i);
136
-    }
137
-    Wd.finalize();
138
-
139
-    // invert time-domain sinusoid exponent
140
-    //LogBarrierCG(G, RefMod, noisy, (Real)0., (Real)1e5, nT2, Wd, Wm, scale*1e1);
141
-    return EXIT_SUCCESS;
142
-
143
-//     #if 0
144
-//     // invert FD
145
-//     Eigen::FFT<Real> fft;
146
-//     fft.SetFlag(fft.HalfSpectrum);
147
-//     VectorXcr dw;
148
-//     fft.fwd(dw, noisy);
149
-//
150
-//     // Compute freqs Hz
151
-//     VectorXr freqs = DataSNMR::GetNMRSampledFrequencies(T/dt, dt);
152
-//     Real df = freqs[1];
153
-//     Real window = 300; // Hz
154
-//     int iL = (int)(Larmor/df);
155
-//     MatrixXr Gw = BuildGw(T2, wL, T, dt, T2Bins, scale, freqs.segment(iL-window/2, window));
156
-//
157
-//     VectorXr dwu = VectorXr::Zero(2.*window);
158
-//     dwu.head(window) = dw.segment(iL-window/2, window).real();
159
-//     dwu.tail(window) = dw.segment(iL-window/2, window).imag();
160
-//
161
-//     Eigen::DynamicSparseMatrix<Real> Wdw (Gw.rows(), Gw.rows());
162
-//     for (int id=0; id<Gw.rows(); ++id) {
163
-//         Wdw.coeffRef(id, id) = 1.; // 1/sigma(i);
164
-//     }
165
-//     Wdw.finalize();
166
-//     std::cout << "psize " << (Gw*RefMod).size() << std::endl;
167
-//     VectorXr dw2 = Gw*m;
168
-//     //std::cout << dw2 << std::endl;
169
-//     std::cout << "Gw " << Gw.rows() << "\t" << Gw.cols() << std::endl;
170
-//     std::cout << "dwu " << dwu.size() << std::endl;
171
-//     //RefMod.array() += .1;
172
-//     VectorXr mod = LogBarrierCG(Gw, RefMod, dwu, 0., 3., nT2, Wdw, Wm,scale*1e5);
173
-//     //VectorXr mod = LogBarrierCG(Gw, dwu, 0., 1e5);
174
-//
175
-//     std::fstream Gws("gw.out", std::ios::out);
176
-//     Gws << Gw << std::endl;
177
-//     Gws.close();
178
-//     #endif
179
-}
180
-
181
-#endif
182
-
183
-MatrixXr BuildG(const Real& T2, const Real& wL, const Real& T,
184
-            const Real& dt, const VectorXr& T2Bins, const Real& scale) {
185
-    std::cout << "scale " << scale << std::endl;
186
-    int nt = T/dt;
187
-    int nT2 = T2Bins.size();
188
-    MatrixXr G = MatrixXr::Zero(nt,nT2);
189
-    for (int iT2=0; iT2<nT2; ++iT2) {
190
-        Real t=0;
191
-        for (int it=0; it<nt; ++it) {
192
-            G(it, iT2) = scale * exp(-t/T2Bins(iT2)) * sin(wL * t);
193
-            t += dt;
194
-        }
195
-    }
196
-    return G;
197
-}
198
-
199
-
200
-MatrixXr BuildGw(const Real& T2, const Real& wL, const Real& T,
201
-            const Real& dt, const VectorXr& T2Bins, const Real& scale,
202
-            const VectorXr &freqs) {
203
-    VectorXr omegas = freqs.array() * 2.*PI;
204
-    std::cout << "scale " << scale << std::endl;
205
-    int nT2 = T2Bins.size();
206
-    MatrixXr Gw = MatrixXr::Zero(2*freqs.size(), nT2);
207
-    int nW = freqs.size();
208
-    Real sc = 1./dt;
209
-    for (int iT2=0; iT2<nT2; ++iT2) {
210
-        for (int iw=0; iw<freqs.size(); ++iw) {
211
-            Real a = 1./T2Bins(iT2);
212
-            Complex T = wL / ( wL*wL + (a+Complex(0, omegas[iw]))*(a+Complex(0,omegas[iw])) ) ;
213
-            Gw(iw, iT2)     = sc * scale * std::real(T);
214
-            Gw(iw+nW, iT2) = sc * scale * std::imag(T);
215
-        }
216
-    }
217
-    return Gw;
218
-}

+ 0
- 67
Modules/LemmaCore/examples/utpolygonalantenna.cpp Dosyayı Görüntüle

@@ -1,67 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  utpolygonalantennae.cpp
4
-//
5
-//    Description:  Unit test of PolygonalAntenna
6
-//
7
-//        Version:  0.0
8
-//        Created:  05/26/2010 04:30:56 PM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++, icpc, and MSVC 2000
11
-//
12
-//         Author:  Trevor Irons (ti)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  United States Geological Survey (USGS)
16
-//
17
-//          Email:  tirons@mines.edu, tirons@usgs.gov
18
-//
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include "Lemma"
35
-
36
-using namespace Lemma;
37
-
38
-int main() {
39
-
40
-    PolygonalWireAntenna *pa = PolygonalWireAntenna::New();
41
-        pa->SetNumberOfPoints(5);
42
-        pa->SetPoint(0, Vector3r(  0,  0, -1e-3));
43
-        pa->SetPoint(1, Vector3r( 10,  0, -1e-3));
44
-        pa->SetPoint(2, Vector3r( 10, 10, -1e-3));
45
-        pa->SetPoint(3, Vector3r(  0, 10, -1e-3));
46
-        pa->SetPoint(4, Vector3r(  0,  0, -1e-3));
47
-        pa->SetNumberOfFrequencies(1);
48
-        pa->SetFrequency(0,1000.);
49
-        pa->SetCurrent(10.);
50
-        pa->SetNumberOfTurns(1);
51
-
52
-    Vector3r pos;
53
-    pos << 23,23,23;
54
-    pa->ApproximateWithElectricDipoles(pos);
55
-    std::cout << "pos "<< pos.transpose() << "  ndipoles="
56
-              << pa->GetNumberOfDipoles() << std::endl;
57
-    pos << 2,2,2;
58
-    pa->ApproximateWithElectricDipoles(pos);
59
-    std::cout << "pos "<< pos.transpose() << "  ndipoles="
60
-              << pa->GetNumberOfDipoles() << std::endl;
61
-    pos << 1,1,1;
62
-    pa->ApproximateWithElectricDipoles(pos);
63
-    std::cout << "pos "<< pos.transpose() << "  ndipoles="
64
-              << pa->GetNumberOfDipoles() << std::endl;
65
-
66
-    pa->Delete();
67
-}

+ 0
- 68
Modules/LemmaCore/examples/utreadfemubc.cpp Dosyayı Görüntüle

@@ -1,68 +0,0 @@
1
-// ===========================================================================
2
-// 
3
-//       Filename:  utreadfemubc.cpp
4
-// 
5
-//    Description:  
6
-// 
7
-//        Version:  0.0
8
-//        Created:  01/03/2013 02:47:24 PM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++ 
11
-// 
12
-//         Author:  M. Andy Kass (MAK)
13
-//
14
-//   Organisation:  Broken Spoke Development, LLC
15
-//                  
16
-//
17
-//          Email:  mkass@numericalgeo.com
18
-// 
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include "Lemma"
35
-
36
-using namespace Lemma;
37
-
38
-#ifdef LEMMAUSEVTK
39
-#include "matplot.h"
40
-using namespace matplot;
41
-#endif
42
-
43
-int main() {
44
-
45
-	std::string datfile;
46
-
47
-	datfile = "126.obs";
48
-	
49
-	DataReaderFemUBC* Reader = DataReaderFemUBC::New();
50
-	DataFEM* thedata = DataFEM::New();
51
-
52
-	Reader->SetDataFEM(thedata);
53
-
54
-	try {
55
-	Reader->ReadData(datfile,1);
56
-	} catch(std::exception& e) {
57
-		exit(EXIT_FAILURE);
58
-	}
59
-
60
-	std::cout << *Reader << std::endl;
61
-	std::cout << *thedata << std::endl;
62
-
63
-
64
-	thedata->Delete();
65
-	Reader->Delete();
66
-
67
-	return EXIT_SUCCESS;
68
-}

+ 0
- 54
Modules/LemmaCore/examples/utsandbox.cpp Dosyayı Görüntüle

@@ -1,54 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  utsandbox.cpp
4
-//
5
-//        Created:  07/29/2010 10:34:23 AM
6
-//       Compiler:  Tested with g++, icpc, and MSVC 2010
7
-//
8
-//         Author:  Trevor Irons (ti)
9
-//
10
-//   Organisation:  Colorado School of Mines (CSM)
11
-//                  United States Geological Survey (USGS)
12
-//
13
-//          Email:  tirons@mines.edu, tirons@usgs.gov
14
-//
15
-//  This program is free software: you can redistribute it and/or modify
16
-//  it under the terms of the GNU General Public License as published by
17
-//  the Free Software Foundation, either version 3 of the License, or
18
-//  (at your option) any later version.
19
-//
20
-//  This program is distributed in the hope that it will be useful,
21
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
22
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
23
-//  GNU General Public License for more details.
24
-//
25
-//  You should have received a copy of the GNU General Public License
26
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
27
-//
28
-// ===========================================================================
29
-
30
-/**
31
-  @file test sandbox helm1rameters
32
-  @author   Trevor Irons
33
-  @date     07/29/2010
34
-  @version   0.0
35
- **/
36
-
37
-#include "Lemma"
38
-
39
-using namespace Lemma;
40
-
41
-int main() {
42
-
43
-    PolygonalWireAntenna *helm1 = PolygonalWireAntenna::New();
44
-	helm1->SetNumberOfFrequencies(1);
45
-	helm1->SetFrequency(0, 1000);
46
-	helm1->SetNumberOfPoints(5);
47
-	helm1->SetPoint(0, Vector3r(   0,   0, 0));
48
-	helm1->SetPoint(1, Vector3r(   0,   0, 0));
49
-	helm1->SetPoint(2, Vector3r(   0,   0, 0));
50
-	helm1->SetPoint(3, Vector3r(   0,   0, 0));
51
-	helm1->SetPoint(4, Vector3r(   0,   0, 0));
52
-	helm1->SetCurrent(1.);
53
-    helm1->Delete();
54
-}

+ 0
- 199
Modules/LemmaCore/examples/uttemforward.cpp Dosyayı Görüntüle

@@ -1,199 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  uttemforward.cpp
4
-//
5
-//    Description:  TEM Forward Modeller
6
-//
7
-//        Version:  0.0
8
-//        Created:  02/10/2011 03:32:18 PM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++, icpc, and MSVC 2000
11
-//
12
-//         Author:  M. Andy Kass (MAK)
13
-//
14
-//		Copyright:  2011 Trevor Irons and M. Andy Kass
15
-//
16
-//   Organisation:  Colorado School of Mines (CSM)
17
-//                  Broken Spoke Development, LLC
18
-//
19
-//          Email:  mkass@numericalgeo.com
20
-//
21
-//  This program is free software: you can redistribute it and/or modify
22
-//  it under the terms of the GNU General Public License as published by
23
-//  the Free Software Foundation, either version 3 of the License, or
24
-//  (at your option) any later version.
25
-//
26
-//  This program is distributed in the hope that it will be useful,
27
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
28
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
29
-//  GNU General Public License for more details.
30
-//
31
-//  You should have received a copy of the GNU General Public License
32
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
33
-//
34
-// ===========================================================================
35
-
36
-#include <time.h>
37
-#include "Lemma"
38
-#include "banner.h"
39
-
40
-using namespace Lemma;
41
-
42
-#ifdef LEMMAUSEVTK
43
-#include "matplot.h"
44
-using namespace matplot;
45
-#endif
46
-
47
-int main(int argv, char** argc) {
48
-
49
-	// Just for timing
50
-	clock_t launch =clock();
51
-
52
-	// Banner display
53
-	std::string name;
54
-	std::string version;
55
-	std::string usage;
56
-	name = "TEM Forward Modeller - 1D";
57
-	version = "1.0beta";
58
-	usage = "temforward1d [inputfile]";
59
-	banner(name,version,usage);
60
-    if ( argv < 2 ) {
61
-        std::cout << "No input file specified, should be of format\n";
62
-        std::cout <<
63
-"origparabk.obsy        ! Observations-style file.\n\
64
-origpara.con           ! Starting model.\n\
65
-100                    ! Number of Hankel kernel evaluations.\n\
66
-100 1. 1.0E+10         ! Number of Fourier kernel evaluations, & min & max freq.\n\
67
-N                      ! Is noise to be added?\n\
68
-5.  1.0E-08  30        ! Noise to be added: percentage, threshold, seed.\n\
69
-" << std::endl;
70
-
71
-        exit(0);
72
-    }
73
-
74
-	time_t curr=time(0);
75
-	std::cout << std::endl;
76
-	std::cout << "  Start time: " << ctime(&curr) << std::endl;
77
-
78
-	// Define objects
79
-	PolygonalWireAntenna* Trans = PolygonalWireAntenna::New();
80
-//     PolygonalWireAntenna* pa = PolygonalWireAntenna::New();
81
-//         pa->SetNumberOfPoints(5);
82
-// 	    pa->SetPoint(0, Vector3r(   0,   0, -30.001));
83
-// 	    pa->SetPoint(1, Vector3r(   0,  20, -35.001));
84
-// 	    pa->SetPoint(2, Vector3r(  20 , 20, -35.001));
85
-// 	    pa->SetPoint(3, Vector3r(  20,   0, -30.001));
86
-// 	    pa->SetPoint(4, Vector3r(   0,   0, -30.001));
87
-// 	    pa->SetCurrent(100.);
88
-//         pa->SetNumberOfTurns(1);
89
-
90
-
91
-	//DipoleSource* Trans = DipoleSource::New();
92
-	ReceiverPoints *Receivers = ReceiverPoints::New();
93
-	LayeredEarthEM *Earth = LayeredEarthEM::New();
94
-	VectorXr maintimes;
95
-
96
-    /////////////////////////////////////
97
-	// Using model reader
98
-	ModelReaderTem1DUBC* Reader = ModelReaderTem1DUBC::New();
99
-	    Reader->SetEMEarth1D(Earth);
100
-	    Reader->SetTransmitter(Trans);
101
-	    Reader->SetReceiver(Receivers);
102
-	    Reader->ReadParameters( argc[1] );
103
-	    maintimes = Reader->GetTimes();
104
-
105
-	// Attach it to instrumentTEM
106
-	InstrumentTem *instrument = InstrumentTem::New();
107
-	    instrument->EMEarthModel(Earth);
108
-	    instrument->SetTransmitLoop(Trans);
109
-	    //instrument->SetTransmitLoop(pa);
110
-	    //instrument->SetDipoleSource(Trans);
111
-	    instrument->SetReceiver(Receivers);
112
-
113
-
114
-
115
-        // TODO need to input these
116
-        VectorXr widths = VectorXr::Ones(maintimes.size()); // * 1e-5;
117
-        /*
118
-        widths.segment(0,5).array()  *= 5e-6;
119
-        widths.segment(5,5).array()  *= 1e-5;
120
-        widths.segment(10,5).array() *= 5e-5;
121
-        widths.segment(15,5).array() *= 2e-4;
122
-        widths.segment(20,5).array() *= 4e-4;
123
-        //widths.segment(25,5).array() *= 4e-4;
124
-        */
125
-        /*
126
-        widths << .48,4.,8.,8.,8.,8.,8.,12.,12.,12.,16.,16.,16.,20.,24.,24.,28.,32.,32.,36.,40.,44.,52.,
127
-  				56.,64.,68.,76.,88.,96.,104.,120.,132.,144.,160.,180.,200.,220.,248.,272.,304.,336.,376.,
128
-  				416.,464.,516.,572.,636.,708.,784.,872.,968.,1076.,1196.,1328.,1476.,1640.,1824.,2024.,
129
-  				2248.,2500. ;
130
-        */
131
-        widths *= 1e-6;
132
-        std::cout << widths.transpose() << std::endl;
133
-
134
-        instrument->SetReferenceTime(.025);
135
-        //instrument->SetReferenceTime(.025);
136
-	    instrument->SetTimeGates(maintimes, widths);
137
-
138
-        //instrument->SetReceiverType(MAGNETOMETER);
139
-        instrument->SetReceiverType(INDUCTIVE);
140
-        // Set the pulse
141
-        VectorXr Amp(4); Amp << 0,1,1,0;
142
-        VectorXr Times(4); Times << 0., .0005, .02497, .025;
143
-
144
-        //VectorXr Amp(4); Amp << 0,1,1,0;
145
-        //VectorXr Times(4); Times << -0.025, -0.0245, -0.00003, 0.0;
146
-        //instrument->SetPulse(Amp, Times);
147
-
148
-        //VectorXr Amp(3); Amp << 0,1,0;
149
-        //VectorXr Times(3); Times << 0, .015, .030;
150
-        //instrument->SetPulse(Amp, Times);
151
-
152
-        //VectorXr Amp(3); Amp << 0,1,0;
153
-        //VectorXr Times(3); Times << 0, .01, .020;
154
-        instrument->SetPulse(Amp, Times);
155
-
156
-    std::cout << *Earth << "\n" << *Trans << "\n" << *Receivers << std::endl;
157
-
158
-	// Perform the forward model
159
-	//instrument->MakeDirectCalculation( FHTKEY201  );
160
-	//instrument->MakeLaggedCalculation( ANDERSON801 );
161
-	//instrument->MakeLaggedCalculation( QWEKEY );
162
-	//instrument->MakeLaggedCalculation( CHAVE );
163
-	instrument->MakeLaggedCalculation( FHTKEY201 );
164
-	//instrument->MakeLaggedCalculation( FHTKEY101 );
165
-
166
-    int nlag = instrument->GetMeasurements().rows();
167
-	// Output results to screen
168
-	for (int ii=0; ii<nlag; ii++) {
169
-		std::cout<<"  "<<instrument->GetMeasurements()(ii,0)<<"  "<<instrument->GetMeasurements()(ii,1)<<std::endl;
170
-	}
171
-
172
-	// Output results to file
173
-	std::ofstream outfile1;
174
-	outfile1.open("solution.out");
175
-    //outfile1 << "//timegate [ms]\t dB/dt [nT/s]" << std::endl;
176
-    outfile1 << "//timegate [s]\t dB/dt [T/s]" << std::endl;
177
-	for (int ii=0; ii<nlag; ii++) {
178
-		//outfile1 << 1e3*instrument->GetMeasurements()(ii,0)<< "\t" << (MU0*1e9)*instrument->GetMeasurements()(ii,1)<<std::endl;
179
-		outfile1 << instrument->GetMeasurements()(ii,0)<< "\t" << MU0*instrument->GetMeasurements()(ii,1) << std::endl;
180
-		//outfile1 << instrument->GetMeasurements()(ii,0)<< "\t" << instrument->GetMeasurements()(ii,1)<<std::endl;
181
-	}
182
-	outfile1.close();
183
-
184
-
185
-	// Timing stuff
186
-	std::cout << "  Time for execution: " <<  (clock()-launch)/CLOCKS_PER_SEC   << " [CPU] seconds."
187
-		 << std::endl;
188
-
189
-
190
-	instrument->Delete();
191
-	Trans->Delete();
192
-	Earth->Delete();
193
-	Receivers->Delete();
194
-	Reader->Delete();
195
-
196
-	return EXIT_SUCCESS;
197
-}
198
-
199
-

+ 0
- 131
Modules/LemmaCore/examples/utteminv1d.cpp Dosyayı Görüntüle

@@ -1,131 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  utteminv1d.cpp
4
-//
5
-//    Description:  Invert for the difference in water table
6
-//
7
-//        Version:  0.0
8
-//        Created:  03/23/2011 02:07:19 PM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++, icpc, and MSVC 2000
11
-//
12
-//         Author:  M. Andy Kass (MAK)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  Broken Spoke Development, LLC
16
-//
17
-//          Email:  mkass@numericalgeo.com
18
-//
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include "Lemma"
35
-#include "banner.h"
36
-
37
-using namespace Lemma;
38
-
39
-int main () {
40
-
41
-	VectorXr maintimes;
42
-	int ntimes;
43
-
44
-	//Banner
45
-	std::string name;
46
-	std::string version;
47
-	std::string usage;
48
-	name = "TEM Inversion - 1D";
49
-	version = "1.0beta";
50
-	usage = "teminv1d [inputfile]";
51
-	banner(name,version,usage);
52
-
53
-	PolygonalWireAntenna* Trans = PolygonalWireAntenna::New();
54
-	ReceiverPoints* Receivers = ReceiverPoints::New();
55
-	LayeredEarthEM* StartingMod = LayeredEarthEM::New();
56
-	//LayeredEarthEM* RecoveredMod = LayeredEarthEM::New();
57
-	InverseSolverTEM1D* Inverse = InverseSolverTEM1D::New();
58
-
59
-
60
-	Trans->SetNumberOfPoints(5);
61
-    Trans->SetPoint(0, Vector3r(   0,   0, -1e-3));
62
-    Trans->SetPoint(1, Vector3r( 100,   0, -1e-3));
63
-    Trans->SetPoint(2, Vector3r( 100, 100, -1e-3));
64
-    Trans->SetPoint(3, Vector3r(   0, 100, -1e-3));
65
-    Trans->SetPoint(4, Vector3r(   0,   0, -1e-3));
66
-	Trans->SetCurrent(1);
67
-	Trans->SetNumberOfTurns(1);
68
-    Trans->SetMinDipoleRatio(1/2.);
69
-
70
-	Vector3r loc;
71
-	Real ox = 50.;
72
-	Real oy = 50.;
73
-	Real depth = -1.e-3;
74
-	Receivers->SetNumberOfReceivers(1);
75
-	loc << ox,oy,depth;
76
-	Receivers->SetLocation(0,loc);
77
-
78
-	StartingMod->SetNumberOfLayers(22);
79
-	StartingMod->SetLayerConductivity( (VectorXcr(22) << 0.,1.e-3,
80
-		1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,
81
-		1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3,1.e-3).finished() );
82
-	StartingMod->SetLayerThickness((VectorXr(20)<<4,4,4,4,4,4,4,4,4,4,4,4,4,
83
-		4,4,4,4,4,4,4).finished());
84
-	//EM-47 gate times
85
-	ntimes = 30;
86
-	maintimes.resize(ntimes);
87
-	maintimes << 36.,45.25,57.,72.25,92.,117.,148.,186.5,234.,290.,
88
-		352.5,427.5,525.,647.5,802.5,1002.5,1257.5,1582.5,1997.5,2525.,
89
-		3197.5,4055.,5147.5,6542.5,8322.5,10592.,13490.,17187.,21902.,
90
-		27915.;
91
-	maintimes = maintimes.array() /1000000;
92
-
93
-	Inverse->AttachStartMod(StartingMod);
94
-	Inverse->AttachWireAntenna(Trans);
95
-	Inverse->AttachReceiver(Receivers);
96
-	Inverse->SetTimes(maintimes);
97
-	LayeredEarthEM* RecoveredMod = StartingMod->Clone();
98
-	Inverse->AttachRecMod(RecoveredMod);
99
-
100
-	//Read input data - temp for SEG!
101
-	/// TODO write a TEM data reader class.  and a functional TEM data class
102
-	std::fstream infile("rotateddat.dat",std::ios::in);
103
-	if (infile.fail()) {
104
-		std::cout << "Shit!" << std::endl;
105
-	}
106
-	MatrixXr rotinpdata;
107
-	rotinpdata.resize(30,1);
108
-	for (int ii=0;ii<30;ii++) {
109
-		infile >> rotinpdata(ii);
110
-	}
111
-	infile.close();
112
-
113
-
114
-	Inverse->AttachMeasuredData(rotinpdata);
115
-	//Inverse->SetFreeParams( (VectorXi(2)<<0,1).finished(),
116
-	//	(VectorXi(3)<<1,2,3).finished());
117
-
118
-	std::cout << *Inverse << std::endl;
119
-
120
-	Inverse->Calculate();
121
-	//Inverse->ShowSoln();
122
-	//Inverse->WriteSoln("temp.dat");
123
-
124
-	Inverse->Delete();
125
-	RecoveredMod->Delete();
126
-	StartingMod->Delete();
127
-	Receivers->Delete();
128
-	Trans->Delete();
129
-
130
-	return EXIT_SUCCESS;
131
-}

+ 0
- 84
Modules/LemmaCore/examples/uttemreader.cpp Dosyayı Görüntüle

@@ -1,84 +0,0 @@
1
-// ===========================================================================
2
-// 
3
-//       Filename:  uttemreader.cpp
4
-// 
5
-//    Description:  
6
-// 
7
-//        Version:  0.0
8
-//        Created:  02/19/2011 12:30:59 PM
9
-//       Revision:  none
10
-//       Compiler:  Tested with g++, icpc, and MSVC 2000 
11
-// 
12
-//         Author:  M. Andy Kass (MAK)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  Broken Spoke Brewery, LLC
16
-//
17
-//          Email:  mkass@numericalgeo.com
18
-// 
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include "Lemma"
35
-
36
-using namespace Lemma;
37
-
38
-
39
-int main() {
40
-
41
-	/*
42
-	ModelReaderTem1DUBC* Reader = ModelReaderTem1DUBC::New();
43
-	PolygonalWireAntenna* Trans = PolygonalWireAntenna::New();
44
-	ReceiverPoints *Receivers = ReceiverPoints::New();
45
-	LayeredEarthEM *Earth = LayeredEarthEM::New();
46
-	Reader->SetEMEarth1D(Earth);
47
-	Reader->SetTransmitter(Trans);
48
-	Reader->SetReceiver(Receivers);
49
-	Reader->ReadParameters("em1dtmfwd.in");
50
-
51
-	Reader->Delete();
52
-	Earth->Delete();
53
-	Receivers->Delete();
54
-	Trans->Delete();
55
-	*/
56
-
57
-	int rnObs;
58
-	int rnGates;
59
-	std::string inputfile;
60
-	MatrixXr somedata;
61
-	Vector3Xr somepositions;
62
-
63
-	DataTEM* TheData = DataTEM::New();
64
-	DataReaderTem* Reader = DataReaderTem::New();
65
-
66
-	inputfile = "temreadertest.txt";
67
-
68
-	Reader->SetDataTEM(TheData);
69
-	Reader->ReadData(inputfile);
70
-
71
-	rnObs = TheData->GetnObs();
72
-	rnGates = TheData->GetnGates();
73
-	somedata = TheData->GetData();
74
-	somepositions = TheData->GetPositions();
75
-
76
-	std::cout << rnObs << " " << rnGates << std::endl;
77
-	std::cout << somedata << std::endl;
78
-	std::cout << somepositions << std::endl;
79
-
80
-	Reader->Delete();
81
-	TheData->Delete();
82
-
83
-	return EXIT_SUCCESS;
84
-}

+ 0
- 207
Modules/LemmaCore/examples/uttemsandbox.cpp Dosyayı Görüntüle

@@ -1,207 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  uttemsandbox.cpp
4
-//
5
-//        Created:  09/29/2010 07:38:26 AM
6
-//       Compiler:  Tested with g++, icpc, and MSVC 2010
7
-//
8
-//         Author:  Trevor Irons (ti), M. Andy Kass
9
-//
10
-//
11
-//   Organisation:  Colorado School of Mines (CSM)
12
-//                  United States Geological Survey (USGS)
13
-//					Broken Spoke Development, LLC
14
-//
15
-//          Email:  tirons@mines.edu, tirons@usgs.gov
16
-//					mkass@numericalgeo.com
17
-//
18
-//  This program is free software: you can redistribute it and/or modify
19
-//  it under the terms of the GNU General Public License as published by
20
-//  the Free Software Foundation, either version 3 of the License, or
21
-//  (at your option) any later version.
22
-//
23
-//  This program is distributed in the hope that it will be useful,
24
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
25
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
26
-//  GNU General Public License for more details.
27
-//
28
-//  You should have received a copy of the GNU General Public License
29
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
30
-//
31
-// ===========================================================================
32
-
33
-/**
34
-  @file
35
-  @author   Trevor Irons
36
-  @date     09/29/2010
37
-  @version   0.0
38
- **/
39
-
40
-#include "Lemma"
41
-using namespace Lemma;
42
-
43
-#ifdef LEMMAUSEVTK
44
-#include "matplot.h"
45
-using namespace matplot;
46
-#endif
47
-
48
-int main() {
49
-
50
-
51
-    int nfreq  =    6000;  // Number of frequencies
52
-
53
-	// Specify receiver times
54
-	int ntimes	=	30;
55
-	VectorXr times(ntimes);
56
-	times <<
57
-	36.0, 45.25, 57.0, 72.25, 92.0,
58
-	117.0, 148.0, 186.5, 234.0, 290.0,
59
-	352.5, 427.5, 525.0, 647.5, 802.5,
60
-	1002.5, 1257.5, 1582.5, 1997.5, 2525.0,
61
-	3197.5, 4055.0, 5147.5, 6542.5, 8322.5,
62
-	10592.0, 13490.0, 17187.0, 21902.0, 27915.0;
63
-
64
-	times = times.array()*1.0e-6;
65
-
66
-	//CALCULATE ABSCISSA
67
-	//define bounds
68
-
69
-	gaussianquadrature *lgqw = gaussianquadrature::New();
70
-
71
-	Real lowb;
72
-	Real upb;
73
-	lowb = 1.0;
74
-	upb = 6000000.0;
75
-	lgqw->SetFreqs(nfreq,upb,lowb);
76
-	lgqw->CalcAW();
77
-
78
-	VectorXr xu(nfreq);
79
-	xu=lgqw->GetAbscissae();
80
-	DipoleSource* Trans=DipoleSource::New();
81
-	Trans->SetType(MAGNETICDIPOLE);
82
-	Trans->SetPolarisation(ZPOLARISATION);
83
-	Trans->SetLocation(0.0,0.0,-1e-4);
84
-
85
-
86
-    // Specify Transmitter
87
-    //PolygonalWireAntenna* Trans  = PolygonalWireAntenna::New();
88
-    //Trans->SetNumberOfPoints(5);
89
-    //Trans->SetPoint(0, Vector3r(   0,   0, -1e-3));
90
-    //Trans->SetPoint(1, Vector3r( 100,   0, -1e-3));
91
-    //Trans->SetPoint(2, Vector3r( 100, 100, -1e-3));
92
-    //Trans->SetPoint(3, Vector3r(   0, 100, -1e-3));
93
-    //Trans->SetPoint(4, Vector3r(   0,   0, -1e-3));
94
-    Trans->SetNumberOfFrequencies(nfreq);
95
-    VectorXr  f(nfreq);
96
-    for (int ifreq=0; ifreq<nfreq; ++ifreq) {
97
-    //    Trans->SetFrequency(ifreq, 1e-3 + dfreq*(Real)(ifreq));
98
-		Trans->SetFrequency(ifreq,xu(ifreq));
99
-        f(ifreq) = xu(ifreq);
100
-    }
101
-	//cout << Trans->GetFrequencies();
102
-    //Trans->SetCurrent(1);
103
-    //Trans->SetNumberOfTurns(1);
104
-
105
-    // Earth properties, top layer is air layer 0 conductivity is fine
106
-    LayeredEarthEM *Earth = LayeredEarthEM::New();
107
-        Earth->SetNumberOfLayers(4);
108
-        Earth->SetLayerConductivity( (VectorXcr(4) << 0.,1.e-6,1.e-2,1.e-6 ).finished() );
109
-        Earth->SetLayerThickness( (VectorXr(2) << 50, 20).finished() );
110
-
111
-    // Receivers, just 1 in the centre for now
112
-   	ReceiverPoints *Receivers = ReceiverPoints::New();
113
-		Vector3r loc;
114
-		Real ox     =    50.;
115
-		Real oy     =    50.;
116
-		Real depth  =  -1e-2;
117
-		Receivers->SetNumberOfReceivers(1);
118
-		loc << ox, oy, depth;
119
-		Receivers->SetLocation(0, loc);
120
-
121
-	// EmEarth
122
-	EMEarth1D  *EmEarth = EMEarth1D::New();
123
-		//EmEarth->AttachWireAntenna(Trans);
124
-		EmEarth->AttachDipoleSource(Trans);
125
-		EmEarth->AttachLayeredEarthEM(Earth);
126
-		EmEarth->AttachReceiverPoints(Receivers);
127
-		EmEarth->SetFieldsToCalculate(H);
128
-        // slower but may be more accurate, depending on frequencies
129
-        EmEarth->SetHankelTransformMethod(CHAVE);
130
-        //EmEarth->SetHankelTransformMethod(DIGITALFILTERING);
131
-
132
-    // Do calculation
133
-   	//EmEarth->CalculateWireAntennaFields();
134
-	//EmEarth->MakeCalc();
135
-	EmEarth->MakeCalc3();
136
-
137
-    // Grab Z component
138
-    // A little painful, I'll try to clean up the API
139
-    VectorXcr Hw(nfreq);
140
-    VectorXr  e(nfreq);
141
-    Hw(0) = 0.; // DC component
142
-    for (int ifreq=0; ifreq<nfreq; ++ifreq) {
143
-        Hw(ifreq) = (Receivers->GetHfield(ifreq, 0))(2);
144
-        e(ifreq) = ifreq;
145
-    }
146
-
147
-    VectorXr Ht(ntimes);                   // Time domain H field
148
-
149
-	//Sine transform
150
-	VectorXr func(nfreq);
151
-	for (int ii=0;ii<ntimes;++ii) {
152
-		func = (Hw.imag().array()*((f.array()*times(ii)).sin()));
153
-		lgqw->SetFunc(func);
154
-		lgqw->Integrate();
155
-		Ht(ii)=lgqw->GetResult();
156
-	}
157
-	Ht = Ht.array()*(-2.0/PI);
158
-
159
-	std::ofstream myfile1;
160
-	myfile1.open("solution.txt");
161
-	for (int ii=0;ii<ntimes;++ii) {
162
-		myfile1 << times(ii) << "   " << Ht(ii) << std::endl;
163
-	}
164
-	myfile1.close();
165
-
166
-	std::ofstream myfile2;
167
-	myfile2.open("freq_domain.txt");
168
-	for (int ii=0;ii<nfreq;++ii) {
169
-		myfile2 << f(ii) << "  " << Hw(ii).real() << "  " << Hw(ii).imag()
170
-			<< std::endl;
171
-	}
172
-	myfile2.close();
173
-
174
-    //std::cout << Ht << std::endl;
175
-    //std::cout << Hw.real() << std::endl;
176
-
177
-    // Quick and dirty plot
178
-    #ifdef  LEMMAUSEVTK
179
-    double colour1[3] = {0.0,0.0,1.0};
180
-    double colour2[3] = {1.0,0.0,0.0};
181
-
182
-    Plot2D_VTK p1("Hz", "Re(Hw)", 800, 600);
183
-    p1.plot(f, Hw.real().eval(), colour1, ".-");
184
-    p1.show();
185
-
186
-    Plot2D_VTK p2("Hz", "Im(Hw)", 800, 600);
187
-    p2.plot(f, Hw.imag().eval(), colour2, ".-");
188
-    p2.show();
189
-
190
-    Plot2D_VTK p3("Time (seconds)", "Ht", 800, 600);
191
-    p3.plot(times, Ht, colour2, ".-");
192
-    p3.show();
193
-
194
-	//Plot2D_VTK p4("index", "frequency",800,600);
195
-	//p4.plot(e,f,colour1,".-");
196
-	//p4.show();
197
-
198
-    #endif
199
-
200
-    // Clean up
201
-    Trans->Delete();
202
-    Earth->Delete();
203
-    Receivers->Delete();
204
-    EmEarth->Delete();
205
-
206
-    return EXIT_SUCCESS;
207
-}

+ 0
- 319
Modules/LemmaCore/examples/wireantenna.cpp Dosyayı Görüntüle

@@ -1,319 +0,0 @@
1
-// ===========================================================================
2
-//
3
-//       Filename:  utdipolesource.cpp
4
-//
5
-//    Description:
6
-//
7
-//        Version:  0.0
8
-//        Created:  12/02/2009 11:57:14 AM
9
-//       Revision:  none
10
-//       Compiler:  g++ (c++)
11
-//
12
-//         Author:  Trevor Irons (ti)
13
-//
14
-//   Organisation:  Colorado School of Mines (CSM)
15
-//                  United States Geological Survey (USGS)
16
-//
17
-//          Email:  tirons@mines.edu, tirons@usgs.gov
18
-//
19
-//  This program is free software: you can redistribute it and/or modify
20
-//  it under the terms of the GNU General Public License as published by
21
-//  the Free Software Foundation, either version 3 of the License, or
22
-//  (at your option) any later version.
23
-//
24
-//  This program is distributed in the hope that it will be useful,
25
-//  but WITHOUT ANY WARRANTY; without even the implied warranty of
26
-//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
27
-//  GNU General Public License for more details.
28
-//
29
-//  You should have received a copy of the GNU General Public License
30
-//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
31
-//
32
-// ===========================================================================
33
-
34
-#include <iostream>
35
-#include <fstream>
36
-
37
-#include "dipolesource.h"
38
-#include "layeredearth.h"
39
-#include "receiverpoints.h"
40
-#include "emearth1d.h"
41
-#include "WireAntenna.h"
42
-#include "PolygonalWireAntenna.h"
43
-
44
-#if  LEMMAUSEVTK
45
-#include "vtkRenderer.h"
46
-#include "vtkRenderWindow.h"
47
-#include "vtkRenderWindowInteractor.h"
48
-#include "vtkRenderLargeImage.h"
49
-#include "vtkPNGWriter.h"
50
-#endif     // -----  not LEMMA_USE_VTK  -----
51
-
52
-// For testing purposes disable VTK and run scale.sh
53
-//#undef LEMMAUSEVTK
54
-
55
-#include "timer.h"
56
-
57
-using namespace Lemma;
58
-
59
-double randDouble(double low, double high) {
60
-	//srand(time(0));
61
-	double temp;
62
-	/* swap low & high around if the user makes no sense */
63
-	if (low > high)	{
64
-	temp = low;
65
-	low = high;
66
-	high = temp;
67
-	}
68
-	/* calculate the random number & return it */
69
-	temp = (rand() / (static_cast<double>(RAND_MAX) + 1.0))
70
-	* (high - low) + low;
71
-	return temp;
72
-}
73
-
74
-
75
-int main() {
76
-
77
-	// Keep track of time
78
-	jsw_timer timer;
79
-
80
-
81
-	srand(time(0));
82
-
83
-	PolygonalWireAntenna *pa = PolygonalWireAntenna::New();
84
-	pa->SetNumberOfFrequencies(1);
85
-	pa->SetFrequency(0, 1000);
86
-	pa->SetNumberOfPoints(5);
87
-	pa->SetPoint(0, Vector3r(   0,   0, -.001));
88
-	pa->SetPoint(1, Vector3r( 100,   0, -.001));
89
-	pa->SetPoint(2, Vector3r( 100, 100, -.001));
90
-	pa->SetPoint(3, Vector3r(   0, 100, -.001));
91
-	pa->SetPoint(4, Vector3r(   0,   0, -.001));
92
-	pa->SetCurrent(1.);
93
-    pa->SetNumberOfTurns(1);
94
-	//Vector3r rp = Vector3r::Random(3);
95
-	//rp << 150., 10, 0.;
96
-	//rp << -27.1456, 15.2350, -1e-3;
97
-	//rp << randDouble(-35,35), randDouble(-35,35), randDouble(-35,35);
98
-	//rp << 3.22806, -13.1548, 14.9695;
99
-	//rp.setRandom(3);
100
-	//std::cout <<  "rp " << rp.transpose() << std::endl;
101
-	//pa->ApproximateWithElectricDipoles(rp);
102
-
103
-	WireAntenna *wire = WireAntenna::New();
104
-		wire->SetNumberOfPoints(5);
105
-		wire->SetPoint(0, Vector3r(   0,   0, -1e-3));
106
-		wire->SetPoint(1, Vector3r( 10,   0, -1e-3));
107
-		wire->SetPoint(2, Vector3r( 10, 10, -1e-3));
108
-		wire->SetPoint(3, Vector3r(   0, 10, -1e-3));
109
-		wire->SetPoint(4, Vector3r(   0,   0, -1e-3));
110
-		// TODO change wire antennae to use my class
111
-		//wire->SetNumberOfFrequencies(1);
112
-		wire->SetCurrent(1.);
113
-		wire->SetNumberOfFrequencies(1);
114
-		wire->SetFrequency(0, 1000);
115
-        wire->SetNumberOfTurns(1);
116
-		//wire->ApproximateWithElectricDipoles(5);
117
-
118
-	// Define model
119
-	VectorXcr sigma(2);
120
-		sigma << Complex(0.,0), Complex(.1,0);
121
-	VectorXr  thick(1);
122
-		thick << 10;
123
-	LayeredEarthEM *earth = LayeredEarthEM::New();
124
-		earth->SetNumberOfLayers(2);
125
-		earth->SetLayerConductivity(sigma);
126
-		//earth->SetLayerThickness(thick);
127
-
128
-	// Receivers
129
-	ReceiverPoints *receivers = ReceiverPoints::New();
130
-		Vector3r loc;
131
-		Real ox    =    50.561 ;
132
-		Real oy    =   105.235 ;
133
-		Real depth =    -3.75e1;
134
-		Real depth2 =   depth;
135
-		Real dx    =    1.;
136
-		int nz     =    1;
137
-		receivers->SetNumberOfReceivers(nz);
138
-		int ir = 0;
139
-		for (int iz=0; iz<nz; ++iz) {
140
-			loc << ox, oy, depth;
141
-			receivers->SetLocation(ir, loc);
142
-			depth += dx;
143
-			++ ir;
144
-		}
145
-
146
-	// EmEarth
147
-	EMEarth1D  *EmEarth = EMEarth1D::New();
148
-		//EmEarth->AttachWireAntenna(wire);
149
-		EmEarth->AttachWireAntenna(pa);
150
-		EmEarth->AttachLayeredEarthEM(earth);
151
-		EmEarth->AttachReceiverPoints(receivers);
152
-		EmEarth->SetFieldsToCalculate(H);
153
-        //EmEarth->SetHankelTransformMethod(GAUSSIANQUADRATURE);
154
-
155
-	// Do calculation
156
-	timer.begin();
157
-	EmEarth->CalculateWireAntennaFields();
158
-	Real paTime = timer.end();
159
-	std::cout << "Polygonal wire antennae time: " << paTime << "\n";
160
-
161
-	//EmEarth->AttachWireAntenna(wire);
162
-	//timer.begin();
163
-	//EmEarth->CalculateWireAntennaFields();
164
-	//Real waTime = timer.end();
165
-	//std::cout << "Fixed wire antennae time: " << waTime << "\n";
166
-
167
-	depth = depth2;
168
-	std::fstream real("reale_lay.dat", std::ios::out);
169
-	std::fstream imag("image_lay.dat", std::ios::out);
170
-	std::fstream hreal("real_lay.dat", std::ios::out);
171
-	std::fstream himag("imag_lay.dat", std::ios::out);
172
-	for (int iz=0; iz<nz; ++iz) {
173
-		Vector3cr temp = receivers->GetEfield(0,iz);
174
-		real << ox << "\t" << oy << "\t" << depth << "\t"
175
-				<< temp(0).real() << "\t" << temp(1).real()
176
-				<< "\t" << temp(2).real() << std::endl;
177
-		imag << ox << "\t" << oy << "\t" << depth << "\t"
178
-				<< std::imag(temp(0)) << "\t" << std::imag(temp(1))
179
-				<< "\t" << std::imag(temp(2)) << std::endl;
180
-		temp = receivers->GetHfield(0, iz);
181
-		hreal << ox << "\t" << oy << "\t" << depth << "\t"
182
-				<< std::real(temp(0)) << "\t" << std::real(temp(1))
183
-				<< "\t" << std::real(temp(2)) << std::endl;
184
-		himag << ox << "\t" << oy << "\t" << depth << "\t"
185
-				<< std::imag(temp(0)) << "\t" << std::imag(temp(1))
186
-				<< "\t" << std::imag(temp(2)) << std::endl;
187
-		depth += dx;
188
-	}
189
-	real.close();
190
-	imag.close();
191
-	hreal.close();
192
-	himag.close();
193
-	EmEarth->Delete();
194
-	receivers->Delete();
195
-	earth->Delete();
196
-	//wire->Delete();
197
-
198
-#if  LEMMAUSEVTK
199
-	// Create the usual rendering stuff.
200
-	vtkRenderer           *renderer = vtkRenderer::New();
201
-	vtkRenderWindow         *renWin = vtkRenderWindow::New();
202
-	vtkRenderWindowInteractor *iren = vtkRenderWindowInteractor::New();
203
-
204
-	// Line of tx
205
-	vtkLineSource       *vline = vtkLineSource::New();
206
-	vtkTubeFilter       *vTube = vtkTubeFilter::New();
207
- 	vtkPolyDataMapper   *vMapper = vtkPolyDataMapper::New();
208
-	vtkActor             *vActor = vtkActor::New();
209
-	vline->SetPoint1(0,0,0);
210
-	vline->SetPoint2(10,0,0);
211
-
212
-	vTube->SetInputConnection(vline->GetOutputPort());
213
-	vTube->SetRadius(.2);
214
-	vTube->SetNumberOfSides(6);
215
-	vMapper->SetInputConnection(vTube->GetOutputPort());
216
-	vActor->SetMapper(vMapper);
217
-	vActor->GetProperty()->SetColor(0.0, .0, 1.0);
218
-	vActor->GetProperty()->SetOpacity(.15);
219
-	renderer->AddActor(vActor);
220
-
221
-	vtkLineSource       *vline2 = vtkLineSource::New();
222
-	vtkTubeFilter       *vTube2 = vtkTubeFilter::New();
223
- 	vtkPolyDataMapper   *vMapper2 = vtkPolyDataMapper::New();
224
-	vtkActor             *vActor2 = vtkActor::New();
225
-	vline2->SetPoint1(10,0,0);
226
-	vline2->SetPoint2(10,10,0);
227
-
228
-	vTube2->SetInputConnection(vline2->GetOutputPort());
229
-	vTube2->SetRadius(.2);
230
-	vTube2->SetNumberOfSides(6);
231
-	vMapper2->SetInputConnection(vTube2->GetOutputPort());
232
-	vActor2->SetMapper(vMapper2);
233
-	vActor2->GetProperty()->SetColor(0.0, .0, 1.0);
234
-	vActor2->GetProperty()->SetOpacity(.15);
235
-	renderer->AddActor(vActor2);
236
-
237
-	vtkLineSource       *vline3 = vtkLineSource::New();
238
-	vtkTubeFilter       *vTube3 = vtkTubeFilter::New();
239
- 	vtkPolyDataMapper   *vMapper3 = vtkPolyDataMapper::New();
240
-	vtkActor             *vActor3 = vtkActor::New();
241
-	vline3->SetPoint1(10,10,0);
242
-	vline3->SetPoint2(0,10,0);
243
-
244
-	vTube3->SetInputConnection(vline3->GetOutputPort());
245
-	vTube3->SetRadius(.2);
246
-	vTube3->SetNumberOfSides(6);
247
-	vMapper3->SetInputConnection(vTube3->GetOutputPort());
248
-	vActor3->SetMapper(vMapper3);
249
-	vActor3->GetProperty()->SetColor(0.0, .0, 1.0);
250
-	vActor3->GetProperty()->SetOpacity(.15);
251
-	renderer->AddActor(vActor3);
252
-
253
-	vtkLineSource       *vline4 = vtkLineSource::New();
254
-	vtkTubeFilter       *vTube4 = vtkTubeFilter::New();
255
- 	vtkPolyDataMapper   *vMapper4 = vtkPolyDataMapper::New();
256
-	vtkActor             *vActor4 = vtkActor::New();
257
-	vline4->SetPoint1(0,10,0);
258
-	vline4->SetPoint2(0,0,0);
259
-
260
-	vTube4->SetInputConnection(vline4->GetOutputPort());
261
-	vTube4->SetRadius(.2);
262
-	vTube4->SetNumberOfSides(6);
263
-	vMapper4->SetInputConnection(vTube4->GetOutputPort());
264
-	vActor4->SetMapper(vMapper4);
265
-	vActor4->GetProperty()->SetColor(0.0, .0, 1.0);
266
-	vActor4->GetProperty()->SetOpacity(.15);
267
-	renderer->AddActor(vActor4);
268
-
269
-    loc << 50, 50, -1e-3;
270
-	pa->ApproximateWithElectricDipoles(loc);
271
-
272
-    vtkActor **pdipActors = new vtkActor*[pa->GetNumberOfDipoles()];
273
-    std::cout <<  "Wire approximated with " << pa->GetNumberOfDipoles() << std::endl;
274
-	for (int id=0; id<pa->GetNumberOfDipoles(); ++id) {
275
-		pdipActors[id] = pa->GetVtkActor(id);
276
-		renderer->AddActor(pdipActors[id]);
277
-	}
278
-
279
-    /*
280
-    vtkActor **dipActors = new vtkActor*[wire->GetNumberOfDipoles()];
281
-	for (int id=0; id<wire->GetNumberOfDipoles(); ++id) {
282
-		dipActors[id] = wire->GetVtkActor(id);
283
-		renderer->AddActor(dipActors[id]);
284
-	}
285
-    */
286
-
287
-	renderer->SetBackground(1,1,1);
288
-
289
-	// Render the window
290
-	renWin->AddRenderer(renderer);
291
-	renWin->SetWindowName("Wire antennae");
292
-
293
-	iren->SetRenderWindow(renWin);
294
-	iren->Initialize();
295
-	iren->Start();
296
-	iren->Render();
297
-
298
-    #if 0
299
-	cout << "Enter File name?: ";
300
-	std::string pngName;
301
-	std::cin >> pngName;
302
-	vtkPNGWriter *pngwrite = vtkPNGWriter::New();
303
-	vtkRenderLargeImage *renlarge = vtkRenderLargeImage::New();
304
-	renlarge->SetInput(renderer);
305
-	renlarge->SetMagnification(2);
306
-	pngwrite->SetInputConnection(renlarge->GetOutputPort());
307
-	pngName.append(".png");
308
-	pngwrite->SetFileName(pngName.c_str());
309
-	pngwrite->Write();
310
-    #endif
311
-
312
-#endif     // -----  not LEMMA_USE_VTK  -----
313
-
314
-
315
-	//std::cout << *pa << std::endl;
316
-	//pa->Delete();
317
-
318
-	return 0;
319
-}

+ 5
- 1
Modules/LemmaCore/include/CubicSplineInterpolator.h Dosyayı Görüntüle

@@ -23,7 +23,11 @@
23 23
 
24 24
 namespace Lemma {
25 25
 
26
-// Simple struct to hold spline terms
26
+
27
+/**
28
+ * \brief Simple struct to hold spline terms
29
+ * \details This struct holds the actual knot and spline interpolation terms.
30
+ */
27 31
 struct SplineSet{
28 32
     VectorXr a;
29 33
     VectorXr b;

+ 28
- 20
Modules/LemmaCore/include/EarthModel.h Dosyayı Görüntüle

@@ -21,7 +21,7 @@ namespace Lemma {
21 21
     // ===================================================================
22 22
     //        Class:  EarthModel
23 23
     /// \ingroup LemmaCore
24
-    /// \brief abstract class for Earth models
24
+    /// \brief   abstract class for Earth models
25 25
     /// \details
26 26
     // ===================================================================
27 27
     class EarthModel : public LemmaObject {
@@ -58,40 +58,48 @@ namespace Lemma {
58 58
             void SetMagneticFieldComponents(const Vector3r &bfield,
59 59
                             const MAGUNITS &unit);
60 60
 
61
-            /// Sets the magnetic field using inclination, declination,
62
-            /// and magnitude, units of Tesla
63
-            /// @param[in] inc is the field's inclination
64
-            /// @param[in] dec is the field's declination
65
-            /// @param[in] Mag is the field's magnitude
66
-            /// @param[in] unit specifies the the units used.
67
-            /// The components are set according to
68
-            /// \f{eqnarray*} { B_x =& B \cos(inc (\pi/180)) \cos(dec (\pi/180))
69
-            ///            \\   B_y =& B \cos(inc (\pi/180)) \sin(dec (\pi/180))
70
-            ///            \\   B_z =& B \sin(inc (\pi/180))
71
-            /// \f}
61
+            /** Sets the magnetic field using inclination, declination,
62
+                and magnitude, units of Tesla
63
+                @param[in] inc is the field's inclination
64
+                @param[in] dec is the field's declination
65
+                @param[in] Mag is the field's magnitude
66
+                @param[in] unit specifies the the units used.
67
+                The components are set according to
68
+                \f{eqnarray*} { B_x =& B \cos(inc (\pi/180)) \cos(dec (\pi/180))
69
+                           \\   B_y =& B \cos(inc (\pi/180)) \sin(dec (\pi/180))
70
+                           \\   B_z =& B \sin(inc (\pi/180))
71
+                \f}
72
+             */
72 73
             void SetMagneticFieldIncDecMag(const Real& inc, const Real&dec,
73 74
                             const Real& Mag, const MAGUNITS &unit);
74 75
 
75 76
             // ====================  INQUIRY       =======================
76 77
 
77
-            /// Gets the magnetic field of the earth, in T
78
+            /** @return the magnetic field of the earth, in T
79
+             */
78 80
             Vector3r GetMagneticField( );
79 81
 
80
-            /// Gets the magnetic field of the earth, in T
82
+            /** @return the magnetic field of the earth, in Gauss
83
+             */
81 84
             Vector3r GetMagneticFieldInGauss(  );
82 85
 
83
-            /// Gets the magnetic field unit vector of the earth
86
+            /** @return the magnetic field unit vector of the earth
87
+             */
84 88
             Vector3r GetMagneticFieldUnitVector( );
85 89
 
86
-            /// Returns the magnitude of the magnetic field \f$ \Vert
87
-            /// \mathbf{B}_0 \Vert \f$
90
+            /** @return the magnitude of the magnetic field (in T)
91
+             * \f$ \Vert \mathbf{B}_0 \Vert \f$
92
+             */
88 93
             Real GetMagneticFieldMagnitude();
89 94
 
90
-            /// Returns the magnitude of the magnetic field \f$ \Vert
91
-            /// \mathbf{B}_0 \Vert \f$ in Gauss units
95
+            /** @return the magnitude of the magnetic field
96
+             *  \f$ \Vert \mathbf{B}_0 \Vert \f$ in Gauss units
97
+             */
92 98
             Real GetMagneticFieldMagnitudeInGauss( );
93 99
 
94
-            /** Returns the name of the underlying class, similiar to Python's type */
100
+            /** @return the name of the underlying class, similiar to Python's
101
+                        type
102
+             */
95 103
             virtual inline std::string GetName() const;
96 104
 
97 105
         protected:

+ 0
- 1
Modules/LemmaCore/include/Filter.h Dosyayı Görüntüle

@@ -19,7 +19,6 @@ namespace Lemma {
19 19
     // ===================================================================
20 20
     //  Class:  Filter
21 21
     /**
22
-      @class  Filter
23 22
       \ingroup LemmaCore
24 23
       \brief  Abstract class for filtering.
25 24
       \details Derived classes include fourier domain and time domain filters.

+ 0
- 1
Modules/LemmaCore/include/GridReader.h Dosyayı Görüntüle

@@ -24,7 +24,6 @@
24 24
 namespace Lemma {
25 25
 
26 26
     /**
27
-      @class
28 27
       \ingroup LemmaCore
29 28
       \brief   Abstract class for grid readers.
30 29
       \details Provides a consistent interface for reading grid files in Lemma.

+ 0
- 1
Modules/LemmaCore/include/RectilinearGridReader.h Dosyayı Görüntüle

@@ -25,7 +25,6 @@
25 25
 namespace Lemma {
26 26
 
27 27
     /**
28
-      @class
29 28
       \ingroup LemmaCore
30 29
       \brief   Base Class for rectilinear grid reader data files
31 30
       \details

+ 0
- 1
Modules/LemmaCore/include/WindowFilter.h Dosyayı Görüntüle

@@ -20,7 +20,6 @@ namespace Lemma {
20 20
     // ===================================================================
21 21
     //  Class:  WindowFilter
22 22
     /**
23
-      @class   WindowFilter
24 23
       \ingroup LemmaCore
25 24
       \brief   Fourier domain window filter.
26 25
       \details Current types are Hamming and Hanning. Others to be added.

+ 3
- 0
Modules/LemmaCore/include/helper.h Dosyayı Görüntüle

@@ -182,6 +182,9 @@ struct convert<Lemma::Vector3Xr> {
182 182
   }
183 183
 };
184 184
 
185
+/**
186
+ *   \brief Serializes and Deserializes VectorXr arrays
187
+ */
185 188
 template<>
186 189
 struct convert<Lemma::VectorXr> {
187 190
   static Node encode(const Lemma::VectorXr& rhs) {

+ 0
- 0
Modules/Optimization/CMakeLists.txt Dosyayı Görüntüle


+ 0
- 98
Modules/Optimization/include/bicgstab.h Dosyayı Görüntüle

@@ -1,98 +0,0 @@
1
-/*
2
- modifed from http://www.netlib.org/templates/cpp//
3
- Iterative template routine -- BiCGSTAB
4
-
5
- BiCGSTAB solves the unsymmetric linear system Ax = b
6
- using the Preconditioned BiConjugate Gradient Stabilized method
7
-
8
- BiCGSTAB follows the algorithm described on p. 27 of the
9
- SIAM Templates book.
10
-
11
- The return value indicates convergence within max_iter (input)
12
- iterations (0), or no convergence within max_iter iterations (1).
13
-
14
- Upon successful return, output arguments have the following values:
15
-
16
-        x  --  approximate solution to Ax = b
17
- max_iter  --  the number of iterations performed before the
18
-               tolerance was reached
19
-      tol  --  the residual after the final iteration
20
-*/
21
-
22
-#include <iostream>
23
-#include <fstream>
24
-#include "lemma.h"
25
-
26
-namespace Lemma {
27
-
28
-    template <typename Scalar>
29
-    VectorXr BiCGSTAB(const MatrixXr &A, const VectorXr &x0, const VectorXr &b,
30
-          const MatrixXr &M, int &max_iter, Scalar& tol) {
31
-        Scalar resid;
32
-        Scalar rho_1(0), rho_2(0), alpha(0), beta(0), omega(0);
33
-        VectorXr p, phat, s, shat, t, v;
34
-        VectorXr x = x0;
35
-        Scalar normb = b.norm();
36
-        VectorXr r = b - A * x;
37
-        VectorXr rtilde = r;
38
-
39
-        if (normb == 0.0)
40
-          normb = 1;
41
-
42
-        if ((resid = r.norm() / normb) <= tol) {
43
-          tol = resid;
44
-          max_iter = 0;
45
-          //return 0;
46
-          return x;
47
-        }
48
-
49
-        for (int i = 1; i <= max_iter; i++) {
50
-          rho_1 = rtilde.dot(r);
51
-          if (rho_1 == 0) {
52
-            tol = r.norm() / normb;
53
-            //return 2;
54
-            return x;
55
-          }
56
-          if (i == 1)
57
-            p = r;
58
-          else {
59
-            beta = (rho_1/rho_2) * (alpha/omega);
60
-            p = r + beta * (p - omega * v);
61
-          }
62
-          phat = M*p; //M.solve(p);
63
-          v = A * phat;
64
-          alpha = rho_1 / rtilde.dot(v);
65
-          s = r - alpha * v;
66
-          if ((resid = s.norm()/normb) < tol) {
67
-            x += alpha * phat;
68
-            tol = resid;
69
-            //return 0;
70
-            return x;
71
-          }
72
-          shat = M*s;//M.solve(s);
73
-          t = A * shat;
74
-          omega = t.dot(s) / t.dot(t);
75
-          x += alpha * phat + omega * shat;
76
-          r = s - omega * t;
77
-
78
-          rho_2 = rho_1;
79
-          if ((resid = r.norm() / normb) < tol) {
80
-            tol = resid;
81
-            max_iter = i;
82
-            //return 0;
83
-            return x;
84
-          }
85
-          if (omega == 0) {
86
-            tol = r.norm() / normb;
87
-            //return 3;
88
-            return x;
89
-          }
90
-        }
91
-
92
-        tol = resid;
93
-        return x;
94
-    }
95
-}
96
-
97
-/* vim: set tabstop=4 expandtab: */
98
-/* vim: set filetype=cpp: */

+ 0
- 437
Modules/Optimization/include/cg.h Dosyayı Görüntüle

@@ -1,437 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API */
2
-
3
-/* This Source Code Form is subject to the terms of the Mozilla Public
4
- * License, v. 2.0. If a copy of the MPL was not distributed with this
5
- * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
6
-
7
-/**
8
-  @file
9
-  @author   Trevor Irons
10
-  @version  $Id: cg.h 87 2013-09-05 22:44:05Z tirons $
11
- **/
12
-
13
-#ifndef  CG_INC
14
-#define  CG_INC
15
-
16
-
17
-#include <iostream>
18
-#include <fstream>
19
-#include "lemma.h"
20
-
21
-namespace Lemma {
22
-
23
-    /** Port of netlib.org http://www.netlib.org/templates/cpp//cg.h
24
-     *  Solves the symmetric postive definite system Ax=b.
25
-     *  No preconditioner is used.
26
-     *  Iterative template routine -- CG
27
-     *
28
-     *  CG solves the symmetric positive definite linear
29
-     *  system Ax=b using the Conjugate Gradient method.
30
-     *
31
-     *  CG follows the algorithm described on p. 15 in the
32
-     *  SIAM Templates book.
33
-     *
34
-     *  The return value indicates convergence within max_iter (input)
35
-     *  iterations (0), or no convergence within max_iter iterations (1).
36
-     *
37
-     *  Upon successful return, output arguments have the following values:
38
-     *
39
-     *         x  --  approximate solution to Ax = b
40
-     *  max_iter  --  the number of iterations performed before the
41
-     *                tolerance was reached
42
-     *       tol  --  the residual after the final iteration
43
-     *  @param[in] A is a Real matrix A to be solved.
44
-     *  @param[in] x0 is the starting model.
45
-     *  @param[in] b is the right hand side.
46
-     */
47
-    template < typename Scalar >
48
-    VectorXr CG(const MatrixXr &A, const VectorXr &x0, const VectorXr &b,
49
-        int &max_iter, Scalar &tol) {
50
-
51
-        VectorXr p, q;
52
-        Scalar alpha, beta, rho, rho_1(0);
53
-        VectorXr x = x0;
54
-        Scalar normb = b.norm( );
55
-        VectorXr r = b - A*x;
56
-
57
-        if (normb == 0.0) {
58
-            normb = 1;
59
-        }
60
-
61
-        Scalar resid = r.norm() / normb;
62
-        if (resid <= tol) {
63
-            tol = resid;
64
-            max_iter = 0;
65
-            return x;
66
-        }
67
-
68
-        for (int i = 1; i <= max_iter; i++) {
69
-
70
-            rho = r.transpose()*r;
71
-
72
-            if (i == 1) {
73
-                p = r;
74
-            }
75
-            else {
76
-                beta = rho / rho_1;
77
-                p = r + beta * p;
78
-            }
79
-
80
-            q = A*p;
81
-            alpha = rho / p.dot(q);
82
-
83
-            x += alpha * p;
84
-            r -= alpha * q;
85
-
86
-            if ((resid = r.norm() / normb) <= tol) {
87
-                tol = resid;
88
-                max_iter = i;
89
-                return x;
90
-            }
91
-            rho_1 = rho;
92
-        }
93
-        tol = resid;
94
-        std::cerr << "CG FAILED TO REACH CONVERGENCE\n";
95
-        return x;
96
-    }
97
-
98
-    // Specialised routine that appliex mod(Ax) so that b and x are in real, but
99
-    // A is complex.
100
-    template < typename Scalar >
101
-    VectorXr CG_ModulusAx(const MatrixXcr &A, const VectorXr &x0, const VectorXr &b,
102
-        int &max_iter, Scalar &tol) {
103
-
104
-        VectorXr p, q;
105
-        Scalar beta, rho, rho_1(0);
106
-        Scalar alpha;
107
-        VectorXr x = x0;
108
-        Scalar normb = b.norm( );
109
-        VectorXr r = b.array() - (A*x).array().abs();
110
-
111
-        if (normb == 0.0) {
112
-            normb = 1;
113
-        }
114
-
115
-        Scalar resid = r.norm() / normb;
116
-        if (resid <= tol) {
117
-            tol = resid;
118
-            max_iter = 0;
119
-            return x;
120
-        }
121
-
122
-        for (int i = 1; i <= max_iter; i++) {
123
-
124
-            rho = r.dot(r); //conjugate().transpose()*r;
125
-
126
-            if (i == 1) {
127
-                p = r;
128
-            }
129
-            else {
130
-                beta = rho / rho_1;
131
-                p = r + beta * p;
132
-            }
133
-
134
-            q = (A*p).array().abs();
135
-            alpha = rho / p.dot(q);
136
-
137
-            x += alpha * p;
138
-            r -= alpha * q;
139
-
140
-            if ((resid = r.norm() / normb) <= tol) {
141
-                tol = resid;
142
-                max_iter = i;
143
-                return x;
144
-            }
145
-            rho_1 = rho;
146
-        }
147
-
148
-        tol = resid;
149
-        std::cerr << "CG FAILED TO REACH CONVERGENCE\n";
150
-        return x;
151
-    }
152
-
153
-// Preconditioned version of above
154
-//*****************************************************************
155
-// Iterative template routine -- CG
156
-//
157
-// CG solves the symmetric positive definite linear
158
-// system Ax=b using the Conjugate Gradient method.
159
-//
160
-// CG follows the algorithm described on p. 15 in the
161
-// SIAM Templates book.
162
-//
163
-// The return value indicates convergence within max_iter (input)
164
-// iterations (0), or no convergence within max_iter iterations (1).
165
-//
166
-// Upon successful return, output arguments have the following values:
167
-//
168
-//        x  --  approximate solution to Ax = b
169
-// max_iter  --  the number of iterations performed before the
170
-//               tolerance was reached
171
-//      tol  --  the residual after the final iteration
172
-//
173
-//*****************************************************************
174
-
175
-//template < class Matrix, class Vector, class Preconditioner, class Real >
176
-//int
177
-//CG(const Matrix &A, Vector &x, const Vector &b,
178
-//   const Preconditioner &M, int &max_iter, Real &tol)
179
-//{
180
-    #include <limits>
181
-    template <typename Preconditioner>
182
-    VectorXr CG(const MatrixXr &A, const VectorXr &x0, const VectorXr &b,
183
-        const Preconditioner &M, int &max_iter, Real &tol) {
184
-        //const Eigen::SparseMatrix<Real> &M, int &max_iter, Real &tol) {
185
-
186
-        VectorXr p, z, q;
187
-        VectorXr x = x0;
188
-        Real alpha(0), beta(0), rho(0), rho_1(0);
189
-        Real normb;
190
-        VectorXr r;
191
-        #ifdef LEMMAUSEOMP
192
-        #pragma omp parallel sections
193
-        {
194
-        #endif
195
-            #ifdef LEMMAUSEOMP
196
-            #pragma omp section
197
-            #endif
198
-            {
199
-                normb = b.norm();
200
-            }
201
-            #ifdef LEMMAUSEOMP
202
-            #pragma omp section
203
-            #endif
204
-            {
205
-                r = b - A*x;
206
-            }
207
-        #ifdef LEMMAUSEOMP
208
-        }
209
-        #endif
210
-        if (normb <= std::numeric_limits<double>::epsilon() ) {
211
-            normb = 1;
212
-        }
213
-        Real resid = r.norm() / normb;
214
-        if (resid <= tol) {
215
-            tol = resid;
216
-            max_iter = 0;
217
-            return x;
218
-        }
219
-        // todo do 0th loop manually, gets rid of if statement
220
-        for (int i = 1; i <= max_iter; i++) {
221
-            z = M.solve(r);
222
-            //z = M*r;
223
-            rho = r.transpose()*z;
224
-            if (i == 1) {
225
-                p = z;
226
-            } else {
227
-                beta = rho / rho_1;
228
-                p = z + beta * p;
229
-            }
230
-            q = A*p;
231
-            alpha = rho / p.dot(q);
232
-            #ifdef LEMMAUSEOMP
233
-            #pragma omp parallel sections
234
-            {
235
-            #endif
236
-                #ifdef LEMMAUSEOMP
237
-                #pragma omp section
238
-                #endif
239
-                {
240
-                    x += alpha * p;
241
-                }
242
-                #ifdef LEMMAUSEOMP
243
-                #pragma omp section
244
-                #endif
245
-                {
246
-                    r -= alpha * q;
247
-                }
248
-            #ifdef LEMMAUSEOMP
249
-            }
250
-            #endif
251
-            if ((resid = r.norm() / normb) <= tol) {
252
-               tol = resid;
253
-               max_iter = i;
254
-               return x;
255
-            }
256
-            rho_1 = rho;
257
-        }
258
-        tol = resid;
259
-        std::cerr << "Preconditioned CG failed to converge\n";
260
-        return x;
261
-    }
262
-
263
-    template < typename Scalar >
264
-    VectorXr CGJ(const MatrixXr &A, const VectorXr &x0, const VectorXr &b,
265
-        const Eigen::SparseMatrix<Scalar> &M, int &max_iter, Scalar &tol) {
266
-
267
-        VectorXr p, z, q;
268
-        VectorXr x = x0;
269
-        Scalar alpha(0), beta(0), rho(0), rho_1(0);
270
-        Scalar normb;
271
-        VectorXr r;
272
-        #ifdef LEMMAUSEOMP
273
-        #pragma omp parallel sections
274
-        {
275
-        #endif
276
-            #ifdef LEMMAUSEOMP
277
-            #pragma omp section
278
-            #endif
279
-            {
280
-                normb = b.norm();
281
-            }
282
-            #ifdef LEMMAUSEOMP
283
-            #pragma omp section
284
-            #endif
285
-            {
286
-                r = b - A*x;
287
-            }
288
-        #ifdef LEMMAUSEOMP
289
-        }
290
-        #endif
291
-        if (normb <= std::numeric_limits<double>::epsilon() ) {
292
-            normb = 1;
293
-        }
294
-        Scalar resid = r.norm() / normb;
295
-        if (resid <= tol) {
296
-            tol = resid;
297
-            max_iter = 0;
298
-            return x;
299
-        }
300
-        // todo do 0th loop manually, gets rid of if statement
301
-        for (int i = 1; i <= max_iter; i++) {
302
-            //z = M.solve(r);
303
-            z = M*r;
304
-            rho = r.transpose()*z;
305
-            if (i == 1) {
306
-                p = z;
307
-            } else {
308
-                beta = rho / rho_1;
309
-                p = z + beta * p;
310
-            }
311
-            q = A*p;
312
-            alpha = rho / p.dot(q);
313
-            #ifdef LEMMAUSEOMP
314
-            #pragma omp parallel sections
315
-            {
316
-            #endif
317
-                #ifdef LEMMAUSEOMP
318
-                #pragma omp section
319
-                #endif
320
-                {
321
-                    x += alpha * p;
322
-                }
323
-                #ifdef LEMMAUSEOMP
324
-                #pragma omp section
325
-                #endif
326
-                {
327
-                    r -= alpha * q;
328
-                }
329
-            #ifdef LEMMAUSEOMP
330
-            }
331
-            #endif
332
-            if ((resid = r.norm() / normb) <= tol) {
333
-               tol = resid;
334
-               max_iter = i;
335
-               return x;
336
-            }
337
-            rho_1 = rho;
338
-        }
339
-        tol = resid;
340
-        std::cerr << "Preconditioned CG failed to converge\n";
341
-        return x;
342
-    }
343
-
344
-    ///////////////////////////////////////////////////////
345
-    // Log Barrier
346
-    /** Solves one iteration, using implicit multiplication of At*b, and ATA.
347
-     *  @param[in] G is the sensitivity matrix to be inverted.
348
-     *  @param[in] WdTWd is the data weighting matrix, usually sparse.
349
-     *  @param[in] WmTWm is the model weighting matrix, usually sparse.
350
-     *  @param[in] X1 is a vector of the inverse of the current model X. Used in
351
-     *  log barrier. Should be computed as X1 = VectorXr( 1. / (x.array() - minVal ))
352
-     *  @param[in] Y1 is a vector of the inverse of the current model X. Used in
353
-     *  log barrier. Should be computed as X1 = VectorXr( 1. / (maxVal - x.array() ))
354
-     *  @param[in] X2 is the analaogous inverse of X^2 diagonal matrix, stored
355
-     *  as a Vector.
356
-     *  @param[in] Y2 is the analaogous inverse of (maxVal-X)^2 diagonal matrix, stored
357
-     *  as a Vector.
358
-     *  @param[in] D2 is the datamisfit vector, formally (d_predicted - d_observed).
359
-     *  @param[in,out] Mk is the input / output solution vector. The input value is
360
-     *  an itital guess, and output is the solution.
361
-     *  @param[in] Mr is the reference model.
362
-     *  @param[in] BETA is the regularisation (Tikhonov parameter) to apply
363
-     *  @param[in] P is a preconditioner of G. The product Pb ~ x
364
-     *  @param[in,out] max_iter is the number of iterations.
365
-     *  @param[in,out] tol is the desired tolerance on input, and achieved on
366
-     *  output.
367
-     */
368
-    template < typename  Scalar >
369
-    int implicit_log_CG(const MatrixXr& G, const MatrixXr& WdTWd, const VectorXr& WmTWm,
370
-				const VectorXr& X1, const VectorXr& X2,
371
-				const VectorXr& Y1, const VectorXr& Y2,
372
-				const VectorXr& D2, VectorXr& Mk, const VectorXr& Mr,
373
-				const Scalar& BETA, const MatrixXr& P,
374
-                int& max_iter, Scalar& tol) {
375
-
376
-        // TODO add WdTWD to this!
377
-
378
-        Scalar resid;
379
-        VectorXr p, z, q;
380
-        Scalar alpha(0), beta(0), rho(0), rho_1(0);
381
-
382
-        // Calculate 'B'
383
-        VectorXr delM = Mk - Mr;
384
-        VectorXr B = (-G.transpose()*D2).array() - BETA*((WmTWm.asDiagonal()*delM).array())
385
-                     + X1.array() + Y1.array();
386
-
387
-        Scalar normb = B.norm();
388
-
389
-        // Implicit calc of A*x
390
-        VectorXr Y = BETA*(WmTWm.asDiagonal()*Mk).array() +
391
-                (X2.asDiagonal()*Mk).array() + (Y2.asDiagonal()*Mk).array();
392
-        VectorXr Z = G*Mk;
393
-        VectorXr U = G.transpose()*Z;
394
-
395
-        VectorXr r = B - (Y + U);
396
-
397
-        if (normb == 0.0) normb = 1;
398
-
399
-        if ((resid = r.norm() / normb) <= tol) {
400
-            tol = resid;
401
-            max_iter = 0;
402
-            return 0;
403
-        }
404
-
405
-        for (int i = 1; i <= max_iter; i++) {
406
-            //z = M.solve(r); // we can solve directly z = P*r
407
-            z = P*r;
408
-            rho = r.dot(z);
409
-            if (i == 1)  p = z;
410
-            else {
411
-                beta = rho / rho_1;
412
-                p = beta * p;
413
- 	            p = p+z;
414
-            }
415
-            Y = BETA*(WmTWm.array()*p.array()) + X2.array()*p.array() + Y2.array()*p.array();
416
-            Z = G*p;
417
-            U = G.transpose()*Z;
418
-            q = Y+U;
419
-
420
-            alpha = rho / p.dot(q);
421
-
422
-            Mk = Mk + alpha * p;
423
-            r  = r - (alpha * q);
424
-
425
-            if ((resid = r.norm() / normb) <= tol) {
426
-                tol = resid;
427
-                max_iter = i;
428
-                return 0;
429
-            }
430
-            rho_1 = rho;
431
-        }
432
-        tol = resid;
433
-        return 1;
434
-    }
435
-} // end of namespace Lemma
436
-
437
-#endif   // ----- #ifndef CG_INC  -----

+ 0
- 1366
Modules/Optimization/include/logbarriercg.h
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+ 0
- 1956
Modules/Optimization/include/logbarriercg_newton.h
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+ 0
- 111
Modules/Optimization/include/quasinewtonbfgs.h Dosyayı Görüntüle

@@ -1,111 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API */
2
-
3
-/* This Source Code Form is subject to the terms of the Mozilla Public
4
- * License, v. 2.0. If a copy of the MPL was not distributed with this
5
- * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
6
-
7
-/**
8
-  @file
9
-  @author   Trevor Irons
10
-  @date     08/09/2010
11
-  @version  $Id: quasinewtonbfgs.h 193 2014-11-10 23:51:41Z tirons $
12
- **/
13
-
14
-#ifndef  QUASINEWTONBFGS_INC
15
-#define  QUASINEWTONBFGS_INC
16
-
17
-#include "inversesolver.h"
18
-
19
-namespace Lemma {
20
-
21
-
22
-    // ===================================================================
23
-    //  Class:  QuasiNewtonBFGS
24
-    /**
25
-      @class  QuasiNewtonBFGS
26
-      \brief  Implimentation of a quasi-newton BFGS solver applied to
27
-              inverse problems.
28
-      \details Based of the algorithm described in Nocedal and Wright book.
29
-     */
30
-    // ===================================================================
31
-    class QuasiNewtonBFGS : public InverseSolver {
32
-
33
-        friend  std::ostream &operator<<(std::ostream &stream,
34
-                const QuasiNewtonBFGS &ob);
35
-
36
-        public:
37
-
38
-            // ====================  LIFECYCLE     =======================
39
-
40
-            /** Returns a pointer to a new object of type QuasiNewtonBFGS.
41
-             * It allocates all necessary memory.
42
-             */
43
-            static QuasiNewtonBFGS* New();
44
-
45
-            /**
46
-             * @copybrief LemmaObject::Delete()
47
-             * @copydetails LemmaObject::Delete()
48
-             */
49
-            void Delete();
50
-
51
-            // ====================  OPERATORS     =======================
52
-
53
-            // ====================  OPERATIONS    =======================
54
-
55
-            // ====================  ACCESS        =======================
56
-
57
-            // ====================  INQUIRY       =======================
58
-
59
-            /** @copybrief InverseSolver::NumberOfIterations()
60
-             *  @copydetails InverseSolver::NumberOfIterations()
61
-             */
62
-            int NumberOfIterations();
63
-
64
-            /** @copybrief InverseSolver::Success()
65
-             *  @copydetails InverseSolver::Success()
66
-             */
67
-            bool Success();
68
-
69
-            /** @copybrief InverseSolver::GetPhiMVector()
70
-             *  @copydetails InverseSolver::GetPhiMVector()
71
-             */
72
-            VectorXr GetPhiMVector();
73
-
74
-            /** @copybrief InverseSolver::GetPhiDVector()
75
-             *  @copydetails InverseSolver::GetPhiDVector()
76
-             */
77
-            VectorXr GetPhiDVector();
78
-
79
-            /// TODO remove this, test
80
-            void PrintNorm();
81
-
82
-        protected:
83
-
84
-            // ====================  LIFECYCLE     =======================
85
-
86
-            /// Default protected constructor.
87
-            QuasiNewtonBFGS (const std::string& cname);
88
-
89
-            /// Default protected constructor.
90
-            ~QuasiNewtonBFGS ();
91
-
92
-            /**
93
-             * @copybrief LemmaObject::Release()
94
-             * @copydetails LemmaObject::Release()
95
-             */
96
-            void Release();
97
-
98
-            // ====================  OPERATIONS    =======================
99
-
100
-            /// Just a filler
101
-            void FillInG(const Vector3r& pos, const Vector3r& step);
102
-
103
-            // ====================  DATA MEMBERS  =========================
104
-
105
-        private:
106
-
107
-    }; // -----  end of class  QuasiNewtonBFGS  -----
108
-
109
-}		// -----  end of Lemma  name  -----
110
-
111
-#endif   // ----- #ifndef QUASINEWTONBFGS_INC  -----

+ 0
- 85
Modules/Optimization/src/quasinewtonbfgs.cpp Dosyayı Görüntüle

@@ -1,85 +0,0 @@
1
-/* This file is part of Lemma, a geophysical modelling and inversion API */
2
-
3
-/* This Source Code Form is subject to the terms of the Mozilla Public
4
- * License, v. 2.0. If a copy of the MPL was not distributed with this
5
- * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
6
-
7
-/**
8
-  @file
9
-  @author   Trevor Irons
10
-  @date     08/09/2010
11
-  @version  $Id: quasinewtonbfgs.cpp 87 2013-09-05 22:44:05Z tirons $
12
- **/
13
-
14
-#include "quasinewtonbfgs.h"
15
-
16
-
17
-namespace Lemma {
18
-
19
-    // ====================  STREAMS       =======================
20
-
21
-    std::ostream &operator<<(std::ostream &stream,
22
-            const QuasiNewtonBFGS &ob) {
23
-        stream << *(InverseSolver*)(&ob);
24
-        return stream;
25
-    }
26
-
27
-
28
-    // ====================  LIFECYCLE     =======================
29
-
30
-    QuasiNewtonBFGS* QuasiNewtonBFGS::New() {
31
-        QuasiNewtonBFGS* Object = new QuasiNewtonBFGS("QuasiNewtonBFGS");
32
-        Object->AttachTo(Object);
33
-        return Object;
34
-    }
35
-
36
-    QuasiNewtonBFGS::QuasiNewtonBFGS(const std::string &name) :
37
-        InverseSolver(name) {
38
-    }
39
-
40
-    void QuasiNewtonBFGS::Delete() {
41
-        this->DetachFrom(this);
42
-    }
43
-
44
-    void QuasiNewtonBFGS::Release() {
45
-        delete this;
46
-    }
47
-
48
-    QuasiNewtonBFGS::~QuasiNewtonBFGS() {
49
-        if (this->NumberOfReferences != 0)
50
-            throw DeleteObjectWithReferences( this );
51
-    }
52
-
53
-    // ====================  INQUIRY       =======================
54
-
55
-    int QuasiNewtonBFGS::NumberOfIterations() {
56
-        return 0;
57
-    }
58
-
59
-    bool QuasiNewtonBFGS::Success () {
60
-        return false;
61
-    }
62
-
63
-    void QuasiNewtonBFGS::PrintNorm() {
64
-        std::cout << "Norm " << std::endl;
65
-        PredictedData->Zero();
66
-        std::cout << ObservedData->Norm(PredictedData) << std::endl;
67
-    }
68
-
69
-    VectorXr QuasiNewtonBFGS::GetPhiMVector() {
70
-        VectorXr NewVec(2);
71
-        return NewVec;
72
-    }
73
-
74
-    VectorXr QuasiNewtonBFGS::GetPhiDVector() {
75
-        VectorXr NewVec(2);
76
-        return NewVec;
77
-    }
78
-
79
-    void QuasiNewtonBFGS::FillInG(const Vector3r& pos, const Vector3r& step) {
80
-
81
-    }
82
-
83
-    // ====================  ACCESS        =======================
84
-
85
-}		// -----  end of Lemma  name  -----

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İptal
Kaydet