1 import WaveSystemCentered
2 import matplotlib.pyplot as plt
4 from math import log10, sqrt
8 def test_validation2DWaveSystemSourceCenteredDeformedQuadrangles(bctype,scaling):
10 #### 2D deformed quadrangles mesh
11 meshList=['squareWithDeformedQuadrangles_1','squareWithDeformedQuadrangles_2','squareWithDeformedQuadrangles_3','squareWithDeformedQuadrangles_4','squareWithDeformedQuadrangles_5']#,'squareWithDeformedQuadrangles_6'
12 meshType="Deformed quadrangles"
14 nbMeshes=len(meshList)
15 error_p_tab=[0]*nbMeshes
16 error_u_tab=[0]*nbMeshes
17 mesh_size_tab=[0]*nbMeshes
18 mesh_path='../../../ressources/2DDeformedQuadrangles/'
19 mesh_name='squareWithDeformedQuadrangles'
20 diag_data_press=[0]*nbMeshes
21 diag_data_vel=[0]*nbMeshes
24 ndt_final=[0]*nbMeshes
27 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 error_p_tab[i], error_u_tab[i], mesh_size_tab[i], t_final[i], ndt_final[i], max_vel[i], diag_data_press[i], diag_data_vel[i], time_tab[i] =WaveSystemSourceCentered.solve_file(mesh_path+filename, mesh_name, resolution, scaling,meshType,testColor,cfl,bctype,True)
35 assert max_vel[i]>0.001 and max_vel[i]<0.01
36 error_p_tab[i]=log10(error_p_tab[i])
37 error_u_tab[i]=log10(error_u_tab[i])
38 time_tab[i]=log10(time_tab[i])
43 # Plot over diagonal line
44 for i in range(nbMeshes):
45 plt.plot(curv_abs, diag_data_press[i], label= str(mesh_size_tab[i]) + ' cells')
47 plt.xlabel('Position on diagonal line')
48 plt.ylabel('Pressure on diagonal line')
49 plt.title('Plot over diagonal line for stationary wave system \n with Centered scheme on 2D deformed quadrangular meshes')
50 plt.savefig(mesh_name+'_Pressure_2DWaveSystemSourceCentered_'+"PlotOverDiagonalLine.png")
54 for i in range(nbMeshes):
55 plt.plot(curv_abs, diag_data_vel[i], label= str(mesh_size_tab[i]) + ' cells')
57 plt.xlabel('Position on diagonal line')
58 plt.ylabel('Velocity on diagonal line')
59 plt.title('Plot over diagonal line for the stationary wave system \n with Centered scheme on 2D deformed quadrangular meshes')
60 plt.savefig(mesh_name+"_Velocity_2DWaveSystemSourceCentered_"+"PlotOverDiagonalLine.png")
63 # Plot of number of time steps
65 plt.plot(mesh_size_tab, ndt_final, label='Number of time step to reach stationary regime')
67 plt.xlabel('Number of cells')
68 plt.ylabel('Max time steps for stationary regime')
69 plt.title('Number of times steps required for the stationary Wave System \n with Centered scheme on 2D deformed quadrangular meshes')
70 plt.savefig(mesh_name+"_2DWaveSystemSourceCentered_"+"TimeSteps.png")
72 # Plot of number of stationary time
74 plt.plot(mesh_size_tab, t_final, label='Time where stationary regime is reached')
76 plt.xlabel('Number of cells')
77 plt.ylabel('Max time for stationary regime')
78 plt.title('Simulated time for the stationary Wave System \n with Centered scheme on 2D deformed quadrangular meshes')
79 plt.savefig(mesh_name+"_2DWaveSystemSourceCentered_"+"TimeFinal.png")
81 # Plot of number of maximal velocity norm
83 plt.plot(mesh_size_tab, max_vel, label='Maximum velocity norm')
85 plt.xlabel('Number of cells')
86 plt.ylabel('Max velocity norm')
87 plt.title('Maximum velocity norm for the stationary Wave System \n with Centered scheme on 2D deformed quadrangular meshes')
88 plt.savefig(mesh_name+"_2DWaveSystemSourceCentered_"+"MaxVelNorm.png")
90 for i in range(nbMeshes):
91 mesh_size_tab[i]=0.5*log10(mesh_size_tab[i])
93 # Least square linear regression
94 # Find the best a,b such that f(x)=ax+b best approximates the convergence curve
95 # The vector X=(a,b) solves a symmetric linear system AX=B with A=(a1,a2\\a2,a3), B=(b1,b2)
96 a1=np.dot(mesh_size_tab,mesh_size_tab)
97 a2=np.sum(mesh_size_tab)
101 assert det!=0, 'test_validation2DWaveSystemSourceCenteredDeformedQuadranglesFV() : Make sure you use distinct meshes and at least two meshes'
103 b1p=np.dot(error_p_tab,mesh_size_tab)
104 b2p=np.sum(error_p_tab)
105 ap=( a3*b1p-a2*b2p)/det
106 bp=(-a2*b1p+a1*b2p)/det
108 print( "FV Centered on 2D deformed quadrangles meshes : scheme order for pressure is ", -ap)
110 b1u=np.dot(error_u_tab,mesh_size_tab)
111 b2u=np.sum(error_u_tab)
112 au=( a3*b1u-a2*b2u)/det
113 bu=(-a2*b1u+a1*b2u)/det
115 print( "FV Centered on 2D deformed quadrangles meshes : scheme order for velocity is ", -au)
117 # Plot of convergence curves
119 plt.plot(mesh_size_tab, error_p_tab, label='|error on stationary pressure|')
121 plt.xlabel('1/2 log(number of cells)')
122 plt.ylabel('log(error p)')
123 plt.title('Convergence of finite volumes for the stationary Wave System \n with Centered scheme on 2D deformed quadrangular meshes')
124 plt.savefig(mesh_name+"_Pressure_2DWaveSystemSourceCentered_"+"ConvergenceCurve.png")
127 plt.plot(mesh_size_tab, error_u_tab, label='|error on stationary velocity|')
129 plt.xlabel('1/2 log(number of cells)')
130 plt.ylabel('log(error u)')
131 plt.title('Convergence of finite volumes for the stationary Wave System \n with Centered scheme on 2D deformed quadrangular meshes')
132 plt.savefig(mesh_name+"_Velocity_2DWaveSystemSourceCentered_"+"ConvergenceCurve.png")
134 # Plot of computational time
136 plt.plot(mesh_size_tab, time_tab, label='log(cpu time)')
138 plt.xlabel('1/2 log(number of cells)')
139 plt.ylabel('log(cpu time)')
140 plt.title('Computational time of finite volumes for the stationary Wave System \n with Centered scheme on 2D deformed quadrangular meshes')
141 plt.savefig(mesh_name+"_2DWaveSystemSourceCentered_ComputationalTime.png")
145 convergence_synthesis={}
147 convergence_synthesis["PDE_model"]="Wave system"
148 convergence_synthesis["PDE_is_stationary"]=False
149 convergence_synthesis["PDE_search_for_stationary_solution"]=True
150 convergence_synthesis["Numerical_method_name"]="Centered"
151 convergence_synthesis["Numerical_method_space_discretization"]="Finite volumes"
152 convergence_synthesis["Numerical_method_time_discretization"]="Implicit"
153 convergence_synthesis["Initial_data"]="Constant pressure, divergence free velocity"
154 convergence_synthesis["Boundary_conditions"]="Periodic"
155 convergence_synthesis["Numerical_parameter_cfl"]=cfl
156 convergence_synthesis["Space_dimension"]=2
157 convergence_synthesis["Mesh_dimension"]=2
158 convergence_synthesis["Mesh_names"]=meshList
159 convergence_synthesis["Mesh_type"]=meshType
160 convergence_synthesis["Mesh_path"]=mesh_path
161 convergence_synthesis["Mesh_description"]=mesh_name
162 convergence_synthesis["Mesh_sizes"]=mesh_size_tab
163 convergence_synthesis["Mesh_cell_type"]="Deformed quadrangles"
164 convergence_synthesis["Numerical_error_velocity"]=error_u_tab
165 convergence_synthesis["Numerical_error_pressure"]=error_p_tab
166 convergence_synthesis["Max_vel_norm"]=max_vel
167 convergence_synthesis["Final_time"]=t_final
168 convergence_synthesis["Final_time_step"]=ndt_final
169 convergence_synthesis["Scheme_order"]=min(-au,-ap)
170 convergence_synthesis["Scheme_order_vel"]=-au
171 convergence_synthesis["Scheme_order_press"]=-ap
172 convergence_synthesis["Scaling_preconditioner"]="None"
173 convergence_synthesis["Test_color"]=testColor
174 convergence_synthesis["Computational_time"]=end-start
176 with open('Convergence_WaveSystemSource_2DFV_Centered_'+mesh_name+'.json', 'w') as outfile:
177 json.dump(convergence_synthesis, outfile)
179 if __name__ == """__main__""":
180 if len(sys.argv) >2 :
182 scaling = int(sys.argv[2])
183 test_validation2DWaveSystemSourceCenteredDeformedQuadrangles(bctype,scaling)
185 raise ValueError("test_validation2DWaveSystemSourceCenteredDeformedQuadrangles.py expects a mesh file name and a scaling parameter")