fish_domain.h
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26 // Include guards
27 #ifndef OOMPH_FISH_DOMAIN_HEADER
28 #define OOMPH_FISH_DOMAIN_HEADER
29 
30 // Generic oomph-lib includes
31 #include "../generic/quadtree.h"
32 #include "../generic/domain.h"
33 #include "../generic/geom_objects.h"
34 
35 namespace oomph
36 {
37  //===========start_of_fish_domain=======================================
38  /// Fish shaped domain, represented by four
39  /// MacroElements. Shape is parametrised by GeomObject
40  /// that represents the fish's back.
41  //=======================================================================
42  class FishDomain : public Domain
43  {
44  public:
45  /// Constructor: Pass pointer to GeomObject that represents the
46  /// (upper) curved boundary of the fish's body, and the start and end values
47  /// of the Lagrangian coordinates along the GeomObject.
48  FishDomain(GeomObject* back_pt,
49  const double& xi_nose,
50  const double& xi_tail)
51  : Xi_nose(xi_nose), Xi_tail(xi_tail), Back_pt(back_pt)
52  {
53  // Set values for private data members that are describe
54  // geometric features of the fish: x-coordinate of the fin,
55  // (half-)height of the fin, and x-position of the mouth.
56  X_fin = 1.7;
57  Y_fin = 0.9;
58  X_mouth = 0.0;
59 
60  // There are four macro elements
61  unsigned nmacro = 4;
62  Macro_element_pt.resize(nmacro);
63 
64  // Build them
65  for (unsigned i = 0; i < nmacro; i++)
66  {
67  Macro_element_pt[i] = new QMacroElement<2>(this, i);
68  }
69  } // end of constructor
70 
71 
72  /// Broken copy constructor
73  FishDomain(const FishDomain&) = delete;
74 
75  /// Broken assignment operator
76  void operator=(const FishDomain&) = delete;
77 
78  /// Destructor for FishDomain: Empty; cleanup done in base class
79  virtual ~FishDomain() {}
80 
81 
82  /// x-position of fin tip
83  double& x_fin()
84  {
85  return X_fin;
86  }
87 
88  /// y-position of fin tip
89  double& y_fin()
90  {
91  return Y_fin;
92  }
93 
94  /// x-position of mouth
95  double& x_mouth()
96  {
97  return X_mouth;
98  }
99 
100  /// Start coordinate on wall (near nose)
101  double& xi_nose()
102  {
103  return Xi_nose;
104  }
105 
106  /// End coordinate on wall (near tail)
107  double& xi_tail()
108  {
109  return Xi_tail;
110  }
111 
112  /// Vector representation of the i_macro-th macro element
113  /// boundary i_direct (N/S/W/E) at the discrete time level t
114  /// (t=0: present; t>0: previous): \f$ {\bf r}({\bf zeta}) \f$
115  /// Note that the local coordinate \b zeta is a 1D
116  /// Vector rather than a scalar -- this is unavoidable because
117  /// this function implements the pure virtual function in the
118  /// Domain base class.
119  void macro_element_boundary(const unsigned& t,
120  const unsigned& i_macro,
121  const unsigned& i_direct,
122  const Vector<double>& zeta,
123  Vector<double>& r);
124 
125  private:
126  /// "Nose" limit for the (1D) coordinates along the wall
127  double Xi_nose;
128 
129  /// "Tail" limit for the (1D) coordinates along the wall
130  double Xi_tail;
131 
132  /// X coordinate of fin tip
133  double X_fin;
134 
135  /// Y coordinate of fin tip
136  double Y_fin;
137 
138  /// X coordinate of corner of mouth
139  double X_mouth;
140 
141  /// Pointer to the fish's back
142  GeomObject* Back_pt;
143 
144  /// Boundary of upper body macro element zeta \f$ \in [-1,1] \f$
145  void r_upper_body_N(const unsigned& t,
146  const Vector<double>& zeta,
147  Vector<double>& f);
148 
149  /// Boundary of upper body macro element zeta \f$ \in [-1,1] \f$
150  void r_upper_body_W(const unsigned& t,
151  const Vector<double>& zeta,
152  Vector<double>& f);
153 
154  /// Boundary of upper body macro element zeta \f$ \in [-1,1] \f$
155  void r_upper_body_S(const unsigned& t,
156  const Vector<double>& zeta,
157  Vector<double>& f);
158 
159  /// Boundary of upper body macro element zeta \f$ \in [-1,1] \f$
160  void r_upper_body_E(const unsigned& t,
161  const Vector<double>& zeta,
162  Vector<double>& f);
163 
164  /// Boundary of upper fin macro element zeta \f$ \in [-1,1] \f$
165  void r_upper_fin_N(const unsigned& t,
166  const Vector<double>& zeta,
167  Vector<double>& f);
168 
169  /// Boundary of upper fin macro element zeta \f$ \in [-1,1] \f$
170  void r_upper_fin_W(const unsigned& t,
171  const Vector<double>& zeta,
172  Vector<double>& f);
173 
174  /// Boundary of upper fin macro element zeta \f$ \in [-1,1] \f$
175  void r_upper_fin_S(const unsigned& t,
176  const Vector<double>& zeta,
177  Vector<double>& f);
178 
179  /// Boundary of upper fin macro element zeta \f$ \in [-1,1] \f$
180  void r_upper_fin_E(const unsigned& t,
181  const Vector<double>& zeta,
182  Vector<double>& f);
183 
184 
185  /// Boundary of lower body macro element zeta \f$ \in [-1,1] \f$
186  void r_lower_body_N(const unsigned& t,
187  const Vector<double>& zeta,
188  Vector<double>& f)
189  {
190  // North of lower body is element is south of upper one.
191  // Direction of the coordinate stays the same.
192  r_upper_body_S(t, zeta, f);
193  // Reflect vertical position
194  f[1] = -f[1];
195  }
196 
197 
198  /// Boundary of lower body macro element zeta \f$ \in [-1,1] \f$
199  void r_lower_body_W(const unsigned& t,
200  const Vector<double>& zeta,
201  Vector<double>& f)
202  {
203  // West of lower body is element is west of upper one.
204  // Direction of the coordinate is inverted
205  Vector<double> zeta_new(1);
206  zeta_new[0] = -zeta[0];
207  r_upper_body_W(t, zeta_new, f);
208  // Vertical coordinate is reflected
209  f[1] = -f[1];
210  }
211 
212  /// Southern boundary of lower body macro element zeta \f$\in [-1,1] \f$
213  void r_lower_body_S(const unsigned& t,
214  const Vector<double>& zeta,
215  Vector<double>& f)
216  {
217  // South of lower body is element is north of upper one.
218  // Direction of the coordinate stays the same.
219  r_upper_body_N(t, zeta, f);
220  // Reflect vertical position
221  f[1] = -f[1];
222  }
223 
224  /// Boundary of lower body macro element zeta \f$ \in [-1,1] \f$
225  void r_lower_body_E(const unsigned& t,
226  const Vector<double>& zeta,
227  Vector<double>& f)
228  {
229  // East of lower body is element is east of upper one.
230  // Direction of the coordinate is inverted.
231  Vector<double> zeta_new(1);
232  zeta_new[0] = -zeta[0];
233  r_upper_body_E(t, zeta_new, f);
234  // Vertical coordinate is reflected
235  f[1] = -f[1];
236  }
237 
238 
239  /// Boundary of lower fin macro element zeta \f$ \in [-1,1] \f$
240  void r_lower_fin_N(const unsigned& t,
241  const Vector<double>& zeta,
242  Vector<double>& f)
243  {
244  // North of lower fin is element is south of upper one.
245  // Direction of the coordinate stays the same.
246  r_upper_fin_S(t, zeta, f);
247  // Reflect vertical position
248  f[1] = -f[1];
249  }
250 
251 
252  /// Boundary of lower fin macro element zeta \f$ \in [-1,1] \f$
253  void r_lower_fin_W(const unsigned& t,
254  const Vector<double>& zeta,
255  Vector<double>& f)
256  {
257  // West of lower fin is element is west of upper one.
258  // Direction of the coordinate is inverted
259  Vector<double> zeta_new(1);
260  zeta_new[0] = -zeta[0];
261  r_upper_fin_W(t, zeta_new, f);
262  // Vertical coordinate is reflected
263  f[1] = -f[1];
264  }
265 
266  /// Boundary of lower fin macro element zeta \f$ \in [-1,1] \f$
267  void r_lower_fin_S(const unsigned& t,
268  const Vector<double>& zeta,
269  Vector<double>& f)
270  {
271  // South of lower fin is element is north of upper one.
272  // Direction of the coordinate stays the same.
273  r_upper_fin_N(t, zeta, f);
274  // Reflect vertical position
275  f[1] = -f[1];
276  }
277 
278  /// Boundary of lower fin macro element zeta \f$ \in [-1,1] \f$
279  void r_lower_fin_E(const unsigned& t,
280  const Vector<double>& zeta,
281  Vector<double>& f)
282  {
283  // East of lower fin is element is east of upper one.
284  // Direction of the coordinate is inverted.
285  Vector<double> zeta_new(1);
286  zeta_new[0] = -zeta[0];
287  r_upper_fin_E(t, zeta_new, f);
288  // Vertical coordinate is reflected
289  f[1] = -f[1];
290  }
291  };
292 
293 
294  /// //////////////////////////////////////////////////////////////////////
295  /// //////////////////////////////////////////////////////////////////////
296  /// //////////////////////////////////////////////////////////////////////
297 
298 
299  //==========start_of_macro_element_boundary========================
300  /// Vector representation of the imacro-th macro element
301  /// boundary idirect (N/S/W/E) at time level t
302  /// (t=0: present; t>0: previous): \f$ {\bf r}({\bf zeta}) \f$
303  /// Note that the local coordinate \b zeta is a 1D
304  /// Vector rather than a scalar -- this is unavoidable because
305  /// this function implements the pure virtual function in the
306  /// Domain base class.
307  //=================================================================
308  void FishDomain::macro_element_boundary(const unsigned& t,
309  const unsigned& imacro,
310  const unsigned& idirect,
311  const Vector<double>& zeta,
312  Vector<double>& r)
313  {
314  using namespace QuadTreeNames;
315 
316 
317 #ifdef WARN_ABOUT_SUBTLY_CHANGED_OOMPH_INTERFACES
318  // Warn about time argument being moved to the front
319  OomphLibWarning(
320  "Order of function arguments has changed between versions 0.8 and 0.85",
321  "FishDomain::macro_element_boundary(...)",
322  OOMPH_EXCEPTION_LOCATION);
323 #endif
324 
325 
326  // Which macro element?
327  // --------------------
328  switch (imacro)
329  {
330  // Macro element 0: Lower body
331  case 0:
332 
333  // Which direction?
334  if (idirect == N)
335  {
336  FishDomain::r_lower_body_N(t, zeta, r);
337  }
338  else if (idirect == S)
339  {
340  FishDomain::r_lower_body_S(t, zeta, r);
341  }
342  else if (idirect == W)
343  {
344  FishDomain::r_lower_body_W(t, zeta, r);
345  }
346  else if (idirect == E)
347  {
348  FishDomain::r_lower_body_E(t, zeta, r);
349  }
350  else
351  {
352  std::ostringstream error_stream;
353  error_stream << "idirect is " << idirect << " not one of N, S, E, W"
354  << std::endl;
355 
356  throw OomphLibError(error_stream.str(),
357  OOMPH_CURRENT_FUNCTION,
358  OOMPH_EXCEPTION_LOCATION);
359  }
360 
361  break;
362 
363  // Macro element 1: Lower Fin
364  case 1:
365 
366  // Which direction?
367  if (idirect == N)
368  {
369  FishDomain::r_lower_fin_N(t, zeta, r);
370  }
371  else if (idirect == S)
372  {
373  FishDomain::r_lower_fin_S(t, zeta, r);
374  }
375  else if (idirect == W)
376  {
377  FishDomain::r_lower_fin_W(t, zeta, r);
378  }
379  else if (idirect == E)
380  {
381  FishDomain::r_lower_fin_E(t, zeta, r);
382  }
383  else
384  {
385  std::ostringstream error_stream;
386  error_stream << "idirect is " << idirect << " not one of N, S, E, W"
387  << std::endl;
388 
389  throw OomphLibError(error_stream.str(),
390  OOMPH_CURRENT_FUNCTION,
391  OOMPH_EXCEPTION_LOCATION);
392  }
393 
394  break;
395 
396 
397  // Macro element 2: Upper body
398  case 2:
399 
400  // Which direction?
401  if (idirect == N)
402  {
403  FishDomain::r_upper_body_N(t, zeta, r);
404  }
405  else if (idirect == S)
406  {
407  FishDomain::r_upper_body_S(t, zeta, r);
408  }
409  else if (idirect == W)
410  {
411  FishDomain::r_upper_body_W(t, zeta, r);
412  }
413  else if (idirect == E)
414  {
415  FishDomain::r_upper_body_E(t, zeta, r);
416  }
417  else
418  {
419  std::ostringstream error_stream;
420  error_stream << "idirect is " << idirect << " not one of N, S, E, W"
421  << std::endl;
422 
423  throw OomphLibError(error_stream.str(),
424  OOMPH_CURRENT_FUNCTION,
425  OOMPH_EXCEPTION_LOCATION);
426  }
427 
428  break;
429 
430 
431  // Macro element 3: Upper Fin
432  case 3:
433 
434  // Which direction?
435  if (idirect == N)
436  {
437  FishDomain::r_upper_fin_N(t, zeta, r);
438  }
439  else if (idirect == S)
440  {
441  FishDomain::r_upper_fin_S(t, zeta, r);
442  }
443  else if (idirect == W)
444  {
445  FishDomain::r_upper_fin_W(t, zeta, r);
446  }
447  else if (idirect == E)
448  {
449  FishDomain::r_upper_fin_E(t, zeta, r);
450  }
451  else
452  {
453  std::ostringstream error_stream;
454  error_stream << "idirect is " << idirect << " not one of N, S, E, W"
455  << std::endl;
456 
457  throw OomphLibError(error_stream.str(),
458  OOMPH_CURRENT_FUNCTION,
459  OOMPH_EXCEPTION_LOCATION);
460  }
461 
462  break;
463 
464  default:
465 
466  // Error
467  std::ostringstream error_stream;
468  error_stream << "Wrong imacro " << imacro << std::endl;
469 
470  throw OomphLibError(
471  error_stream.str(), OOMPH_CURRENT_FUNCTION, OOMPH_EXCEPTION_LOCATION);
472  }
473 
474  } // end of macro_element_boundary
475 
476 
477  //=================================================================
478  /// Northern edge of upper fin macro element; \f$ \zeta \in [-1,1] \f$
479  //=================================================================
480  void FishDomain::r_upper_fin_N(const unsigned& t,
481  const Vector<double>& zeta,
482  Vector<double>& r)
483  {
484  // Right end of fish back
485  Vector<double> x(1);
486  x[0] = Xi_tail;
487  Vector<double> r_fish(2);
488  Back_pt->position(t, x, r_fish);
489 
490  // Top end of fin
491  Vector<double> r_fin(2);
492  r_fin[0] = X_fin;
493  r_fin[1] = Y_fin;
494 
495 
496  // Straight line along upper fin
497  r[0] = r_fish[0] + (r_fin[0] - r_fish[0]) * 0.5 * (zeta[0] + 1.0);
498  r[1] = r_fish[1] + (r_fin[1] - r_fish[1]) * 0.5 * (zeta[0] + 1.0);
499  }
500 
501 
502  //=================================================================
503  /// Western edge of upper fin macro element; \f$ \zeta \in [-1,1] \f$
504  //=================================================================
505  void FishDomain::r_upper_fin_W(const unsigned& t,
506  const Vector<double>& zeta,
507  Vector<double>& r)
508  {
509  // Right end of fish back
510  Vector<double> x(1);
511  x[0] = Xi_tail;
512  Vector<double> r_fish(2);
513  Back_pt->position(t, x, r_fish);
514 
515  r[0] = r_fish[0];
516  r[1] = r_fish[1] * 0.5 * (zeta[0] + 1.0);
517  }
518 
519 
520  //=================================================================
521  /// Southern edge of upper fin macro element; \f$ \zeta \in [-1,1] \f$
522  //=================================================================
523  void FishDomain::r_upper_fin_S(const unsigned& t,
524  const Vector<double>& zeta,
525  Vector<double>& r)
526  {
527  // Right end of fish back
528  Vector<double> x(1);
529  x[0] = Xi_tail;
530  Vector<double> r_fish(2);
531  Back_pt->position(t, x, r_fish);
532 
533 
534  r[0] = r_fish[0] * 0.5 * (zeta[0] + 1.0);
535  r[1] = 0.0;
536  }
537 
538 
539  //=================================================================
540  /// Eastern edge of upper fin macro element; \f$ \zeta \in [-1,1] \f$
541  //=================================================================
542  void FishDomain::r_upper_fin_E(const unsigned& t,
543  const Vector<double>& zeta,
544  Vector<double>& r)
545  {
546  // Straight vertical line from top of fin
547  r[0] = X_fin;
548  r[1] = Y_fin * 0.5 * (zeta[0] + 1.0);
549  }
550 
551 
552  //===============start_of_r_upper_body_N==============================
553  /// Northern edge of upper body macro element; \f$ \zeta \in [-1,1] \f$
554  //=====================================================================
555  void FishDomain::r_upper_body_N(const unsigned& t,
556  const Vector<double>& zeta,
557  Vector<double>& r)
558  {
559  // Lagrangian coordinate along curved "back"
560  Vector<double> x(1);
561  x[0] = Xi_nose + (Xi_tail - Xi_nose) * 0.5 * (zeta[0] + 1.0);
562 
563  // Get position on curved back
564  Back_pt->position(t, x, r);
565 
566  } // end of r_upper_body_N
567 
568 
569  //================start_of_r_upper_body_E=============================
570  /// Eastern edge of upper body macro element; \f$ \zeta \in [-1,1] \f$
571  //=====================================================================
572  void FishDomain::r_upper_body_E(const unsigned& t,
573  const Vector<double>& zeta,
574  Vector<double>& r)
575  {
576  // Top right corner (tail end) of body
577  Vector<double> r_top(2);
578  Vector<double> x(1);
579  x[0] = Xi_tail;
580  Back_pt->position(t, x, r_top);
581 
582  // Corresponding point on the x-axis
583  Vector<double> r_back(2);
584  r_back[0] = r_top[0];
585  r_back[1] = 0.0;
586 
587  r[0] = r_back[0] + (r_top[0] - r_back[0]) * 0.5 * (zeta[0] + 1.0);
588  r[1] = r_back[1] + (r_top[1] - r_back[1]) * 0.5 * (zeta[0] + 1.0);
589 
590 
591  } // end of r_upper_body_E
592 
593 
594  //==================start_of_r_upper_body_S============================
595  /// Southern edge of upper body macro element; \f$ \zeta \in [-1,1] \f$
596  //=====================================================================
597  void FishDomain::r_upper_body_S(const unsigned& t,
598  const Vector<double>& zeta,
599  Vector<double>& r)
600  {
601  // Top right (tail) corner of fish body
602  Vector<double> r_top(2);
603  Vector<double> x(1);
604  x[0] = Xi_tail;
605  Back_pt->position(t, x, r_top);
606 
607  // Straight line from mouth to start of fin (=end of body)
608  r[0] = X_mouth + (r_top[0] - X_mouth) * 0.5 * (zeta[0] + 1.0);
609  r[1] = 0.0;
610 
611  } // end of r_upper_body_S
612 
613 
614  //===============start_of_r_upper_body_W==============================
615  /// Western edge of upper body macro element; \f$ \zeta \in [-1,1] \f$
616  //====================================================================
617  void FishDomain::r_upper_body_W(const unsigned& t,
618  const Vector<double>& zeta,
619  Vector<double>& r)
620  {
621  // Top left (mouth) corner of curved boundary of upper body
622  Vector<double> r_top(2);
623  Vector<double> x(1);
624  x[0] = Xi_nose;
625  Back_pt->position(t, x, r_top);
626 
627  // The "mouth"
628  Vector<double> r_mouth(2);
629  r_mouth[0] = X_mouth;
630  r_mouth[1] = 0.0;
631 
632  // Straight line from mouth to leftmost corner on curved boundary
633  // of upper body
634  r[0] = r_mouth[0] + (r_top[0] - r_mouth[0]) * 0.5 * (zeta[0] + 1.0);
635  r[1] = r_mouth[1] + (r_top[1] - r_mouth[1]) * 0.5 * (zeta[0] + 1.0);
636 
637  } // end of r_upper_body_W
638 
639 
640 } // namespace oomph
641 
642 #endif
Fish shaped domain, represented by four MacroElements. Shape is parametrised by GeomObject that repre...
Definition: fish_domain.h:43
void r_upper_fin_E(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper fin macro element zeta .
Definition: fish_domain.h:542
double Y_fin
Y coordinate of fin tip.
Definition: fish_domain.h:136
void r_lower_fin_S(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower fin macro element zeta .
Definition: fish_domain.h:267
void macro_element_boundary(const unsigned &t, const unsigned &i_macro, const unsigned &i_direct, const Vector< double > &zeta, Vector< double > &r)
Vector representation of the i_macro-th macro element boundary i_direct (N/S/W/E) at the discrete tim...
Definition: fish_domain.h:308
double Xi_tail
"Tail" limit for the (1D) coordinates along the wall
Definition: fish_domain.h:130
void operator=(const FishDomain &)=delete
Broken assignment operator.
void r_lower_body_W(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower body macro element zeta .
Definition: fish_domain.h:199
void r_upper_body_N(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper body macro element zeta .
Definition: fish_domain.h:555
void r_upper_body_E(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper body macro element zeta .
Definition: fish_domain.h:572
void r_upper_fin_N(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper fin macro element zeta .
Definition: fish_domain.h:480
void r_lower_fin_N(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower fin macro element zeta .
Definition: fish_domain.h:240
void r_upper_fin_W(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper fin macro element zeta .
Definition: fish_domain.h:505
void r_lower_body_N(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower body macro element zeta .
Definition: fish_domain.h:186
double & xi_nose()
Start coordinate on wall (near nose)
Definition: fish_domain.h:101
FishDomain(const FishDomain &)=delete
Broken copy constructor.
void r_lower_fin_E(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower fin macro element zeta .
Definition: fish_domain.h:279
FishDomain(GeomObject *back_pt, const double &xi_nose, const double &xi_tail)
Constructor: Pass pointer to GeomObject that represents the (upper) curved boundary of the fish's bod...
Definition: fish_domain.h:48
double X_mouth
X coordinate of corner of mouth.
Definition: fish_domain.h:139
void r_lower_body_S(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Southern boundary of lower body macro element zeta .
Definition: fish_domain.h:213
void r_lower_fin_W(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower fin macro element zeta .
Definition: fish_domain.h:253
virtual ~FishDomain()
Destructor for FishDomain: Empty; cleanup done in base class.
Definition: fish_domain.h:79
void r_lower_body_E(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of lower body macro element zeta .
Definition: fish_domain.h:225
void r_upper_body_W(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper body macro element zeta .
Definition: fish_domain.h:617
void r_upper_fin_S(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper fin macro element zeta .
Definition: fish_domain.h:523
double & x_mouth()
x-position of mouth
Definition: fish_domain.h:95
double & y_fin()
y-position of fin tip
Definition: fish_domain.h:89
double & xi_tail()
End coordinate on wall (near tail)
Definition: fish_domain.h:107
double & x_fin()
x-position of fin tip
Definition: fish_domain.h:83
GeomObject * Back_pt
Pointer to the fish's back.
Definition: fish_domain.h:142
double X_fin
X coordinate of fin tip.
Definition: fish_domain.h:133
void r_upper_body_S(const unsigned &t, const Vector< double > &zeta, Vector< double > &f)
Boundary of upper body macro element zeta .
Definition: fish_domain.h:597
double Xi_nose
"Nose" limit for the (1D) coordinates along the wall
Definition: fish_domain.h:127
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