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Galerkin FEM for elliptic PDEs
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FEM4EllipticPDE/examples/magnet/sphereBox.geo

sphereBox.geo 4.0KB
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  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. D0 = 10;          // Top of magnet

  11. D1 = 11;          // Bottom of magnet

  12. radius = 3.25;     // Radius of the damn thing

  13. 

  14. lc = radius;   //  0.25;   // Target element size

  15. 

  16. // Total Solution Space

  17. Box = 3*radius; // The down side of potential

  18. X0 = -Box;

  19. X1 =  Box;

  20. Y0 = -Box;

  21. Y1 =  Box;

  22. Z0 = -Box;

  23. Z1 =  Box;

  24. 

  25. cellSize=lc; //300;

  26. dd = 0 ; //  1e-5; //cellSize; // .01;

  27. pio2=Pi/2;

  28. 

  29. 

  30. /////////////////////////////////////

  31. // Large Bounding box

  32. pp = newp;

  33. Point(pp)    = {X0, Y0, Z0, lc};

  34. Point(pp+1)  = {X1, Y0, Z0, lc};

  35. Point(pp+2)  = {X1, Y1, Z0, lc};

  36. Point(pp+3)  = {X0, Y1, Z0, lc};

  37. 

  38. 

  39. lv = newl;

  40. Line(lv) = {pp,pp+1};

  41. Line(lv+1) = {pp+1,pp+2};

  42. Line(lv+2) = {pp+2,pp+3};

  43. Line(lv+3) = {pp+3,pp};

  44. Line Loop(lv+4) = {lv, lv+1, lv+2, lv+3};

  45. 

  46. // Hard coded doom

  47. Plane Surface(125) = {lv+4};

  48. 

  49. //v = newv;

  50. v[] = Extrude {0, 0, Z1-Z0} { Surface{125}; };

  51. 

  52. // // Calculate offset effect

  53. // theta = Asin(dd/radius);

  54. // rr = radius * Cos(theta);

  55. //

  56. // ///////////////////////////////////

  57. // // Positive half sphere

  58. // // create inner 1/8 shell

  59. // p0 = newp;

  60. // Point(p0)   = {      0,   0,       0, cellSize}; // origin

  61. // Point(p0+1) = {    -rr,   0,      dd, cellSize};

  62. // Point(p0+2) = {      0,  rr,      dd, cellSize};

  63. // Point(p0+3) = {      0,   0,  radius, cellSize};

  64. // Point(p0+4) = {      0,   0,      dd, cellSize}; // origin

  65. //

  66. // c0 = newc;

  67. // Circle(c0  ) = {p0+1, p0+4, p0+2};       // Tricky, This one needs to be offset!

  68. // Circle(c0+1) = {p0+3, p0, p0+1};

  69. // Circle(c0+2) = {p0+3, p0, p0+2};

  70. //

  71. // Line Loop(10) = {c0, -(c0+2), c0+1} ;

  72. // Ruled Surface (60) = {10};

  73. //

  74. // ////////////////////////////////////////////////////////////

  75. // // Negative half sphere

  76. // p = newp;

  77. // Point(  p) = {      0,      0,            0, cellSize};

  78. // Point(p+1) = {    -rr,      0,          -dd, cellSize};

  79. // Point(p+2) = {      0,     rr,          -dd, cellSize};

  80. // Point(p+3) = {      0,      0,      -radius, cellSize};

  81. // Point(p+4) = {      0,      0,          -dd, cellSize};

  82. //

  83. // cc = newc;

  84. // Circle(cc  ) = {p+1, p+4, p+2};

  85. // Circle(cc+1) = {p+3, p,   p+1};

  86. // Circle(cc+2) = {p+3, p,   p+2};

  87. //

  88. // Circle(cc+3) = {p+3, p, p+2};

  89. // Circle(cc+4) = {p+3, p, p+2};

  90. // Circle(cc+5) = {p+3, p, p+2};

  91. //

  92. // ccl = newl;

  93. // Line(ccl) = { p0+3, p+3 };

  94. //

  95. // Line Loop(11) = {cc, -(cc+2), cc+1} ;

  96. // Ruled Surface (61) = {11};

  97. //

  98. // // create remaining 7/8 inner shells

  99. // t1[] = Rotate {{0,0,1},{0,0,0},pio2  } {Duplicata{Surface{60};}};

  100. // t2[] = Rotate {{0,0,1},{0,0,0},pio2*2} {Duplicata{Surface{60};}};

  101. // t3[] = Rotate {{0,0,1},{0,0,0},pio2*3} {Duplicata{Surface{60};}};

  102. // //

  103. // t4[] = Rotate {{0,0,1},{0,0,0},pio2  } {Duplicata{Surface{61};}};

  104. // t5[] = Rotate {{0,0,1},{0,0,0},pio2*2} {Duplicata{Surface{61};}};

  105. // t6[] = Rotate {{0,0,1},{0,0,0},pio2*3} {Duplicata{Surface{61};}};

  106. //

  107. // /* This is GOOD */

  108. // Surface{60} In Volume{v[1]};

  109. // Surface{t1[0]} In Volume{v[1]};

  110. // Surface{t2[0]} In Volume{v[1]};

  111. // Surface{t3[0]} In Volume{v[1]};

  112. //

  113. // Surface{61} In Volume{v[1]};

  114. // Surface{t4[0]} In Volume{v[1]};

  115. // Surface{t5[0]} In Volume{v[1]};

  116. // Surface{t6[0]} In Volume{v[1]};

  117. //

  118. // ///////////////////////////////////////////////

  119. // // Attractor Field

  120. //

  121. // //Field[1] = Attractor;

  122. // //Field[1].NodesList = {p}; //0, p0+1, p0+2, p0+3, p0+4, p, p+1, p+2, p+3, p+4};

  123. //

  124. // //Field[2] = MathEval;

  125. // //Field[2].F = Sprintf("(2.25 - F1)^2 + %g", cellSize*10 );  // WORKS

  126. // //Field[2].F = Sprintf("(%g - F1)^2 + %g", radius, 2*cellSize );

  127. // //Background Field = 2;

  128. //

  129. // // Don't extend the elements sizes from the boundary inside the domain

  130. // //Mesh.CharacteristicLengthExtendFromBoundary = 0;

  131. //

  132. // Physical Volume(1) = {v[1]};

  133. 

  134. // To create the mesh run

  135. // gmsh sphere.gmsh -2 -v 0 -format msh -o sphere.msh

  136. //gmsh -3 -format msh1 -o outfile.msh sphere.geo