How to use the openpnm.network function in openpnm

To help you get started, we’ve selected a few openpnm examples, based on popular ways it is used in public projects.

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PMEAL / porespy / test / unit / test_io.py View on Github

def test_openpnm_to_im(self):
        net = op.network.Cubic(shape=[5, 5, 5])
        geom = op.geometry.StickAndBall(network=net,
                                        pores=net.Ps, throats=net.Ts)
        geom.add_model(propname="pore.volume",
                       model=op.models.geometry.pore_volume.cube)
        geom.add_model(propname="throat.volume",
                       model=op.models.geometry.throat_volume.cylinder)
        geom.regenerate_models()

        im = ps.io.openpnm_to_im(network=net, pore_shape="cube",
                                 throat_shape="cylinder", rtol=0.01)
        porosity_actual = im.astype(bool).sum() / np.prod(im.shape)

        volume_void = net["pore.volume"].sum() + net["throat.volume"].sum()
        volume_total = np.prod(net.spacing * net.shape)
        porosity_desired = volume_void / volume_total

PMEAL / OpenPNM / tests / integration / test_multiple_geoms.py View on Github

import openpnm as op

pn = op.network.Cubic(shape=[10, 10, 40], spacing=1)

# Generate Ps as boolean mask
Ps = pn['pore.coords'][:, 2] &lt;= 20
Ts = pn.find_neighbor_throats(pores=Ps, mode='intersection', flatten=True)
geom1 = op.geometry.GenericGeometry(network=pn, pores=Ps, throats=Ts)

# Convert Ps to indices
Ps = pn.toindices(pn['pore.coords'][:, 2] &gt; 20)
Ts = pn.find_neighbor_throats(pores=Ps, mode='union')
geom2 = op.geometry.GenericGeometry(network=pn, pores=Ps, throats=Ts)

water = op.phases.Water(network=pn)

phys1 = op.physics.GenericPhysics(network=pn, phase=water, geometry=geom1)
phys1.add_model(propname='pore.test',
                model=op.models.geometry.pore_misc.constant,

PMEAL / OpenPNM / scripts / example_mass_partitioning.py View on Github

r"""
Example: How to use OpenPNNM to simulating multiphase Fickian diffusion

    1D network, the first half of the network is occupied by air and the next
    half by water. A partition coefficient of 0.5 is assumed, meaning that the
    concentration of the diffusing species in water "at the interface" is half
    of that in air.

"""
import openpnm as op
import matplotlib.pyplot as plt
import numpy as np
np.random.seed(10)

# Define network and geometry
net = op.network.Cubic(shape=[10, 1, 1])
geom = op.geometry.StickAndBall(network=net)

# Define constituent phases
air = op.phases.Air(network=net, name="air")
water = op.phases.Water(network=net, name="water")
water["pore.diffusivity"] = air["pore.diffusivity"] * 0.2

# Define MultiPhase object
mphase = op.phases.MultiPhase(network=net, phases=[air, water])
mphase._set_automatic_throat_occupancy()
mphase.set_occupancy(phase=air, pores=[0, 1, 2, 3, 4])
mphase.set_occupancy(phase=water, pores=[5, 6, 7, 8, 9])
const = op.models.misc.constant
mphase.set_binary_partition_coef(propname="throat.partition_coef",
                                 phases=[water, air], model=const, value=0.5)

PMEAL / OpenPNM / example_transient_Fickian_diffusion.py View on Github

import openpnm as op
import numpy as np

# work space and project
ws = op.Workspace()
ws.settings["loglevel"] = 30
proj = ws.new_project()

# network
np.random.seed(7)
net = op.network.Cubic(shape=[51, 19, 1], spacing=1e-4, project=proj)

# geometry
geo = op.geometry.StickAndBall(network=net, pores=net.Ps, throats=net.Ts)

# phase
phase = op.phases.Water(network=net)

# physics
phys = op.physics.GenericPhysics(network=net, phase=phase, geometry=geo)
phase['pore.diffusivity'] = 2e-09
phase['throat.diffusivity'] = 2e-09

mod = op.models.physics.diffusive_conductance.ordinary_diffusion
phys.add_model(propname='throat.diffusive_conductance',
               model=mod, regen_mode='normal')

PMEAL / OpenPNM / example_transientPNP.py View on Github

import openpnm as op
from openpnm.phases import mixtures
import numpy as np
ws = op.Workspace()
proj = ws.new_project()
# ws.settings['loglevel'] = 20


# network, geometry, phase
np.random.seed(0)

net = op.network.Cubic(shape=[8, 8, 1], spacing=9e-4, project=proj)
prs = (net['pore.back'] * net['pore.right'] + net['pore.back'] *
       net['pore.left'] + net['pore.front'] * net['pore.right'] +
       net['pore.front'] * net['pore.left'])
thrts = net['throat.surface']
op.topotools.trim(network=net, pores=net.Ps[prs], throats=net.Ts[thrts])


geo = op.geometry.StickAndBall(network=net, pores=net.Ps, throats=net.Ts)
pore_d = op.models.misc.constant
throat_d = op.models.misc.constant
geo.add_model(propname='pore.diameter', model=pore_d, value=1.5e-4)
geo.add_model(propname='throat.diameter', model=throat_d, value=1e-4)
geo.regenerate_models()

sw = mixtures.SalineWater(network=net)
# Retrieve handles to each species for use below

PMEAL / porespy / porespy / networks / __getnet__.py View on Github

net['throat.diameter'] = sp.array(t_dia_inscribed)*voxel_size
    net['throat.inscribed_diameter'] = sp.array(t_dia_inscribed)*voxel_size
    net['throat.area'] = sp.array(t_area)*(voxel_size**2)
    net['throat.perimeter'] = sp.array(t_perimeter)*voxel_size
    net['throat.equivalent_diameter'] = (sp.array(t_area) * (voxel_size**2))**0.5
    P12 = net['throat.conns']
    PT1 = sp.sqrt(sp.sum(((p_coords[P12[:, 0]]-t_coords) * voxel_size)**2, axis=1))
    PT2 = sp.sqrt(sp.sum(((p_coords[P12[:, 1]]-t_coords) * voxel_size)**2, axis=1))
    net['throat.total_length'] = PT1 + PT2
    PT1 = PT1-p_dia_local[P12[:, 0]]/2*voxel_size
    PT2 = PT2-p_dia_local[P12[:, 1]]/2*voxel_size
    net['throat.length'] = PT1 + PT2
    dist = (p_coords[P12[:, 0]]-p_coords[P12[:, 1]])*voxel_size
    net['throat.direct_length'] = sp.sqrt(sp.sum(dist**2, axis=1))
    # Make a dummy openpnm network to get the conduit lengths
    pn = op.network.GenericNetwork()
    pn.update(net)
    pn.add_model(propname='throat.endpoints',
                 model=op_gm.throat_endpoints.spherical_pores,
                 pore_diameter='pore.inscribed_diameter',
                 throat_diameter='throat.inscribed_diameter')
    pn.add_model(propname='throat.conduit_lengths',
                 model=op_gm.throat_length.conduit_lengths)
    pn.add_model(propname='pore.area',
                 model=op_gm.pore_area.sphere)
    net['throat.endpoints.head'] = pn['throat.endpoints.head']
    net['throat.endpoints.tail'] = pn['throat.endpoints.tail']
    net['throat.conduit_lengths.pore1'] = pn['throat.conduit_lengths.pore1']
    net['throat.conduit_lengths.pore2'] = pn['throat.conduit_lengths.pore2']
    net['throat.conduit_lengths.throat'] = pn['throat.conduit_lengths.throat']
    net['pore.area'] = pn['pore.area']
    prj = pn.project

PMEAL / OpenPNM / example_script.py View on Github

import openpnm as op
ws = op.Workspace()
proj = ws.new_project()

pn = op.network.Cubic(shape=[10, 10, 10], spacing=1e-4, project=proj)
geo = op.geometry.StickAndBall(network=pn, pores=pn.Ps, throats=pn.Ts)
air = op.phases.Air(network=pn, name='air')
water = op.phases.Water(network=pn, name='h2o')
hg = op.phases.Mercury(network=pn, name='hg')
phys_air = op.physics.Standard(network=pn, phase=air, geometry=geo)
phys_water = op.physics.Standard(network=pn, phase=water, geometry=geo)
phys_hg = op.physics.Standard(network=pn, phase=hg, geometry=geo)

mip = op.algorithms.Porosimetry(network=pn)
mip.setup(phase=hg)
mip.set_inlets(pores=pn.pores(['top', 'bottom']))
mip.run()
hg.update(mip.results(Pc=70000))
# mip.plot_intrusion_curve()

perm = op.algorithms.StokesFlow(network=pn)

PMEAL / OpenPNM / openpnm / utils / Project.py View on Github

def _new_object(self, objtype, name=None):
        r"""
        """
        if objtype.startswith('net'):
            obj = openpnm.network.GenericNetwork(project=self, name=name)
        elif objtype.startswith('geo'):
            obj = openpnm.geometry.GenericGeometry(project=self, name=name,
                                                   pores=[], throats=[])
        elif objtype.startswith('pha'):
            obj = openpnm.phases.GenericPhase(project=self, name=name)
        elif objtype.startswith('phy'):
            obj = openpnm.physics.GenericPhysics(project=self, name=name)
        elif objtype.startswith('alg'):
            obj = openpnm.algorithm.GenericAlgorithm(project=self, name=name)
        else:
            obj = openpnm.core.Base(project=self, name=name)
        return obj

PMEAL / OpenPNM / example_NP.py View on Github

import openpnm as op
import numpy as np
ws = op.Workspace()
proj = ws.new_project()
# ws.settings['loglevel'] = 20


# network, geometry, phase
np.random.seed(0)
net = op.network.Cubic(shape=[33, 33, 1], spacing=1e-5)
geo = op.geometry.StickAndBall(network=net, pores=net.Ps, throats=net.Ts)
sw = op.phases.Mixtures.SalineWater(network=net)

# physics
phys = op.physics.GenericPhysics(network=net, phase=sw, geometry=geo)

flow = op.models.physics.hydraulic_conductance.hagen_poiseuille
phys.add_model(propname='throat.hydraulic_conductance.solvent',
               pore_viscosity='pore.viscosity.solvent',
               throat_viscosity='throat.viscosity.solvent',
               model=flow, regen_mode='normal')
phys.regenerate_models()

current = op.models.physics.ionic_conductance.ordinary
phys.add_model(propname='throat.electrical_conductance.solvent',
               model=current, regen_mode='normal')

PMEAL / OpenPNM / scripts / example_Knudsen.py View on Github

import openpnm as op
import numpy as np
import matplotlib.pyplot as plt


# Get Deff w/o including Knudsen effect
spacing = 1.0
net = op.network.Cubic(shape=[10, 10, 10], spacing=spacing)
geom = op.geometry.StickAndBall(network=net)
air = op.phases.Air(network=net)
phys = op.physics.Standard(network=net, geometry=geom, phase=air)
odiff = op.models.physics.diffusive_conductance.ordinary_diffusion
phys.add_model(propname="throat.diffusive_conductance", model=odiff)
fd = op.algorithms.FickianDiffusion(network=net, phase=air)
fd.set_value_BC(pores=net.pores("left"), values=1.0)
fd.set_value_BC(pores=net.pores("right"), values=0.0)
fd.run()
L = (net.shape * net.spacing)[1]
A = (net.shape * net.spacing)[[0, 2]].prod()
Mdot = fd.rate(pores=net.pores("left")).squeeze()
Deff0 =  Mdot * L / A

# Get Deff w/ including Knudsen effect
mdiff = op.models.physics.diffusive_conductance.mixed_diffusion

How to use the openpnm.network function in openpnm

To help you get started, we’ve selected a few openpnm examples, based on popular ways it is used in public projects.

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