refineable_b_convection.cc
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26 //Driver for a multi-physics problem that couples the Navier--Stokes
27 //equations to the advection diffusion equations,
28 //giving Boussinesq convection
29 
30 //Oomph-lib headers, we require the generic, advection-diffusion
31 //and navier-stokes elements.
32 #include "generic.h"
33 #include "advection_diffusion.h"
34 #include "navier_stokes.h"
35 #include "multi_physics.h"
36 
37 // The mesh is our standard rectangular quadmesh
38 #include "meshes/rectangular_quadmesh.h"
39 
40 // Use the oomph and std namespaces
41 using namespace oomph;
42 using namespace std;
43 
44 
45 /// ///////////////////////////////////////////////////////////////////
46 /// ///////////////////////////////////////////////////////////////////
47 /// ///////////////////////////////////////////////////////////////////
48 
49 
50 //======start_of_namespace============================================
51 /// Namespace for the physical parameters in the problem
52 //====================================================================
54 {
55 
56  /// Peclet number (identically one from our non-dimensionalisation)
57  double Peclet=1.0;
58 
59  /// 1/Prandtl number
60  double Inverse_Prandtl=1.0;
61 
62  /// Rayleigh number, set to be greater than
63  /// the threshold for linear instability
64  double Rayleigh = 1800.0;
65 
66  /// Gravity vector
67  Vector<double> Direction_of_gravity(2);
68 
69 } // end_of_namespace
70 
71 
72 /// ///////////////////////////////////////////////////////////////////
73 /// ///////////////////////////////////////////////////////////////////
74 /// ///////////////////////////////////////////////////////////////////
75 
76 
77 
78 //=======start_of_problem_class=======================================
79 /// 2D Convection problem on rectangular domain, discretised
80 /// with refineable elements. The specific type
81 /// of element is specified via the template parameter.
82 //====================================================================
83 template<class ELEMENT>
84 class RefineableConvectionProblem : public Problem
85 {
86 
87 public:
88 
89  /// Constructor
91 
92  /// Destructor. Empty
94 
95  /// Update the problem specs before solve:
97 
98  /// Update the problem after solve (empty)
100 
101  /// Overloaded version of the problem's access function to
102  /// the mesh. Recasts the pointer to the base Mesh object to
103  /// the actual mesh type.
104  RectangularQuadMesh<ELEMENT>* mesh_pt()
105  {
106  return dynamic_cast<RectangularQuadMesh<ELEMENT>*>(
107  Problem::mesh_pt());
108  } //end of access function to specic mesh
109 
110  /// Actions before adapt:(empty)
112 
113  /// Actions after adaptation,
114  /// Re-pin a single pressure degree of freedom
116  {
117  //Unpin all the pressures to avoid pinning two pressures
118  RefineableNavierStokesEquations<2>::
119  unpin_all_pressure_dofs(mesh_pt()->element_pt());
120 
121  //Pin the zero-th pressure dof in the zero-th element and set
122  // its value to zero
123  fix_pressure(0,0,0.0);
124  }
125 
126  /// Fix pressure in element e at pressure dof pdof and set to pvalue
127  void fix_pressure(const unsigned &e, const unsigned &pdof,
128  const double &pvalue)
129  {
130  //Cast to specific element and fix pressure
131  dynamic_cast<ELEMENT*>(mesh_pt()->element_pt(e))->
132  fix_pressure(pdof,pvalue);
133  } // end_of_fix_pressure
134 
135  /// Set the
136  /// boundary condition on the upper wall to be perturbed slightly
137  /// to force the solution into the symmetry broken state.
138  void enable_imperfection() {Imperfect = true;}
139 
140  /// Set the
141  /// boundary condition on the upper wall to be unperturbed.
142  void disable_imperfection() {Imperfect = false;}
143 
144  /// Doc the solution.
145  void doc_solution();
146 
147 private:
148 
149  /// DocInfo object
150  DocInfo Doc_info;
151 
152  /// Is the boundary condition imperfect or not
153  bool Imperfect;
154 
155 }; // end of problem class
156 
157 
158 //=======start_of_constructor=============================================
159 /// Constructor for adaptive thermal convection problem
160 //========================================================================
161 template<class ELEMENT>
163 RefineableConvectionProblem() : Imperfect(false)
164 {
165  // Set output directory
166  Doc_info.set_directory("RESLT");
167 
168  // # of elements in x-direction
169  unsigned n_x=9;
170 
171  // # of elements in y-direction
172  unsigned n_y=8;
173 
174  // Domain length in x-direction
175  double l_x=3.0;
176 
177  // Domain length in y-direction
178  double l_y=1.0;
179 
180  // Build the mesh
181  RefineableRectangularQuadMesh<ELEMENT>* cast_mesh_pt =
182  new RefineableRectangularQuadMesh<ELEMENT>(n_x,n_y,l_x,l_y);
183 
184  //Set the problem's mesh pointer
185  Problem::mesh_pt() = cast_mesh_pt;
186 
187 
188  // Create/set error estimator
189  cast_mesh_pt->spatial_error_estimator_pt()=new Z2ErrorEstimator;
190 
191  // Set error targets for adaptive refinement
192  cast_mesh_pt->max_permitted_error()=0.5e-3;
193  cast_mesh_pt->min_permitted_error()=0.5e-4;
194 
195 
196  // Set the boundary conditions for this problem: All nodes are
197  // free by default -- only need to pin the ones that have Dirichlet
198  // conditions here
199 
200  //Loop over the boundaries
201  unsigned num_bound = mesh_pt()->nboundary();
202  for(unsigned ibound=0;ibound<num_bound;ibound++)
203  {
204  //Set the maximum index to be pinned (all values by default)
205  unsigned val_max=3;
206  //If we are on the side-walls, the v-velocity and temperature
207  //satisfy natural boundary conditions, so we only pin the
208  //first value
209  if((ibound==1) || (ibound==3)) {val_max=1;}
210 
211  //Loop over the number of nodes on the boundry
212  unsigned num_nod= mesh_pt()->nboundary_node(ibound);
213  for (unsigned inod=0;inod<num_nod;inod++)
214  {
215  //Loop over the desired values stored at the nodes and pin
216  for(unsigned j=0;j<val_max;j++)
217  {
218  mesh_pt()->boundary_node_pt(ibound,inod)->pin(j);
219  }
220  }
221  }
222 
223  // Pin the zero-th pressure value in the zero-th element and
224  // set its value to zero.
225  fix_pressure(0,0,0.0);
226 
227  // Complete the build of all elements so they are fully functional
228 
229  // Loop over the elements to set up element-specific
230  // things that cannot be handled by the (argument-free!) ELEMENT
231  // constructor.
232  unsigned n_element = mesh_pt()->nelement();
233  for(unsigned i=0;i<n_element;i++)
234  {
235  // Upcast from GeneralsedElement to the present element
236  ELEMENT *el_pt = dynamic_cast<ELEMENT*>(mesh_pt()->element_pt(i));
237 
238  // Set the Peclet number
239  el_pt->pe_pt() = &Global_Physical_Variables::Peclet;
240 
241  // Set the Peclet Strouhal number
242  el_pt->pe_st_pt() = &Global_Physical_Variables::Peclet;
243 
244  // Set the Reynolds number (1/Pr in our non-dimensionalisation)
246 
247  // Set ReSt (also 1/Pr in our non-dimensionalisation)
248  el_pt->re_st_pt() = &Global_Physical_Variables::Inverse_Prandtl;
249 
250  // Set the Rayleigh number
251  el_pt->ra_pt() = &Global_Physical_Variables::Rayleigh;
252 
253  //Set Gravity vector
255  }
256 
257  // Setup equation numbering scheme
258  cout <<"Number of equations: " << assign_eqn_numbers() << endl;
259 
260 } // end of constructor
261 
262 
263 //===================start_actions_before_newton_solve===========================
264 /// Update the problem specs before solve: (Re-)set boundary conditions
265 /// to include an imperfection (or not) depending on the control flag.
266 //========================================================================
267 template<class ELEMENT>
269 {
270  // Loop over the boundaries
271  unsigned num_bound = mesh_pt()->nboundary();
272  for(unsigned ibound=0;ibound<num_bound;ibound++)
273  {
274  // Loop over the nodes on boundary
275  unsigned num_nod=mesh_pt()->nboundary_node(ibound);
276  for(unsigned inod=0;inod<num_nod;inod++)
277  {
278  // Get pointer to node
279  Node* nod_pt=mesh_pt()->boundary_node_pt(ibound,inod);
280 
281  //Set the number of velocity components
282  unsigned vel_max=2;
283  //If we are on the side walls we only pin the x-velocity.
284  if((ibound==1) || (ibound==3)) {vel_max = 1;}
285  //Set the pinned velocities to zero
286  for(unsigned j=0;j<vel_max;j++) {nod_pt->set_value(j,0.0);}
287 
288  //If we are on the top boundary
289  if(ibound==2)
290  {
291  //Set the temperature to -0.5 (cooled)
292  nod_pt->set_value(2,-0.5);
293  //Add small velocity imperfection if desired
294  if(Imperfect)
295  {
296  //Read out the x position
297  double x = nod_pt->x(0);
298  //Set a sinusoidal perturbation in the vertical velocity
299  //This perturbation is mass conserving
300  double value = sin(2.0*3.141592654*x/3.0);
301  nod_pt->set_value(1,value);
302  }
303  }
304 
305  //If we are on the bottom boundary, set the temperature
306  //to 0.5 (heated)
307  if(ibound==0) {nod_pt->set_value(2,0.5);}
308  }
309  }
310 
311 } // end of actions before solve
312 
313 
314 
315 //====================start_of_doc_solution===============================
316 /// Doc the solution
317 //========================================================================
318 template<class ELEMENT>
320 {
321  //Declare an output stream and filename
322  ofstream some_file;
323  char filename[100];
324 
325  // Number of plot points: npts x npts
326  unsigned npts=5;
327 
328  // Output solution
329  //-----------------
330  sprintf(filename,"%s/soln%i.dat",Doc_info.directory().c_str(),
331  Doc_info.number());
332  some_file.open(filename);
333  mesh_pt()->output(some_file,npts);
334  some_file.close();
335 
336  Doc_info.number()++;
337 } // end of doc
338 
339 
340 //===============start_of_main========================================
341 /// Driver code for 2D Boussinesq convection problem with
342 /// adaptivity.
343 //====================================================================
344 int main()
345 {
346 
347  // Set the direction of gravity
350 
351  // Create the problem with 2D nine-node refineable elements.
354 
355  // Apply a perturbation to the upper boundary condition to
356  // force the solution into the symmetry-broken state.
357  problem.enable_imperfection();
358 
359  //Solve the problem with (up to) two levels of adaptation
360  problem.newton_solve(2);
361 
362  //Document the solution
363  problem.doc_solution();
364 
365  // Make the boundary conditions perfect and solve again.
366  // Now the slightly perturbed symmetry broken state computed
367  // above is used as the initial condition and the Newton solver
368  // converges to the symmetry broken solution, even without
369  // the perturbation
370  problem.disable_imperfection();
371  problem.newton_solve(2);
372  problem.doc_solution();
373 
374 } // end of main
375 
376 
377 
378 
379 
380 
381 
382 
383 
/////////////////////////////////////////////////////////////////// /////////////////////////////////...
void actions_after_newton_solve()
Update the problem after solve (empty)
void fix_pressure(const unsigned &e, const unsigned &pdof, const double &pvalue)
Fix pressure in element e at pressure dof pdof and set to pvalue.
~RefineableConvectionProblem()
Destructor. Empty.
void actions_before_newton_solve()
Update the problem specs before solve:
void disable_imperfection()
Set the boundary condition on the upper wall to be unperturbed.
RectangularQuadMesh< ELEMENT > * mesh_pt()
Overloaded version of the problem's access function to the mesh. Recasts the pointer to the base Mesh...
void doc_solution()
Doc the solution.
void actions_before_adapt()
Actions before adapt:(empty)
void actions_after_adapt()
Actions after adaptation, Re-pin a single pressure degree of freedom.
RefineableConvectionProblem()
Constructor.
void enable_imperfection()
Set the boundary condition on the upper wall to be perturbed slightly to force the solution into the ...
void actions_before_newton_solve()
Update the problem specs before solve:
////////////////////////////////////////////////////////////////////// //////////////////////////////...
Namespace for the physical parameters in the problem.
Vector< double > Direction_of_gravity(2)
Gravity vector.
double Rayleigh
Rayleigh number, set to be greater than the threshold for linear instability.
double Inverse_Prandtl
1/Prandtl number
double Peclet
Peclet number (identically one from our non-dimensionalisation)
int main()
Driver code for 2D Boussinesq convection problem with adaptivity.