# Diff of /trunk/doc/examples/usersguide/wave.py

trunk/doc/examples/wave.py revision 2420 by gross, Thu May 14 02:28:58 2009 UTC trunk/doc/examples/usersguide/wave.py revision 2548 by jfenwick, Mon Jul 20 06:20:06 2009 UTC
# Line 1  Line 1
1
2  ########################################################  ########################################################
3  #  #
4  # Copyright (c) 2003-2008 by University of Queensland  # Copyright (c) 2003-2009 by University of Queensland
5  # Earth Systems Science Computational Center (ESSCC)  # Earth Systems Science Computational Center (ESSCC)
6  # http://www.uq.edu.au/esscc  # http://www.uq.edu.au/esscc
7  #  #
21
# You can shorten the execution time by reducing variable tend from 60 to 0.5

22  from esys.escript import *  from esys.escript import *
23  from esys.escript.pdetools import Locator  from esys.escript.pdetools import Locator
24  from esys.escript.linearPDEs import LinearPDE  from esys.escript.linearPDEs import LinearPDE
25  from esys.finley import Brick  from esys.finley import Brick
26  from numarray import identity,zeros,ones  from numpy import identity,zeros,ones

if not os.path.isdir("data"):
print "\nCreating subdirectory 'data'\n"
os.mkdir("data")
27
28  ne=32          # number of cells in x_0 and x_1 directions  ne=32          # number of cells in x_0 and x_1 directions
29  width=10000.  # length in x_0 and x_1 directions  width=10000.  # length in x_0 and x_1 directions
30  lam=3.462e9  lam=3.462e9
31  mu=3.462e9  mu=3.462e9
32  rho=1154.  rho=1154.
33  tend=60  tend=20. # to ran a full simulation change tend to 60.
34  h=(1./5.)*sqrt(rho/(lam+2*mu))*(width/ne)  alpha=0.7
35  print "time step size = ",h  t0=3.
36
37  U0=0.01 # amplitude of point source  U0=1. # maximum displacement
38    mkDir("data") # create directory data if it does not exist already.
39
40  def wavePropagation(domain,h,tend,lam,mu,rho,U0):  def wavePropagation(domain,h,tend,lam,mu,rho, xc, src_radius, U0):
41     x=domain.getX()     x=domain.getX()
42     # ... open new PDE ...     # ... open new PDE ...
43     mypde=LinearPDE(domain)     mypde=LinearPDE(domain)
44     mypde.setSolverMethod(LinearPDE.LUMPING)     mypde.getSolverOptions().setSolverMethod(mypde.getSolverOptions().LUMPING)
45     kronecker=identity(mypde.getDim())     kronecker=identity(mypde.getDim())
46
47     #  spherical source at middle of bottom face     dunit=numpy.array([1.,0.,0.]) # defines direction of point source

xc=[width/2.,width/2.,0.]
# define small radius around point xc
# Lsup(x) returns the maximum value of the argument x

dunit=numarray.array([1.,0.,0.]) # defines direction of point source
48
50     # ... set initial values ....     # ... set initial values ....
51     n=0     n=0
# initial value of displacement at point source is constant (U0=0.01)
52     # for first two time steps     # for first two time steps
55     t=0     t=0
56
57     # define the location of the point source     # define the location of the point source
58     L=Locator(domain,numarray.array(xc))     L=Locator(domain,xc)
59     # find potential at point source     # find potential at point source
60     u_pc=L.getValue(u)     u_pc=L.getValue(u)
61     print "u at point charge=",u_pc     print "u at point charge=",u_pc

u_pc_x = u_pc[0]
u_pc_y = u_pc[1]
u_pc_z = u_pc[2]

62     # open file to save displacement at point source     # open file to save displacement at point source
63     u_pc_data=FileWriter('./data/U_pc.out')     u_pc_data=FileWriter('./data/U_pc.out')
64     u_pc_data.write("%f %f %f %f\n"%(t,u_pc_x,u_pc_y,u_pc_z))     u_pc_data.write("%f %f %f %f\n"%(t,u_pc[0],u_pc[1],u_pc[2]))
65
66     while t<tend:     while t<tend:
67         t+=h
68       # ... get current stress ....       # ... get current stress ....
70       stress=lam*trace(g)*kronecker+mu*(g+transpose(g))       stress=lam*trace(g)*kronecker+mu*(g+transpose(g))
71       # ... get new acceleration ....       # ... get new acceleration ....
72       mypde.setValue(X=-stress)                 amplitude=U0*(4*(t-t0)**3/alpha**3-6*(t-t0)/alpha)*sqrt(2.)/alpha**2*exp(1./2.-(t-t0)**2/alpha**2)
73         mypde.setValue(X=-stress, r=dunit*amplitude)
74       a=mypde.getSolution()       a=mypde.getSolution()
75       # ... get new displacement ...       # ... get new displacement ...
76       u_new=2*u-u_last+h**2*a       u_new=2*u-u_last+h**2*a
77       # ... shift displacements ....       # ... shift displacements ....
78       u_last=u       u_last=u
79       u=u_new       u=u_new
t+=h
80       n+=1       n+=1
81       print n,"-th time step t ",t       print n,"-th time step t ",t
82       u_pc=L.getValue(u)       u_pc=L.getValue(u)
83       print "u at point charge=",u_pc       print "u at point charge=",u_pc

u_pc_x=u_pc[0]
u_pc_y=u_pc[1]
u_pc_z=u_pc[2]

84       # save displacements at point source to file for t > 0       # save displacements at point source to file for t > 0
85       u_pc_data.write("%f %f %f %f\n"%(t,u_pc_x,u_pc_y,u_pc_z))       u_pc_data.write("%f %f %f %f\n"%(t,u_pc[0],u_pc[1],u_pc[2]))
86
87       # ... save current acceleration in units of gravity and displacements       # ... save current acceleration in units of gravity and displacements
88       if n==1 or n%10==0: saveVTK("./data/usoln.%i.vtu"%(n/10),acceleration=length(a)/9.81,       if n==1 or n%10==0: saveVTK("./data/usoln.%i.vtu"%(n/10),acceleration=length(a)/9.81,
# Line 113  def wavePropagation(domain,h,tend,lam,mu Line 90  def wavePropagation(domain,h,tend,lam,mu
90
91     u_pc_data.close()     u_pc_data.close()
92
93  mydomain=Brick(ne,ne,10,l0=width,l1=width,l2=10.*width/32.)  mydomain=Brick(ne,ne,10,l0=width,l1=width,l2=10.*width/ne)
94  wavePropagation(mydomain,h,tend,lam,mu,rho,U0)  h=inf(1./5.)*inf(sqrt(rho/(lam+2*mu))*mydomain.getSize())
95    print "time step size = ",h
96    #  spherical source at middle of bottom face
97    xc=[width/2.,width/2.,0.]
98    # define small radius around point xc