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337 lines
12 KiB
Python
337 lines
12 KiB
Python
# Vector-U,A,V,RF
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# Tensors-S
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# Scalars-PEEQ
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def U(displacement,outfile,reop_N):
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#Access Spatial displacement
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fieldValues = displacement.values
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for valueX in fieldValues :
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i = valueX.nodeLabel
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ux = valueX.data[0]
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uy = valueX.data[1]
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uz = valueX.data[2]
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#Spatial displacement, <DataArray>
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Spatial_displacement"+'"'+" "+"NumberOfComponents="+'"'+"3"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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X,Y,Z = ux,uy,uz
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outfile.write('%11.8e'%X+' '+'%11.8e'%Y+' '+'%11.8e'%Z+'\n')
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outfile.write("</DataArray>"+'\n')
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#</DataArray>
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def A(acceleration,outfile,reop_N):
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#Access Spatial acceleration
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fieldValues = acceleration.values
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for valueX in fieldValues :
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i = valueX.nodeLabel
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ax = valueX.data[0]
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ay = valueX.data[1]
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az = valueX.data[2]
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#Spatial acceleration, <DataArray>
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Spatial_acceleration"+'"'+" "+"NumberOfComponents="+'"'+"3"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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X,Y,Z = ax,ay,az
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outfile.write('%11.8e'%X+' '+'%11.8e'%Y+' '+'%11.8e'%Z+'\n')
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outfile.write("</DataArray>"+'\n')
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#</DataArray>
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def V(velocity,outfile,reop_N):
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#Access Spatial velocity
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fieldValues = velocity.values
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for valueX in fieldValues :
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i = valueX.nodeLabel
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vx = valueX.data[0]
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vy = valueX.data[1]
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vz = valueX.data[2]
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#Spatial velocity, <DataArray>
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Spatial_velocity"+'"'+" "+"NumberOfComponents="+'"'+"3"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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X,Y,Z = vx,vy,vz
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outfile.write('%11.8e'%X+' '+'%11.8e'%Y+' '+'%11.8e'%Z+'\n')
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outfile.write("</DataArray>"+'\n')
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#</DataArray>
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def RF(Reaction_force,outfile,reop_N):
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#Access Reaction force
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fieldValues = Reaction_force.values
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for valueX in fieldValues :
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i = valueX.nodeLabel
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rfx = valueX.data[0]
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rfy = valueX.data[1]
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rfz = valueX.data[2]
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#Reaction force
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Reaction_force"+'"'+" "+"NumberOfComponents="+'"'+"3"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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X,Y,Z = rfx,rfy,rfz
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outfile.write('%11.8e'%X+' '+'%11.8e'%Y+' '+'%11.8e'%Z+'\n')
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outfile.write("</DataArray>"+'\n')
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#</DataArray>
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def PEEQ(Equivalent_plastic_strain,outfile,reop_N):
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#Equivalent plastic strain
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node_Equivalent_plastic_strain = Equivalent_plastic_strain.getSubs(position=ELEMENT_NODAL)
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fieldValues = node_Equivalent_plastic_strain.values
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for valueX in fieldValues :
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PEEQ_data= valueX.data
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#Equivalent plastic strain, <DataArray>
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Equivalent_plastic_strain"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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pd = PEEQ_data
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outfile.write('%11.8e'%pd+'\n')
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outfile.write('</DataArray>'+'\n')
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#</DataArray>
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def Stress(Stress,outfile,reop_N):
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#access Stress components
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node_Stress = Stress.getSubset(position=ELEMENT_NODAL)
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fieldValues = node_Stress.values
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for valueX in fieldValues :
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s11 = valueX.data[0]
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s22 = valueX.data[1]
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s33 = valueX.data[2]
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s12 = valueX.data[3]
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s23 = valueX.data[4]
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s13 = valueX.data[5]
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# L1[valueX.nodeLabel-1][7] += valueX.mises
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# L1[valueX.nodeLabel-1][8] += valueX.maxPrincipal
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# L1[valueX.nodeLabel-1][9] += valueX.midPrincipal
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# L1[valueX.nodeLabel-1][10] += valueX.minPrincipal
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# L1[valueX.nodeLabel-1][11] += valueX.press
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# L1[valueX.nodeLabel-1][12] += valueX.tresca
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# L1[valueX.nodeLabel-1][13] += valueX.inv3
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#Stress components, <DataArray>
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Components"+'"'+" "+"NumberOfComponents="+'"'+"9"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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XX,XY,XZ,YX,YY,YZ,ZX,ZY,ZZ = s11,s12,s13,s12,s22,s23,s13,s23,s33
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outfile.write('%11.8e'%XX+' '+'%11.8e'%XY+' '+'%11.8e'%XZ+' '+'%11.8e'%YX+' '+'%11.8e'%YY+' '+'%11.8e'%YZ+' '+'%11.8e'%ZX+' '+'%11.8e'%ZY+' '+'%11.8e'%ZZ+'\n')
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outfile.write("</DataArray>"+'\n')
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#</DataArray>
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def NT11(Temperature,outfile,reop_N):
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#Equivalent plastic strain
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fieldValues = Temperature.values
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for valueX in fieldValues :
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NT11_data= valueX.data
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#Equivalent plastic strain, <DataArray>
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outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Temperature"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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for i in reop_N:
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temp = NT11_data
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outfile.write('%11.8e'%temp+'\n')
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outfile.write('</DataArray>'+'\n')
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#</DataArray>
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# print "Reading U, A, V, RF ......"
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# time1 = time()
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# #Access Spatial displacement
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# displacement = N_Frame.fieldOutputs['U']
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# fieldValues = displacement.values
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# for valueX in fieldValues :
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# i = valueX.nodeLabel
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# L0[i-1][0] = valueX.data[0] ux
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# L0[i-1][1] = valueX.data[1] uy
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# L0[i-1][2] = valueX.data[2] uz
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# #Access Spatial acceleration
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# acceleration = N_Frame.fieldOutputs['A']
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# fieldValues = acceleration.values
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# for valueX in fieldValues :
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# i = valueX.nodeLabel
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# L0[i-1][3] = valueX.data[0] ax
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# L0[i-1][4] = valueX.data[1] ay
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# L0[i-1][5] = valueX.data[2] az
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# #Access Spatial velocity
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# velocity = N_Frame.fieldOutputs['V']
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# fieldValues = velocity.values
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# for valueX in fieldValues :
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# i = valueX.nodeLabel
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# L0[i-1][6] = valueX.data[0] vx
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# L0[i-1][7] = valueX.data[1] vy
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# L0[i-1][8] = valueX.data[2] vz
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# #Access Reaction force
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# Reaction_force = N_Frame.fieldOutputs['RF']
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# fieldValues = Reaction_force.values
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# for valueX in fieldValues :
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# i = valueX.nodeLabel
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# L0[i-1][9] = valueX.data[0] rfx
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# L0[i-1][10] = valueX.data[1] rfy
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# L0[i-1][11] = valueX.data[2] rfz
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# print "Time elapsed: ", time() - time1, "s"
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# print "Reading Stress ......"
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# time1 = time()
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# #access Stress components
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# Stress = N_Frame.fieldOutputs['S']
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# node_Stress = Stress.getSubset(position=ELEMENT_NODAL)
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# fieldValues = node_Stress.values
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# for valueX in fieldValues :
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# L1[valueX.nodeLabel-1][0] += 1
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# L1[valueX.nodeLabel-1][1] += valueX.data[0] s11
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# L1[valueX.nodeLabel-1][2] += valueX.data[1] s22
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# L1[valueX.nodeLabel-1][3] += valueX.data[2] s33
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# L1[valueX.nodeLabel-1][4] += valueX.data[3] s12
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# L1[valueX.nodeLabel-1][5] += valueX.data[4] s23
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# L1[valueX.nodeLabel-1][6] += valueX.data[5] s13
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# L1[valueX.nodeLabel-1][7] += valueX.mises
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# L1[valueX.nodeLabel-1][8] += valueX.maxPrincipal
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# L1[valueX.nodeLabel-1][9] += valueX.midPrincipal
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# L1[valueX.nodeLabel-1][10] += valueX.minPrincipal
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# L1[valueX.nodeLabel-1][11] += valueX.press
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# L1[valueX.nodeLabel-1][12] += valueX.tresca
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# L1[valueX.nodeLabel-1][13] += valueX.inv3
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# # can first ave
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# print "Time elapsed: ", time() - time1, "s"
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# print "Reading Equivalent plastic strain ......"
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# time1 = time()
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# #Equivalent plastic strain
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# Equivalent_plastic_strain = N_Frame.fieldOutputs['PEEQ']
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# node_Equivalent_plastic_strain = Equivalent_plastic_strain.getSubset(position=ELEMENT_NODAL)
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# fieldValues = node_Equivalent_plastic_strain.values
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# for valueX in fieldValues :
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# L4[valueX.nodeLabel-1][0] += 1
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# L4[valueX.nodeLabel-1][1] += valueX.data
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# print "Time elapsed: ", time() - time1, "s"
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# print "Reading Logarithmic strain ......"
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# time1 = time()
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# #Logarithmic strain components
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# Logarithmic_strain = N_Frame.fieldOutputs['LE']
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# node_Logarithmic_strain = Logarithmic_strain.getSubset(position=ELEMENT_NODAL)
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# fieldValues = node_Logarithmic_strain.values
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# for valueX in fieldValues :
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# L2[valueX.nodeLabel-1][0] += 1
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# L2[valueX.nodeLabel-1][1] += valueX.data[0]
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# L2[valueX.nodeLabel-1][2] += valueX.data[1]
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# L2[valueX.nodeLabel-1][3] += valueX.data[2]
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# L2[valueX.nodeLabel-1][4] += valueX.data[3]
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# L2[valueX.nodeLabel-1][5] += valueX.data[4]
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# L2[valueX.nodeLabel-1][6] += valueX.data[5]
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# L2[valueX.nodeLabel-1][7] += valueX.maxPrincipal
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# L2[valueX.nodeLabel-1][8] += valueX.minPrincipal
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# print "Time elapsed: ", time() - time1, "s"
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# print "Reading Plastic strain ......"
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# time1 = time()
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# #Plastic strain components
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# Plastic_strain = N_Frame.fieldOutputs['PE']
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# node_Plastic_strain = Plastic_strain.getSubset(position=ELEMENT_NODAL)
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# fieldValues = node_Plastic_strain.values
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# for valueX in fieldValues :
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# L3[valueX.nodeLabel-1][0] += 1
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# L3[valueX.nodeLabel-1][1] += valueX.data[0]
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# L3[valueX.nodeLabel-1][2] += valueX.data[1]
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# L3[valueX.nodeLabel-1][3] += valueX.data[2]
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# L3[valueX.nodeLabel-1][4] += valueX.data[3]
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# L3[valueX.nodeLabel-1][5] += valueX.data[4]
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# L3[valueX.nodeLabel-1][6] += valueX.data[5]
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# L3[valueX.nodeLabel-1][7] += valueX.maxPrincipal
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# L3[valueX.nodeLabel-1][8] += valueX.minPrincipal
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# print "Time elapsed: ", time() - time1, "s"
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#Logarithmic_strain_Max_Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Logarithmic_strain_Max_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = L2[k][7]
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Logarithmic strain Min.Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Logarithmic_strain_Min_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = L2[k][8]
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>'''
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#Plastic strain Max.Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Plastic_strain_Max_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = L3[k][7]
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Plastic strain Min.Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Plastic_strain_Min_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = L3[k][8]
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Mises, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Mises"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = smises
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Max.Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Max_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = maxPrincipal
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Mid.Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Mid_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = midPrincipal
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Min.Principal, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Min_Principal"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = minPrincipal
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Pressure, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Pressure"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = press
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Tresca, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Tresca"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = tresca
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray>
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# #Stress Third_Invariant, <DataArray>
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# outfile.write("<"+"DataArray"+" "+"type="+'"'+"Float32"+'"'+" "+"Name="+'"'+"Stress_Third_Invariant"+'"'+" "+"format="+'"'+"ascii"+'"'+">"+'\n')
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# for i in reop_N:
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# k = node[stg_n[i]].label-1
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# X = inv3
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# outfile.write('%11.8e'%X+'\n')
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# outfile.write('</DataArray>'+'\n')
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# #</DataArray> |