doc/cookbook/sb2.py


########################################################
#
# Copyright (c) 2003-2008 by University of Queensland
# Earth Systems Science Computational Center (ESSCC)
# http://www.uq.edu.au/esscc
#
# Primary Business: Queensland, Australia
# Licensed under the Open Software License version 3.0
# http://www.opensource.org/licenses/osl-3.0.php
#
########################################################

__copyright__="""Copyright (c) 2003-2008 by University of Queensland
Earth Systems Science Computational Center (ESSCC)
http://www.uq.edu.au/esscc
Primary Business: Queensland, Australia"""
__license__="""Licensed under the Open Software License version 3.0
http://www.opensource.org/licenses/osl-3.0.php"""
__url__="https://launchpad.net/escript-finley"

"""
Author: Lutz Gross, l.gross@uq.edu.au
Author: John Ngui, john.ngui@uq.edu.au
"""

# Import the necessary modules.
from esys.escript import *
from esys.escript.linearPDEs import LinearPDE
from esys.finley import Rectangle
from esys.pyvisi import Scene, DataCollector, Map, Camera
from esys.pyvisi.constant import *
import os

PYVISI_EXAMPLE_IMAGES_PATH = "data_sample_images"
X_SIZE = 400
Y_SIZE = 400
JPG_RENDERER = Renderer.ONLINE_JPG

#... set some parameters ...
qc=50.e6
Tref=0.
rhocp=2.6e6
eta=75.
kappa=240.
tend=5.
# ... time, time step size and counter ...
t=0
h=0.1
i=0

#... generate domain ...
mydomain = Rectangle(l0=0.05,l1=0.01,n0=250, n1=50)
#... open PDE ...
mypde=LinearPDE(mydomain)
mypde.setSymmetryOn()
mypde.setValue(A=kappa*kronecker(mydomain),D=rhocp/h,d=eta,y=eta*Tref)
# ... set heat source: ....
x=mydomain.getX()

# ... set initial temperature ....
T=0.1*whereNonNegative(x[0]-0.025)
T=-0.1*whereNonPositive(x[0]-0.025)
qH=0*qc*whereZero(x[0]-0.001)
# Create a Scene.
s = Scene(renderer = JPG_RENDERER, x_size = X_SIZE, y_size = Y_SIZE)

# Create a DataCollector reading directly from escript objects.
dc = DataCollector(source = Source.ESCRIPT)

# Create a Map.
m = Map(scene = s, data_collector = dc, \
        viewport = Viewport.SOUTH_WEST, lut = Lut.COLOR, \
        cell_to_point = False, outline = True)

# Create a Camera.
c = Camera(scene = s, viewport = Viewport.SOUTH_WEST)

dc.setData(temp = T)
      
# Render the object.
s.render(image_name = os.path.join(PYVISI_EXAMPLE_IMAGES_PATH, \
              "diffusion%02d.jpg") % i)

# ... start iteration:
while t<1.0:
      i+=1
      t+=h
      mypde.setValue(Y=qH+rhocp/h*T)
      T=mypde.getSolution()

      dc.setData(temp = T)
      
      # Render the object.
      s.render(image_name = os.path.join(PYVISI_EXAMPLE_IMAGES_PATH, \
              "diffusion%02d.jpg") % i)

1
2	########################################################
3	#
4	# Copyright (c) 2003-2008 by University of Queensland
5	# Earth Systems Science Computational Center (ESSCC)
6	# http://www.uq.edu.au/esscc
7	#
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	__copyright__="""Copyright (c) 2003-2008 by University of Queensland
15	Earth Systems Science Computational Center (ESSCC)
16	http://www.uq.edu.au/esscc
17	Primary Business: Queensland, Australia"""
18	__license__="""Licensed under the Open Software License version 3.0
19	http://www.opensource.org/licenses/osl-3.0.php"""
20	__url__="https://launchpad.net/escript-finley"
21
22	"""
23	Author: Lutz Gross, l.gross@uq.edu.au
24	Author: John Ngui, john.ngui@uq.edu.au
25	"""
26
27	# Import the necessary modules.
28	from esys.escript import *
29	from esys.escript.linearPDEs import LinearPDE
30	from esys.finley import Rectangle
31	from esys.pyvisi import Scene, DataCollector, Map, Camera
32	from esys.pyvisi.constant import *
33	import os
34
35	PYVISI_EXAMPLE_IMAGES_PATH = "data_sample_images"
36	X_SIZE = 400
37	Y_SIZE = 400
38	JPG_RENDERER = Renderer.ONLINE_JPG
39
40	#... set some parameters ...
41	qc=50.e6
42	Tref=0.
43	rhocp=2.6e6
44	eta=75.
45	kappa=240.
46	tend=5.
47	# ... time, time step size and counter ...
48	t=0
49	h=0.1
50	i=0
51
52	#... generate domain ...
53	mydomain = Rectangle(l0=0.05,l1=0.01,n0=250, n1=50)
54	#... open PDE ...
55	mypde=LinearPDE(mydomain)
56	mypde.setSymmetryOn()
57	mypde.setValue(A=kappakronecker(mydomain),D=rhocp/h,d=eta,y=etaTref)
58	# ... set heat source: ....
59	x=mydomain.getX()
60
61	# ... set initial temperature ....
62	T=0.1*whereNonNegative(x[0]-0.025)
63	T=-0.1*whereNonPositive(x[0]-0.025)
64	qH=0qcwhereZero(x[0]-0.001)
65	# Create a Scene.
66	s = Scene(renderer = JPG_RENDERER, x_size = X_SIZE, y_size = Y_SIZE)
67
68	# Create a DataCollector reading directly from escript objects.
69	dc = DataCollector(source = Source.ESCRIPT)
70
71	# Create a Map.
72	m = Map(scene = s, data_collector = dc, \
73	viewport = Viewport.SOUTH_WEST, lut = Lut.COLOR, \
74	cell_to_point = False, outline = True)
75
76	# Create a Camera.
77	c = Camera(scene = s, viewport = Viewport.SOUTH_WEST)
78
79	dc.setData(temp = T)
80
81	# Render the object.
82	s.render(image_name = os.path.join(PYVISI_EXAMPLE_IMAGES_PATH, \
83	"diffusion%02d.jpg") % i)
84
85	# ... start iteration:
86	while t<1.0:
87	i+=1
88	t+=h
89	mypde.setValue(Y=qH+rhocp/h*T)
90	T=mypde.getSolution()
91
92	dc.setData(temp = T)
93
94	# Render the object.
95	s.render(image_name = os.path.join(PYVISI_EXAMPLE_IMAGES_PATH, \
96	"diffusion%02d.jpg") % i)
97