escript/py_src/flows.py

# $Id:$
#
#######################################################
#
#       Copyright 2008 by University of Queensland
#
#                http://esscc.uq.edu.au
#        Primary Business: Queensland, Australia
#  Licensed under the Open Software License version 3.0
#     http://www.opensource.org/licenses/osl-3.0.php
#
#######################################################
#

"""
Some models for flow

@var __author__: name of author
@var __copyright__: copyrights
@var __license__: licence agreement
@var __url__: url entry point on documentation
@var __version__: version
@var __date__: date of the version
"""

__author__="Lutz Gross, l.gross@uq.edu.au"
__copyright__="""  Copyright (c) 2008 by ACcESS MNRF
                    http://www.access.edu.au
                Primary Business: Queensland, Australia"""
__license__="""Licensed under the Open Software License version 3.0
             http://www.opensource.org/licenses/osl-3.0.php"""
__url__="http://www.iservo.edu.au/esys"
__version__="$Revision:$"
__date__="$Date:$"

from escript import *
import util
from linearPDEs import LinearPDE
from pdetools import HomogeneousSaddlePointProblem,Projector

class StokesProblemCartesian(HomogeneousSaddlePointProblem):
      """
      solves 

          -(eta*(u_{i,j}+u_{j,i}))_j - p_i = f_i
                u_{i,i}=0

          u=0 where  fixed_u_mask>0
          eta*(u_{i,j}+u_{j,i})*n_j=surface_stress 

      if surface_stress is not give 0 is assumed. 

      typical usage:

            sp=StokesProblemCartesian(domain)
            sp.setTolerance()
            sp.initialize(...)
            v,p=sp.solve(v0,p0)
      """
      def __init__(self,domain,**kwargs):
         HomogeneousSaddlePointProblem.__init__(self,**kwargs)
         self.domain=domain
         self.vol=util.integrate(1.,Function(self.domain))
         self.__pde_u=LinearPDE(domain,numEquations=self.domain.getDim(),numSolutions=self.domain.getDim())
         self.__pde_u.setSymmetryOn()
         self.__pde_u.setSolverMethod(preconditioner=LinearPDE.RILU)
            
         self.__pde_prec=LinearPDE(domain)
         self.__pde_prec.setReducedOrderOn()
         self.__pde_prec.setSymmetryOn()

         self.__pde_proj=LinearPDE(domain)
         self.__pde_proj.setReducedOrderOn()
         self.__pde_proj.setSymmetryOn()
         self.__pde_proj.setValue(D=1.)

      def initialize(self,f=Data(),fixed_u_mask=Data(),eta=1,surface_stress=Data()):
        self.eta=eta
        A =self.__pde_u.createCoefficientOfGeneralPDE("A")
    self.__pde_u.setValue(A=Data())
        for i in range(self.domain.getDim()):
        for j in range(self.domain.getDim()):
            A[i,j,j,i] += 1. 
            A[i,j,i,j] += 1.
    self.__pde_prec.setValue(D=1/eta) #1./self.eta
        self.__pde_u.setValue(A=A*self.eta,q=fixed_u_mask,Y=f,y=surface_stress)

      def B(self,arg):
         d=util.div(arg)
         self.__pde_proj.setValue(Y=d)
         self.__pde_proj.setTolerance(self.getSubProblemTolerance())
         return self.__pde_proj.getSolution(verbose=self.show_details)

      def inner(self,p0,p1):
         s0=util.interpolate(p0,Function(self.domain))
         s1=util.interpolate(p1,Function(self.domain))
         return util.integrate(s0*s1)

      def inner_a(self,a0,a1):
         p0=util.interpolate(a0[1],Function(self.domain))
         p1=util.interpolate(a1[1],Function(self.domain))
         alfa=(1/self.vol)*util.integrate(p0)
         beta=(1/self.vol)*util.integrate(p1)
     v0=util.grad(a0[0])
     v1=util.grad(a1[0])
     #print "NORM",alfa,beta,util.integrate((p0-alfa)*(p1-beta))+util.integrate(util.inner(v0,v1))
         return util.integrate((p0-alfa)*(p1-beta)+((1/self.eta)**2)*util.inner(v0,v1))


      def getStress(self,u):
         mg=util.grad(u)
         return 2.*self.eta*util.symmetric(mg)

      def solve_A(self,u,p):
         """
         solves Av=f-Au-B^*p (v=0 on fixed_u_mask)
         """
         self.__pde_u.setTolerance(self.getSubProblemTolerance())
         self.__pde_u.setValue(X=-self.getStress(u)-p*util.kronecker(self.domain))
         return  self.__pde_u.getSolution(verbose=self.show_details)


      def solve_prec(self,p):
     #proj=Projector(domain=self.domain, reduce = True, fast=False)
         self.__pde_prec.setTolerance(self.getSubProblemTolerance())
         self.__pde_prec.setValue(Y=p)
         q=self.__pde_prec.getSolution(verbose=self.show_details)
     q0=util.interpolate(q,Function(self.domain))
         q-=(1/self.vol)*util.integrate(q0)
         return q

      def stoppingcriterium(self,Bv,v,p):
          n_r=util.sqrt(self.inner(Bv,Bv))
          n_v=util.Lsup(v)
          if self.verbose: print "PCG step %s: L2(div(v)) = %s, Lsup(v)=%s"%(self.iter,n_r,n_v) 
          self.iter+=1
          if n_r <= self.vol**(1./2.-1./self.domain.getDim())*n_v*self.getTolerance():
              if self.verbose: print "PCG terminated after %s steps."%self.iter
              return True
          else:
              return False
      def stoppingcriterium2(self,norm_r,norm_b,solver='GMRES',TOL=None):
      if TOL==None:
             TOL=self.getTolerance()
          if self.verbose: print "%s step %s: L2(r) = %s, L2(b)*TOL=%s"%(solver,self.iter,norm_r,norm_b*TOL)
          self.iter+=1
          
          if norm_r <= norm_b*TOL:
              if self.verbose: print "%s terminated after %s steps."%(solver,self.iter)
              return True
          else:
              return False


1	# $Id:$
2	#
3	#######################################################
4	#
5	# Copyright 2008 by University of Queensland
6	#
7	# http://esscc.uq.edu.au
8	# Primary Business: Queensland, Australia
9	# Licensed under the Open Software License version 3.0
10	# http://www.opensource.org/licenses/osl-3.0.php
11	#
12	#######################################################
13	#
14
15	"""
16	Some models for flow
17
18	@var __author__: name of author
19	@var __copyright__: copyrights
20	@var __license__: licence agreement
21	@var __url__: url entry point on documentation
22	@var __version__: version
23	@var __date__: date of the version
24	"""
25
26	__author__="Lutz Gross, l.gross@uq.edu.au"
27	__copyright__=""" Copyright (c) 2008 by ACcESS MNRF
28	http://www.access.edu.au
29	Primary Business: Queensland, Australia"""
30	__license__="""Licensed under the Open Software License version 3.0
31	http://www.opensource.org/licenses/osl-3.0.php"""
32	__url__="http://www.iservo.edu.au/esys"
33	__version__="$Revision:$"
34	__date__="$Date:$"
35
36	from escript import *
37	import util
38	from linearPDEs import LinearPDE
39	from pdetools import HomogeneousSaddlePointProblem,Projector
40
41	class StokesProblemCartesian(HomogeneousSaddlePointProblem):
42	"""
43	solves
44
45	-(eta*(u_{i,j}+u_{j,i}))_j - p_i = f_i
46	u_{i,i}=0
47
48	u=0 where fixed_u_mask>0
49	eta(u_{i,j}+u_{j,i})n_j=surface_stress
50
51	if surface_stress is not give 0 is assumed.
52
53	typical usage:
54
55	sp=StokesProblemCartesian(domain)
56	sp.setTolerance()
57	sp.initialize(...)
58	v,p=sp.solve(v0,p0)
59	"""
60	def __init__(self,domain,**kwargs):
61	HomogeneousSaddlePointProblem.__init__(self,**kwargs)
62	self.domain=domain
63	self.vol=util.integrate(1.,Function(self.domain))
64	self.__pde_u=LinearPDE(domain,numEquations=self.domain.getDim(),numSolutions=self.domain.getDim())
65	self.__pde_u.setSymmetryOn()
66	self.__pde_u.setSolverMethod(preconditioner=LinearPDE.RILU)
67
68	self.__pde_prec=LinearPDE(domain)
69	self.__pde_prec.setReducedOrderOn()
70	self.__pde_prec.setSymmetryOn()
71
72	self.__pde_proj=LinearPDE(domain)
73	self.__pde_proj.setReducedOrderOn()
74	self.__pde_proj.setSymmetryOn()
75	self.__pde_proj.setValue(D=1.)
76
77	def initialize(self,f=Data(),fixed_u_mask=Data(),eta=1,surface_stress=Data()):
78	self.eta=eta
79	A =self.__pde_u.createCoefficientOfGeneralPDE("A")
80	self.__pde_u.setValue(A=Data())
81	for i in range(self.domain.getDim()):
82	for j in range(self.domain.getDim()):
83	A[i,j,j,i] += 1.
84	A[i,j,i,j] += 1.
85	self.__pde_prec.setValue(D=1/eta) #1./self.eta
86	self.__pde_u.setValue(A=A*self.eta,q=fixed_u_mask,Y=f,y=surface_stress)
87
88	def B(self,arg):
89	d=util.div(arg)
90	self.__pde_proj.setValue(Y=d)
91	self.__pde_proj.setTolerance(self.getSubProblemTolerance())
92	return self.__pde_proj.getSolution(verbose=self.show_details)
93
94	def inner(self,p0,p1):
95	s0=util.interpolate(p0,Function(self.domain))
96	s1=util.interpolate(p1,Function(self.domain))
97	return util.integrate(s0*s1)
98
99	def inner_a(self,a0,a1):
100	p0=util.interpolate(a0[1],Function(self.domain))
101	p1=util.interpolate(a1[1],Function(self.domain))
102	alfa=(1/self.vol)*util.integrate(p0)
103	beta=(1/self.vol)*util.integrate(p1)
104	v0=util.grad(a0[0])
105	v1=util.grad(a1[0])
106	#print "NORM",alfa,beta,util.integrate((p0-alfa)*(p1-beta))+util.integrate(util.inner(v0,v1))
107	return util.integrate((p0-alfa)(p1-beta)+((1/self.eta)2)util.inner(v0,v1))
108
109
110	def getStress(self,u):
111	mg=util.grad(u)
112	return 2.self.etautil.symmetric(mg)
113
114	def solve_A(self,u,p):
115	"""
116	solves Av=f-Au-B^*p (v=0 on fixed_u_mask)
117	"""
118	self.__pde_u.setTolerance(self.getSubProblemTolerance())
119	self.__pde_u.setValue(X=-self.getStress(u)-p*util.kronecker(self.domain))
120	return self.__pde_u.getSolution(verbose=self.show_details)
121
122
123	def solve_prec(self,p):
124	#proj=Projector(domain=self.domain, reduce = True, fast=False)
125	self.__pde_prec.setTolerance(self.getSubProblemTolerance())
126	self.__pde_prec.setValue(Y=p)
127	q=self.__pde_prec.getSolution(verbose=self.show_details)
128	q0=util.interpolate(q,Function(self.domain))
129	q-=(1/self.vol)*util.integrate(q0)
130	return q
131
132	def stoppingcriterium(self,Bv,v,p):
133	n_r=util.sqrt(self.inner(Bv,Bv))
134	n_v=util.Lsup(v)
135	if self.verbose: print "PCG step %s: L2(div(v)) = %s, Lsup(v)=%s"%(self.iter,n_r,n_v)
136	self.iter+=1
137	if n_r <= self.vol*(1./2.-1./self.domain.getDim())n_v*self.getTolerance():
138	if self.verbose: print "PCG terminated after %s steps."%self.iter
139	return True
140	else:
141	return False
142	def stoppingcriterium2(self,norm_r,norm_b,solver='GMRES',TOL=None):
143	if TOL==None:
144	TOL=self.getTolerance()
145	if self.verbose: print "%s step %s: L2(r) = %s, L2(b)TOL=%s"%(solver,self.iter,norm_r,norm_bTOL)
146	self.iter+=1
147
148	if norm_r <= norm_b*TOL:
149	if self.verbose: print "%s terminated after %s steps."%(solver,self.iter)
150	return True
151	else:
152	return False
153
154