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edición aprobada el 7 nov. 2016 a las 22:29
Randall Sandoval
edición aprobada el 7 nov. 2016 a las 22:29
Randall Sandoval
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Identación del código
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ChemaCortes
ChemaCortes
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M=N=8

def I00(x,i,m,a):
    I00=X(x,i,a)*X(x,m,a)
    return I00
K=np.zeros(shape=(m*n,m*n))
M=np.zeros(shape=(m*n,m*n))

mmm=np.linspace(0,m,num=m,endpoint=False,dtype='int')
ii=np.linspace(0,m,num=m,endpoint=False,dtype='int')
nnn=np.linspace(0,n,num=n,endpoint=False,dtype='int')
jj=np.linspace(0,n,num=n,endpoint=False,dtype='int')
mii=np.linspace(0,n*m,num=m,endpoint=False,dtype='int')
njj=np.linspace(0,n*m,num=n,endpoint=False,dtype='int')

    for i,mi in zip(ii,mii):
    for j in jj:
        for mm,nj in zip(mmm,njj):
            for nn in nnn:
                    
                K[mi+j][nj+nn]=(D[0][0]*integrate.quad(I22,0,a,args=(mm+1,i+1,a))[0]
                    
                 K[mi+j][nj+nn]=(D[0][0]*integrate.quad(I22,0,a,args=(mm+1,i+1,a))[0]*integrate   *integrate.quad(I00,0,b,args=(nn+1,j+1,b))[0]) +
  +                             (D[1][1]*integrate.quad(I00,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                       *integrate.quad(I22,0,b,args=(nn+1,j+1,b))[0]) +
   +                            (D[0][1]*((integrate.quad(I20,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                         *integrate.quad(I02,0,b,args=(nn+1,j+1,b))[0]) +
                                         (integrate.quad(I02,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                         *integrate.quad(I20,0,b,args=(nn+1,j+1,b))[0]))) +
                               (4*D[2][2]*integrate.quad(I11,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                         *integrate.quad(I11,0,b,args=(nn+1,j+1,b))[0]) +
                               (2*D[0][2]*((integrate.quad(I21,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                           *integrate.quad(I01,0,b,args=(nn+1,j+1,b))[0]) +
                                           (integrate.quad(I12,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                           *integrate.quad(I10,0,b,args=(nn+1,j+1,b))[0]))) +
                               (2*D[1][2]*((integrate.quad(I10,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                           *integrate.quad(I12,0,b,args=(nn+1,j+1,b))[0]) +
                                           (integrate.quad(I01,0,a,args=(mm+1,i+1,a))[0]*integrate[0]
                                           *integrate.quad(I21,0,b,args=(nn+1,j+1,b))[0])))
                
                M[mi+j][nj+nn]=rho*h*integrate.quad(I00, 0, a, args=(mm+1,i+1,a))[0]*integrate[0]
                                    *integrate.quad(I00, 0, b, args=(nn+1,j+1,b))[0]
                                  

M=N=8

def I00(x,i,m,a):
    I00=X(x,i,a)*X(x,m,a)
    return I00
K=np.zeros(shape=(m*n,m*n))
M=np.zeros(shape=(m*n,m*n))

mmm=np.linspace(0,m,num=m,endpoint=False,dtype='int')
ii=np.linspace(0,m,num=m,endpoint=False,dtype='int')
nnn=np.linspace(0,n,num=n,endpoint=False,dtype='int')
jj=np.linspace(0,n,num=n,endpoint=False,dtype='int')
mii=np.linspace(0,n*m,num=m,endpoint=False,dtype='int')
njj=np.linspace(0,n*m,num=n,endpoint=False,dtype='int')

    for i,mi in zip(ii,mii):
    for j in jj:
        for mm,nj in zip(mmm,njj):
            for nn in nnn:
                    
              
                    
                 K[mi+j][nj+nn]=(D[0][0]*integrate.quad(I22,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I00,0,b,args=(nn+1,j+1,b))[0])   +   (D[1][1]*integrate.quad(I00,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I22,0,b,args=(nn+1,j+1,b))[0])   +   (D[0][1]*((integrate.quad(I20,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I02,0,b,args=(nn+1,j+1,b))[0]) + (integrate.quad(I02,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I20,0,b,args=(nn+1,j+1,b))[0]))) + (4*D[2][2]*integrate.quad(I11,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I11,0,b,args=(nn+1,j+1,b))[0]) + (2*D[0][2]*((integrate.quad(I21,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I01,0,b,args=(nn+1,j+1,b))[0])+ (integrate.quad(I12,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I10,0,b,args=(nn+1,j+1,b))[0]))) + (2*D[1][2]*((integrate.quad(I10,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I12,0,b,args=(nn+1,j+1,b))[0]) + (integrate.quad(I01,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I21,0,b,args=(nn+1,j+1,b))[0])))
                M[mi+j][nj+nn]=rho*h*integrate.quad(I00, 0, a, args=(mm+1,i+1,a))[0]*integrate.quad(I00, 0, b, args=(nn+1,j+1,b))[0]
                 

M=N=8

def I00(x,i,m,a):
    I00=X(x,i,a)*X(x,m,a)
    return I00
K=np.zeros(shape=(m*n,m*n))
M=np.zeros(shape=(m*n,m*n))

mmm=np.linspace(0,m,num=m,endpoint=False,dtype='int')
ii=np.linspace(0,m,num=m,endpoint=False,dtype='int')
nnn=np.linspace(0,n,num=n,endpoint=False,dtype='int')
jj=np.linspace(0,n,num=n,endpoint=False,dtype='int')
mii=np.linspace(0,n*m,num=m,endpoint=False,dtype='int')
njj=np.linspace(0,n*m,num=n,endpoint=False,dtype='int')

for i,mi in zip(ii,mii):
    for j in jj:
        for mm,nj in zip(mmm,njj):
            for nn in nnn:
                    
                K[mi+j][nj+nn]=(D[0][0]*integrate.quad(I22,0,a,args=(mm+1,i+1,a))[0]
                                       *integrate.quad(I00,0,b,args=(nn+1,j+1,b))[0]) +
                               (D[1][1]*integrate.quad(I00,0,a,args=(mm+1,i+1,a))[0]
                                       *integrate.quad(I22,0,b,args=(nn+1,j+1,b))[0]) +
                               (D[0][1]*((integrate.quad(I20,0,a,args=(mm+1,i+1,a))[0]
                                         *integrate.quad(I02,0,b,args=(nn+1,j+1,b))[0]) +
                                         (integrate.quad(I02,0,a,args=(mm+1,i+1,a))[0]
                                         *integrate.quad(I20,0,b,args=(nn+1,j+1,b))[0]))) +
                               (4*D[2][2]*integrate.quad(I11,0,a,args=(mm+1,i+1,a))[0]
                                         *integrate.quad(I11,0,b,args=(nn+1,j+1,b))[0]) +
                               (2*D[0][2]*((integrate.quad(I21,0,a,args=(mm+1,i+1,a))[0]
                                           *integrate.quad(I01,0,b,args=(nn+1,j+1,b))[0]) +
                                           (integrate.quad(I12,0,a,args=(mm+1,i+1,a))[0]
                                           *integrate.quad(I10,0,b,args=(nn+1,j+1,b))[0]))) +
                               (2*D[1][2]*((integrate.quad(I10,0,a,args=(mm+1,i+1,a))[0]
                                           *integrate.quad(I12,0,b,args=(nn+1,j+1,b))[0]) +
                                           (integrate.quad(I01,0,a,args=(mm+1,i+1,a))[0]
                                           *integrate.quad(I21,0,b,args=(nn+1,j+1,b))[0])))
                
                M[mi+j][nj+nn]=rho*h*integrate.quad(I00, 0, a, args=(mm+1,i+1,a))[0]
                                    *integrate.quad(I00, 0, b, args=(nn+1,j+1,b))[0]
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user21428
user21428
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Optimización de un bucle for

Buenas, ando liado con una matriz que se crea con un bucle for múltiple que a su vez dentro del bucle se integra a través de la función quad el tamaño de la matriz depende de unos valores de m y n. Para unos valores de m y n de 8 tarda aproximadamente unos 180 segundos (3 minutos) en crear la matriz. Algún consejo para optimizar el llenado de la matriz.

Un saludo.

M=N=8

def I00(x,i,m,a):
    I00=X(x,i,a)*X(x,m,a)
    return I00
K=np.zeros(shape=(m*n,m*n))
M=np.zeros(shape=(m*n,m*n))

mmm=np.linspace(0,m,num=m,endpoint=False,dtype='int')
ii=np.linspace(0,m,num=m,endpoint=False,dtype='int')
nnn=np.linspace(0,n,num=n,endpoint=False,dtype='int')
jj=np.linspace(0,n,num=n,endpoint=False,dtype='int')
mii=np.linspace(0,n*m,num=m,endpoint=False,dtype='int')
njj=np.linspace(0,n*m,num=n,endpoint=False,dtype='int')

    for i,mi in zip(ii,mii):
    for j in jj:
        for mm,nj in zip(mmm,njj):
            for nn in nnn:
                    
              
                    
                K[mi+j][nj+nn]=(D[0][0]*integrate.quad(I22,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I00,0,b,args=(nn+1,j+1,b))[0])   +   (D[1][1]*integrate.quad(I00,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I22,0,b,args=(nn+1,j+1,b))[0])   +   (D[0][1]*((integrate.quad(I20,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I02,0,b,args=(nn+1,j+1,b))[0]) + (integrate.quad(I02,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I20,0,b,args=(nn+1,j+1,b))[0]))) + (4*D[2][2]*integrate.quad(I11,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I11,0,b,args=(nn+1,j+1,b))[0]) + (2*D[0][2]*((integrate.quad(I21,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I01,0,b,args=(nn+1,j+1,b))[0])+ (integrate.quad(I12,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I10,0,b,args=(nn+1,j+1,b))[0]))) + (2*D[1][2]*((integrate.quad(I10,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I12,0,b,args=(nn+1,j+1,b))[0]) + (integrate.quad(I01,0,a,args=(mm+1,i+1,a))[0]*integrate.quad(I21,0,b,args=(nn+1,j+1,b))[0])))
                M[mi+j][nj+nn]=rho*h*integrate.quad(I00, 0, a, args=(mm+1,i+1,a))[0]*integrate.quad(I00, 0, b, args=(nn+1,j+1,b))[0]