4 import validationStationaryDiffusionEquation
6 import matplotlib.pyplot as plt
8 from math import log10, sqrt
11 convergence_synthesis=dict(validationStationaryDiffusionEquation.test_desc)
13 def convergence_StationaryDiffusion_2DFV_Dirichlet_DelaunayTriangles():
15 ### 2D FV Delaunay triangle meshes
18 meshList=['squareWithTriangles_1','squareWithTriangles_2','squareWithTriangles_3','squareWithTriangles_4','squareWithTriangles_5']
19 mesh_path=os.environ['CDMATH_INSTALL']+'/share/meshes//2DTriangles/'
20 mesh_name='squareWithDelaunayTriangles'
21 meshType="Unstructured_triangles"
22 nbMeshes=len(meshList)
23 error_tab=[0]*nbMeshes
24 mesh_size_tab=[0]*nbMeshes
25 diag_data=[0]*nbMeshes
28 curv_abs=np.linspace(0,sqrt(2),resolution+1)
32 # Storing of numerical errors, mesh sizes and diagonal values
33 for filename in meshList:
34 my_mesh=cm.Mesh(mesh_path+filename+".med")
35 error_tab[i], mesh_size_tab[i], diag_data[i], min_sol_num, max_sol_num, time_tab[i] =validationStationaryDiffusionEquation.SolveStationaryDiffusionEquation(my_mesh,resolution,meshType,method,BC)
38 assert max_sol_num<1.2
39 plt.plot(curv_abs, diag_data[i], label= str(mesh_size_tab[i]) + ' cells')
40 error_tab[i]=log10(error_tab[i])
41 time_tab[i]=log10(time_tab[i])
42 mesh_size_tab[i] = 0.5*log10(mesh_size_tab[i])
48 # Plot over diagonal line
50 plt.xlabel('Position on diagonal line')
51 plt.ylabel('Value on diagonal line')
52 plt.title('Plot over diagonal line for finite volumes for Poisson problem \n on 2D Delaunay triangles with Dirichlet BC')
53 plt.savefig(mesh_name+"_2DFV_StatDiffusion_Dirichlet_PlotOverDiagonalLine.png")
55 # Least square linear regression
56 # Find the best a,b such that f(x)=ax+b best approximates the convergence curve
57 # The vector X=(a,b) solves a symmetric linear system AX=B with A=(a1,a2\\a2,a3), B=(b1,b2)
58 a1=np.dot(mesh_size_tab,mesh_size_tab)
59 a2=np.sum(mesh_size_tab)
61 b1=np.dot(error_tab,mesh_size_tab)
65 assert det!=0, 'convergence_StationaryDiffusion_2DFV_Dirichlet_DelaunayTriangles() : Make sure you use distinct meshes and at least two meshes'
69 print "FV for diffusion on 2D Delaunay triangle meshes: scheme order is ", -a
70 assert abs(a+0.6)<0.02
72 # Plot of convergence curve
74 plt.plot(mesh_size_tab, error_tab, label='log(|numerical-exact|)')
75 plt.plot(mesh_size_tab, a*np.array(mesh_size_tab)+b,label='least square slope : '+'%.3f' % a)
77 plt.plot(mesh_size_tab, error_tab)
78 plt.xlabel('log(sqrt(number of cells))')
79 plt.ylabel('log(error)')
80 plt.title('Convergence of finite volumes for Poisson problem \n on 2D Delaunay triangles meshes with Dirichlet BC')
81 plt.savefig(mesh_name+"_2DFV_StatDiffusion_Dirichlet_ConvergenceCurve.png")
83 # Plot of computational time
85 plt.plot(mesh_size_tab, time_tab, label='log(cpu time)')
87 plt.xlabel('log(sqrt(number of cells))')
88 plt.ylabel('log(cpu time)')
89 plt.title('Computational time of finite volumes for Poisson problem \n on 2D Delaunay triangles meshes with Dirichlet BC')
90 plt.savefig(mesh_name+"_2DFV_StatDiffusion_Dirichlet_ComputationalTime.png")
94 convergence_synthesis["Mesh_names"]=meshList
95 convergence_synthesis["Mesh_type"]=meshType
96 #convergence_synthesis["Mesh_path"]=mesh_path
97 convergence_synthesis["Mesh_description"]=mesh_name
98 convergence_synthesis["Mesh_sizes"]=[10**x for x in mesh_size_tab]
99 convergence_synthesis["Space_dim"]=2
100 convergence_synthesis["Mesh_dim"]=2
101 convergence_synthesis["Mesh_cell_type"]="Triangles"
102 convergence_synthesis["Errors"]=[10**x for x in error_tab]
103 convergence_synthesis["Scheme_order"]=round(-a,4)
104 convergence_synthesis["Test_color"]=testColor
105 convergence_synthesis["PDE_model"]='Poisson'
106 convergence_synthesis["Num_method"]=method
107 convergence_synthesis["Bound_cond"]=BC
108 convergence_synthesis["Comput_time"]=round(end-start,3)
110 with open('Convergence_Poisson_2DFV_'+mesh_name+'.json', 'w') as outfile:
111 json.dump(convergence_synthesis, outfile)
114 if __name__ == """__main__""":
115 convergence_StationaryDiffusion_2DFV_Dirichlet_DelaunayTriangles()