def test1(self):
'mccomponents.sample.samplecomponent: IsotropicKernel'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-isotropickernel/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
for i in range(10):
neutron = neutrons[i]
print neutron
continue
# N should be about 2/3 of N0. this is determined by
# the mc weights in Al-isotropic-kernel-plate-scatterer.xml
self.assert_( N < 0.72*N0 and N > 0.6*N0)
return
def test1(self):
'mccomponents.sample.samplecomponent'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Ni', 'sampleassemblies/Ni/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
neutrons = mcni.neutron_buffer( 1 )
from mcni.pyre_support.ConsoleNeutronTracer import ConsoleNeutronTracer
tracer = ConsoleNeutronTracer()
mcni.simulate(
instrument, geometer, neutrons,
multiple_scattering=True,
tracer = tracer
)
return
def test1(self):
'mccomponents.sample.samplecomponent'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,4149.48), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'V-constantE', 'sampleassemblies/V-constantE/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
neutrons = mcni.neutron_buffer( 1 )
from mcni.pyre_support.ConsoleNeutronTracer import ConsoleNeutronTracer
tracer = ConsoleNeutronTracer()
mcni.simulate(
instrument, geometer, neutrons,
multiple_scattering=True,
tracer = tracer
)
return
def test1(self):
'mccomponents.sample.samplecomponent: IsotropicKernel'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-isotropickernel/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
for i in range(10):
neutron = neutrons[i]
print neutron
continue
# N should be about 2/3 of N0. this is determined by
# the mc weights in Al-isotropic-kernel-plate-scatterer.xml
self.assert_( N < 0.72*N0 and N > 0.6*N0)
return
def test1(self):
'mccomponents.sample.samplecomponent isotropic kernel, multiple-scattering'
import mcni
neutron = mcni.neutron(r=(0, 0, 0), v=(0, 0, 3000), time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent(
'Al', 'sampleassemblies/Al-isotropickernel/sampleassembly.xml')
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 1
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons, multiple_scattering=True)
N = len(neutrons)
for i in range(N):
neutron = neutrons[i]
print neutron
continue
return
def test1(self):
'mccomponents.sample.samplecomponent isotropic kernel, multiple-scattering'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-isotropickernel/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
N0 = 1
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons, multiple_scattering=True)
N = len(neutrons)
for i in range(N):
neutron = neutrons[i]
print neutron
continue
return
def test1(self):
'mccomponents.sample.samplecomponent: DGSSXResKernel'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-DGSSXResKernel/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,6), (0,0,0) )
N0 = 10
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
for i in range(10):
neutron = neutrons[i]
# print neutron
self.assert_(np.allclose(neutron.state.velocity, [3000, 0, 0], atol=20))
continue
return
def test(self):
"Source_simple --> E_monitor"
from mcstas2 import componentfactory
ssimplefac = componentfactory( 'sources', 'Source_simple' )
ssimple = ssimplefac(
'ssimple',
radius=0.1, dist=2, xw=0.1, yh=0.1, E0=55, dE=2)
from mcstas2.wrappers import wrap
wrap( 'E_monitor.comp', 'monitors' )
emonfac = componentfactory( 'monitors', 'E_monitor' )
emon = emonfac(
'emon',
nchan=20, filename="e.dat",
xmin=-0.2, xmax=0.2,
ymin=-0.2, ymax=0.2,
Emin=50, Emax=60)
import mcni
instrument = mcni.instrument( [ssimple, emon] )
geometer = mcni.geometer()
geometer.register( ssimple, (0,0,0), (0,0,0) )
geometer.register( emon, (0,0,1), (0,0,0) )
neutrons = mcni.neutron_buffer( 100 )
mcni.simulate( instrument, geometer, neutrons )
return
def test2(self):
"mccomponents.sample.samplecomponent: E_vQ_Kernel - discontinued dispersion surface"
import mcni
from mcni.utils import conversion
ei = 60
vil = conversion.e2v(ei)
vi = (0, 0, vil)
neutron = mcni.neutron(r=(0, 0, 0), v=vi, time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource("source", neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent("Al", "sampleassemblies/Al-E_vQ_withdiscontinuity-kernel/sampleassembly.xml")
E_Q = "np.where(Qx*Qx+Qy*Qy+Qz*Qz>30, 25, 15)" # in sampleassemblies/Al-E_vQ-kernel/Al-scatterer.xml
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 10000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
import numpy.linalg as nl
import numpy as np
from math import sin
N_noscatt = 0
for i in range(N):
neutron = neutrons[i]
vf = np.array(neutron.state.velocity)
diffv = vi - vf
# no scattering is fine
if np.linalg.norm(diffv) < 1e-12:
N_noscatt += 1
continue
Q = conversion.V2K * diffv
Qx, Qy, Qz = Q
ef = conversion.v2e(nl.norm(vf))
E = ei - ef
# print E, Q, neutron
E1 = eval(E_Q)
self.assertAlmostEqual(E, E1)
continue
print "\n* percentage of no scattering (Q happen to be at a singular point):", N_noscatt * 100.0 / N, "%"
return
def test(self):
component1 = Component("comp")
instrument = mcni.instrument([component1])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
neutrons = mcni.neutron_buffer(2)
mcni.simulate(instrument, geometer, neutrons, multiple_scattering=1)
return
def test(self):
component1 = Component('comp')
instrument = mcni.instrument( [component1] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
neutrons = mcni.neutron_buffer( 2 )
mcni.simulate( instrument, geometer, neutrons, multiple_scattering=1)
return
def test1(self):
'mccomponents.sample: ConstantQEKernel'
# momentum and energy transfer. defined in the scatterer xml file
Q0 = 3
E0 = 30
import mcni
from mcni.utils import conversion
ei = 60
vi = conversion.e2v(ei)
Vi = (0, 0, vi)
neutron = mcni.neutron(r=(0, 0, 0), v=Vi, time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent(
'Al', 'sampleassemblies/Al-constantqekernel/sampleassembly.xml')
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
import numpy.linalg as nl, numpy as np
for i in range(10):
neutron = neutrons[i]
Vf = np.array(neutron.state.velocity)
print Vf
ef = conversion.v2e(nl.norm(Vf))
E = ei - ef
dV = np.array(Vf) - np.array(Vi)
qasv = nl.norm(dV)
Q = conversion.v2k(qasv)
self.assertAlmostEqual(E, E0, 7)
self.assertAlmostEqual(Q, Q0, 7)
continue
return
def test1(self):
"mccomponents.sample.samplecomponent: E_vQ_Kernel"
import mcni
from mcni.utils import conversion
ei = 60
vil = conversion.e2v(ei)
vi = (0, 0, vil)
neutron = mcni.neutron(r=(0, 0, 0), v=vi, time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource("source", neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent("Al", "sampleassemblies/Al-E_vQ-kernel/sampleassembly.xml")
E_Q = "20 + 5 * sin(Qx+Qy+Qz)" # in sampleassemblies/Al-E_vQ-kernel/Al-scatterer.xml
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 10000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
import numpy.linalg as nl
import numpy as np
from math import sin
for i in range(N):
neutron = neutrons[i]
vf = np.array(neutron.state.velocity)
diffv = vi - vf
Q = conversion.V2K * diffv
Qx, Qy, Qz = Q
ef = conversion.v2e(nl.norm(vf))
E = ei - ef
# print E, Q, neutron
E1 = eval(E_Q)
self.assertAlmostEqual(E, E1)
continue
return
def test1(self):
'mccomponents.sample: ConstantvQEKernel'
# momentum and energy transfer. defined in the scatterer xml file
Q0 = 2,0,2
E0 = 28
import mcni
from mcni.utils import conversion
ei = 60
vi = conversion.e2v(ei)
Vi = (0,0,vi)
neutron = mcni.neutron( r = (0,0,0), v = Vi, time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-constantvqekernel/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
import numpy.linalg as nl, numpy as np
for i in range(10):
neutron = neutrons[i]
Vf = np.array(neutron.state.velocity)
# print Vf
ef = conversion.v2e(nl.norm(Vf))
E = ei-ef
dV = np.array(Vi) - np.array(Vf)
Q = dV * conversion.V2K
print E, Q, neutron.probability
self.assertAlmostEqual(E, E0, 1)
for i in range(3):
self.assertAlmostEqual(Q[i], Q0[i], 7)
continue
return
def test(self):
component1 = Source('source')
import mcni.mcnibp as c
component2 = c.DummyComponent('dummy2')
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,90) )
neutrons = mcni.neutron_buffer( 1 )
mcni.simulate( instrument, geometer, neutrons )
return
def test1(self):
from mcni.components.NeutronFromStorage import NeutronFromStorage
component1 = NeutronFromStorage('storage', neutron_storage_path)
component2 = Verifier('verifier', self)
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 0), (0, 0, 0))
neutrons = mcni.neutron_buffer(1)
mcni.simulate(instrument, geometer, neutrons)
return
def test1(self):
from mcni.components.NeutronFromStorage import NeutronFromStorage
component1 = NeutronFromStorage('storage', neutron_storage_path)
component2 = Verifier( 'verifier', self)
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,0), (0,0,0) )
neutrons = mcni.neutron_buffer( 1 )
mcni.simulate( instrument, geometer, neutrons )
return
def test2(self):
'storage --> verifier'
from mcni.components.NeutronFromStorage import NeutronFromStorage
component1 = NeutronFromStorage('storage', '%s-saved' % neutron_storage_path)
component2 = Verifier( 'verifier', self)
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,0), (0,0,0) )
neutrons = mcni.neutron_buffer( packetsize*(npackets+1) )
mcni.simulate( instrument, geometer, neutrons )
return
def test1(self):
'mccomponents.sample.samplecomponent: E_vQ_Kernel'
import mcni
from mcni.utils import conversion
ei = 60
vil = conversion.e2v(ei)
vi = (0, 0, vil)
neutron = mcni.neutron(r=(0, 0, 0), v=vi, time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent(
'Al', 'sampleassemblies/Al-E_vQ-kernel/sampleassembly.xml')
E_Q = '20 + 5 * sin(Qx+Qy+Qz)' # in sampleassemblies/Al-E_vQ-kernel/Al-scatterer.xml
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
import numpy.linalg as nl
import numpy as np
from math import sin
for i in range(N):
neutron = neutrons[i]
vf = np.array(neutron.state.velocity)
diffv = vi - vf
Q = conversion.V2K * diffv
Qx, Qy, Qz = Q
ef = conversion.v2e(nl.norm(vf))
E = ei - ef
# print E, Q, neutron
E1 = eval(E_Q)
self.assertAlmostEqual(E, E1)
continue
return
def test2(self):
'storage --> verifier'
from mcni.components.NeutronFromStorage import NeutronFromStorage
component1 = NeutronFromStorage('storage',
'%s-saved' % neutron_storage_path)
component2 = Verifier('verifier', self)
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 0), (0, 0, 0))
neutrons = mcni.neutron_buffer(packetsize * (npackets + 1))
mcni.simulate(instrument, geometer, neutrons)
return
def test(self):
if self.nompi: return
component1 = Source('source')
component2 = Printer('printer')
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 0), (0, 0, 0))
neutrons = mcni.neutron_buffer(2)
mcni.simulate(instrument, geometer, neutrons)
return
def test(self):
if self.nompi: return
component1 = Source('source')
component2 = Printer('printer')
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,0), (0,0,0) )
neutrons = mcni.neutron_buffer( 2 )
mcni.simulate( instrument, geometer, neutrons )
return
def test1(self):
'mccomponents.sample.samplecomponent: Broadened_E_Q_Kernel'
import mcni
from mcni.utils import conversion
ei = 600
vil = conversion.e2v(ei)
vi = (0, 0, vil)
neutron = mcni.neutron(r=(0, 0, 0), v=vi, time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent(
'Al',
'sampleassemblies/Al-broadened-E_Q-kernel/sampleassembly.xml')
E_Q = 'Q*Q/3.5' # in sampleassemblies/Al-broadened-E_Q-kernel/Al-scatterer.xml
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
import numpy.linalg as nl
import numpy as np
for i in range(10):
neutron = neutrons[i]
vf = np.array(neutron.state.velocity)
diffv = vi - vf
Q = conversion.v2k(nl.norm(diffv))
ef = conversion.v2e(nl.norm(vf))
E = ei - ef
E1 = eval(E_Q)
print E, Q, neutron, E - E1
continue
return
def test1(self):
'mccomponents.sample.samplecomponent: Broadened_E_Q_Kernel'
import mcni
from mcni.utils import conversion
ei = 600
vil = conversion.e2v(ei)
vi = (0,0,vil)
neutron = mcni.neutron(
r = (0,0,0), v = vi,
time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-broadened-E_Q-kernel/sampleassembly.xml' )
E_Q = 'Q*Q/3.5' # in sampleassemblies/Al-broadened-E_Q-kernel/Al-scatterer.xml
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
import numpy.linalg as nl
import numpy as np
for i in range(10):
neutron = neutrons[i]
vf = np.array(neutron.state.velocity)
diffv = vi - vf
Q = conversion.v2k(nl.norm(diffv))
ef = conversion.v2e(nl.norm(vf))
E = ei - ef
E1 = eval(E_Q)
print E, Q, neutron, E-E1
continue
return
def test1(self):
'mccomponents.sample: SimplePowderDiffractionKernel'
import mcni
from mcni.utils import conversion
from mcstas2 import componentfactory as cf
f = cf('sources', 'Source_simple')
component1 = f(
E0=60,
dE=20,
height=0.01,
width=0.01,
radius=0,
dist=4,
xw=0.1,
yh=0.1,
)
from mccomponents.sample import samplecomponent
import mccomponents.sample.diffraction.xml
component2 = samplecomponent(
'Al',
'sampleassemblies/Al-simplepowderdiffractionkernel/sampleassembly.xml'
)
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 5), (0, 0, 0))
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
print N
import numpy.linalg as nl, numpy as np
for i in range(10):
neutron = neutrons[i]
Vf = np.array(neutron.state.velocity)
print Vf
continue
return
def test1(self):
'neutron --> storage'
#from mcni.components.MonochromaticSource import MonochromaticSource
#component1 = MonochromaticSource('source', neutron)
component1 = Source( 'source' )
from mcni.components.NeutronToStorage import NeutronToStorage
component2 = NeutronToStorage( 'storage', neutron_storage_path)
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,90) )
neutrons = mcni.neutron_buffer( ntotneutrons )
mcni.simulate( instrument, geometer, neutrons )
return
def test1(self):
'neutron --> storage'
#from mcni.components.MonochromaticSource import MonochromaticSource
#component1 = MonochromaticSource('source', neutron)
component1 = Source('source')
from mcni.components.NeutronToStorage import NeutronToStorage
component2 = NeutronToStorage('storage', neutron_storage_path)
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 90))
neutrons = mcni.neutron_buffer(ntotneutrons)
mcni.simulate(instrument, geometer, neutrons)
return
def test1(self):
'detector component'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (1500,0,2000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.detector import detectorcomponent
component2 = detectorcomponent(
'detectorsystem', instrumentxml, coordinate_system, tofparams, outfilename )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,0), (0,0,0) )
neutrons = mcni.neutron_buffer( nevents )
mcni.simulate( instrument, geometer, neutrons )
return
def test1(self):
'mccomponents.sample.samplecomponent'
# energy transfer. defined in the scatterer xml file
E0 = 10
import mcni
from mcni.utils import conversion
ei = 60
vi = conversion.e2v(ei)
neutron = mcni.neutron(r=(0, 0, 0), v=(0, 0, vi), time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent(
'Al',
'sampleassemblies/Al-constantenergytransfer/sampleassembly.xml')
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 0))
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate(instrument, geometer, neutrons)
N = len(neutrons)
import numpy.linalg as nl
for i in range(10):
neutron = neutrons[i]
vf = nl.norm(neutron.state.velocity)
ef = conversion.v2e(vf)
E = ei - ef
self.assertAlmostEqual(E, E0, 7)
continue
return
def test1(self):
'detector component'
import mcni
neutron = mcni.neutron(r=(0, 0, 0), v=(1500, 0, 2000), time=0, prob=1)
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.detector import detectorcomponent
component2 = detectorcomponent('detectorsystem', instrumentxml,
coordinate_system, tofparams,
outfilename)
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 0), (0, 0, 0))
neutrons = mcni.neutron_buffer(nevents)
mcni.simulate(instrument, geometer, neutrons)
return
def _createInstrument(self):
neutron_components = self.neutron_components
for comp in neutron_components:
if comp not in self.sequence:
self._warning.log(
'component %s was not included in component sequence %s' %
(comp, self.sequence))
pass
continue
for name in self.sequence:
if name not in neutron_components:
raise RuntimeError , "Neutron component %s specified in sequence %s does not " \
"correspond to any known simulation components: %s" % (
name, self.sequence, neutron_components )
continue
import mcni
components = [neutron_components[name] for name in self.sequence]
instrument = mcni.instrument(components)
return instrument
def test1(self):
'mccomponents.sample.samplecomponent'
# energy transfer. defined in the scatterer xml file
E0 = 10
import mcni
from mcni.utils import conversion
ei = 60
vi = conversion.e2v(ei)
neutron = mcni.neutron( r = (0,0,0), v = (0,0,vi), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-constantenergytransfer/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
import numpy.linalg as nl
for i in range(10):
neutron = neutrons[i]
vf = nl.norm(neutron.state.velocity)
ef = conversion.v2e(vf)
E = ei-ef
self.assertAlmostEqual(E, E0, 7)
continue
return
def test(self):
component1 = Source('source')
component2 = Verifier('dummy2', self)
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,90) )
neutrons = mcni.neutron_buffer( 1 )
mcni.simulate( instrument, geometer, neutrons )
for i in range(len(neutrons)):
neutron = neutrons[i]
r = list( neutron.state.position )
v = list( neutron.state.velocity )
self.assertVectorAlmostEqual( r, (1,2,3) )
self.assertVectorAlmostEqual( v, (1,2,3) )
continue
return
def test(self):
component1 = Source("source")
component2 = Verifier("dummy2", self)
instrument = mcni.instrument([component1, component2])
geometer = mcni.geometer()
geometer.register(component1, (0, 0, 0), (0, 0, 0))
geometer.register(component2, (0, 0, 1), (0, 0, 90))
neutrons = mcni.neutron_buffer(1)
mcni.simulate(instrument, geometer, neutrons)
for i in range(len(neutrons)):
neutron = neutrons[i]
r = list(neutron.state.position)
v = list(neutron.state.velocity)
self.assertVectorAlmostEqual(r, (1, 2, 3))
self.assertVectorAlmostEqual(v, (1, 2, 3))
continue
return
def _createInstrument(self):
neutron_components = self.neutron_components
for comp in neutron_components:
if comp not in self.sequence:
self._warning.log(
'component %s was not included in component sequence %s' % (
comp, self.sequence )
)
pass
continue
for name in self.sequence:
if name not in neutron_components:
raise RuntimeError , "Neutron component %s specified in sequence %s does not " \
"correspond to any known simulation components: %s" % (
name, self.sequence, neutron_components )
continue
import mcni
components = [ neutron_components[ name ] for name in self.sequence ]
instrument = mcni.instrument( components )
return instrument
def test1(self):
'mccomponents.sample: SimplePowderDiffractionKernel'
import mcni
from mcni.utils import conversion
from mcstas2 import componentfactory as cf
f = cf('sources', 'Source_simple')
component1 = f(
E0=60, dE=20,
height = 0.01, width = 0.01, radius=0,
dist=4,
xw = 0.1, yh = 0.1,
)
from mccomponents.sample import samplecomponent
import mccomponents.sample.diffraction.xml
component2 = samplecomponent( 'Al', 'sampleassemblies/Al-simplepowderdiffractionkernel/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,5), (0,0,0) )
N0 = 1000
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
print N
import numpy.linalg as nl, numpy as np
for i in range(10):
neutron = neutrons[i]
Vf = np.array(neutron.state.velocity)
print Vf
continue
return
def test1(self):
'dgs sx res'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
xmlpath = os.path.join(
os.path.dirname(__file__),
"..", 'sample',
'sampleassemblies/Al-DGSSXResKernel/sampleassembly.xml'
)
component2 = samplecomponent( 'Al', xmlpath)
from mccomponents.components.DGSSXResPixel import DGSSXResPixel
component3 = DGSSXResPixel(
"pixel",
pressure=10*101325, tof=3e-3,
radius=0.0254/2, height=1./128)
instrument = mcni.instrument( [component1, component2, component3] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,6), (0,0,0) )
geometer.register( component3, (0,0,6), (0,0,0) )
N0 = 10
neutrons = mcni.neutron_buffer(N0)
mcni.simulate( instrument, geometer, neutrons )
N = len(neutrons)
for i in range(10):
neutron = neutrons[i]
print neutron
self.assert_(np.allclose(neutron.state.velocity, [3000, 0, 0], atol=20))
continue
return
def test(self):
"Source_simple --> E_monitor"
from mcstas2 import componentfactory
ssimplefac = componentfactory('sources', 'Source_simple')
ssimple = ssimplefac('ssimple',
radius=0.1,
dist=2,
xw=0.1,
yh=0.1,
E0=55,
dE=2)
from mcstas2.wrappers import wrap
wrap('E_monitor.comp', 'monitors')
emonfac = componentfactory('monitors', 'E_monitor')
emon = emonfac('emon',
nchan=20,
filename="e.dat",
xmin=-0.2,
xmax=0.2,
ymin=-0.2,
ymax=0.2,
Emin=50,
Emax=60)
import mcni
instrument = mcni.instrument([ssimple, emon])
geometer = mcni.geometer()
geometer.register(ssimple, (0, 0, 0), (0, 0, 0))
geometer.register(emon, (0, 0, 1), (0, 0, 0))
neutrons = mcni.neutron_buffer(100)
mcni.simulate(instrument, geometer, neutrons)
return
def test1(self):
'mccomponents.sample.samplecomponent'
import mcni
neutron = mcni.neutron( r = (0,0,0), v = (0,0,3000), time = 0, prob = 1 )
from mcni.components.MonochromaticSource import MonochromaticSource
component1 = MonochromaticSource('source', neutron)
from mccomponents.sample import samplecomponent
component2 = samplecomponent( 'Ni', 'sampleassemblies/Ni/sampleassembly.xml' )
instrument = mcni.instrument( [component1, component2] )
geometer = mcni.geometer()
geometer.register( component1, (0,0,0), (0,0,0) )
geometer.register( component2, (0,0,1), (0,0,0) )
neutrons = mcni.neutron_buffer( 1 )
mcni.simulate( instrument, geometer, neutrons )
for i in range(len(neutrons)):
neutron = neutrons[i]
print neutron
continue
return
def run(beam_neutrons_path, instrument, samplexmlpath, psi, hkl2Q, pixel, t_m2p,
Q, E, hkl_projection, Nbuffer=100000, Nrounds_beam=1):
"""Run mcvine simulation with using the resolution sample and the resolution pixel,
and save the results as numpy arrays
- beam_neutrons_path: path to the "neutrons" file of a beam simulation
- instrument: instrument object with geometry data such as L1 and L2
- samplexmlpath: path to the sampleassembly xml file
- psi: sample rotation angle
- hkl2Q: matrix to convert hkl to Q: Q = hkl dot hkl2Q
- pixel: pixel object with pixe, height, pressure. and position
- t_m2p: exepcted tof from moderator to pixel
- Q: expected Q
- E: expected E
- hkl_projection: the simulated data is projected to this axis and E axis for easy inspection
- Nbuffer: neutron buffer size
- Nrounds_beam: number of rounds replaying neutrons in the beam
"""
from mcni.components.NeutronFromStorage import NeutronFromStorage
source = NeutronFromStorage('source', path=beam_neutrons_path)
from mccomponents.sample import samplecomponent
sample = samplecomponent( 'sample', samplexmlpath)
# dummy component to save the state of scattered neutrons
from mcni.components.Dummy import Dummy
sample_location = Dummy('sample_location')
# det pixel
from mccomponents.components.DGSSXResPixel import DGSSXResPixel
pressure = mcvine.units.parse(pixel.pressure)/mcvine.units.parse("kg/m/s/s")
r = mcvine.units.parse(pixel.radius)/mcvine.units.meter
h = mcvine.units.parse(pixel.height)/mcvine.units.meter
pixel_comp = DGSSXResPixel(
"pixel",
pressure=pressure, tof=t_m2p,
radius=r, height=h)
# build instrument simulation chain
import mcni
sim_chain = mcni.instrument( [source, sample, sample_location, pixel_comp] )
# put components into place
geometer = mcni.geometer()
z_beam = mcvine.units.parse(instrument.offset_sample2beam)/mcvine.units.meter
# z along beam
geometer.register( source, (0,0,z_beam), (0,0,0) )
geometer.register( sample, (0,0,0), (0,psi*180/np.pi,0) )
geometer.register( sample_location, (0,0,0), (0,0,0) )
geometer.register( pixel_comp, pixel.position, pixel.orientation )
#
Q2hkl = np.linalg.inv(hkl2Q)
# lengh of hkl_projection squared
hkl_proj_len2 = np.dot(hkl_projection, hkl_projection)
# neutron buffer
from mcni.neutron_storage.idf_usenumpy import count
N0 = count(beam_neutrons_path) * Nrounds_beam
dxs_all = None; dEs_all = None; probs_all=None; dhkls_all=None
start = 0
for i in range(int(np.ceil(N0/Nbuffer))+1):
# for i in range(10):
end = start + Nbuffer
end = min(end, N0)
if end<=start:
continue
sys.stdout.write("%s-%s: " % (start, end-1)); sys.stdout.flush()
neutrons = mcni.neutron_buffer(end-start)
# simulate
tracer = NeutronTracer()
mcni.simulate( sim_chain, geometer, neutrons, tracer=tracer)
#
before_dummy_start, after_dummy_start, \
before_incident, after_incident, \
before_scattered, after_scattered, \
at_sample_location, at_sample_location2, \
before_detected, after_detected, \
before_dummy_end, after_dummy_end = tracer._store
incident = after_incident
# has to be `at_sample_location` because both sample_location and
# beam have no relative rotation.
# should not used after_scattered.
# it is in the sample's coordinate system, which is rotated by angle psi.
# should not use before_detected. It could be rotated in spherical case
scattered = at_sample_location
detected = after_detected
del (before_dummy_start, after_dummy_start,
before_incident, after_incident,
before_scattered, after_scattered,
before_detected, after_detected,
before_dummy_end, after_dummy_end)
is_scattered = incident.v != scattered.v
is_scattered = np.logical_or(
is_scattered[:,0],
np.logical_or(is_scattered[:,1], is_scattered[:,2])
)
good = np.logical_and(is_scattered, detected.p>np.finfo(float).eps)
vi = incident.v[good]
vf = scattered.v[good]
probs = p = detected.p[good]
from mcni.utils import conversion
Ei = conversion.VS2E * (vi*vi).sum(axis=-1)
Ef = conversion.VS2E * (vf*vf).sum(axis=-1)
Es = Ei - Ef
vQ = vi-vf
Qs = vQ * conversion.V2K
Qs = np.array([Qs[:, 2], Qs[:, 0], Qs[:, 1]]).T
# print Qs
# print Es
dQs = Qs - Q
dEs = Es - E
dhkls = np.dot(dQs, Q2hkl)
# print dhkls
# print dEs
# print p
dxs = np.dot( dhkls, np.array(hkl_projection) )/hkl_proj_len2
if dxs_all is None:
dxs_all = dxs
dEs_all = dEs
probs_all = probs
dhkls_all = dhkls
else:
dxs_all = np.concatenate((dxs_all, dxs))
dEs_all = np.concatenate((dEs_all, dEs))
probs_all = np.concatenate((probs_all, probs))
dhkls_all = np.concatenate((dhkls_all, dhkls))
print()
start = end
continue
# reverse x and E
# the negative sign here makes the result the PSF
dxs_all *= -1
dEs_all *= -1
dhkls_all *= -1
# save results
np.save("dhkls.npy", dhkls_all)
np.save("dxs.npy", dxs_all)
np.save("dEs.npy", dEs_all)
np.save("probs.npy", probs_all)
h, xedges, yedges = np.histogram2d(
dxs_all, dEs_all, bins=100, weights=probs_all)
import histogram as H, histogram.hdf as hh
xaxis = H.axis('x', boundaries=xedges)
Eaxis = H.axis('E', boundaries=yedges)
res = H.histogram('res', (xaxis, Eaxis), data=h)
hh.dump(res, 'res.h5')
sys.stdout.write("Done.\n"); sys.stdout.flush()
return
