Exemple #1
0
def main():
    set_diagnostics_on(False)

    #define model geometry and indices
    perfusion_indices()

    #Read in geometry files
    define_node_geometry(get_default_geometry_path('Small.ipnode'))
    define_1d_elements(get_default_geometry_path('Small.ipelem'))
    append_units()

    #define radius by Strahler order
    s_ratio=1.5
    inlet_rad=12.0
    order_system = 'strahler'
    order_options = 'all'
    name = 'inlet'
    define_rad_from_geom(order_system, s_ratio, name, inlet_rad, order_options,'')

    #Call solve
    evaluate_prq()

    #export geometry
    group_name = 'perf_model'
    export_1d_elem_geometry(get_default_output_path('small.exnode'), group_name)
    export_node_geometry(get_default_output_path('small.exelem'), group_name)

    # export element field for radius
    field_name = 'radius_perf'
    ne_radius = get_ne_radius()
    export_1d_elem_field(ne_radius, get_default_output_path('radius_perf.exelem'), name, field_name)
def main():
    set_diagnostics_on(False)

    # Read settings
    ventilation_indices()

    define_node_geometry(get_default_geometry_path('SmallTree.ipnode'))
    define_1d_elements(get_default_geometry_path('SmallTree.ipelem'))
    define_rad_from_file(get_default_geometry_path('SmallTree.ipfiel'))
    append_units()

    # Set the working directory to the this files directory and then reset after running simulation.
    file_location = os.path.dirname(os.path.abspath(__file__))
    cur_dir = os.getcwd()
    os.chdir(file_location)

    # Run simulation.
    evaluate_vent()

    # Set the working directory back to it's original location.
    os.chdir(cur_dir)

    # Output results
    # Export airway nodes and elements
    group_name = 'vent_model'
    export_1d_elem_geometry(
        get_default_output_path('Output/Ventilation/small_tree.exelem'),
        group_name)
    export_node_geometry(
        get_default_output_path('Output/Ventilation/small_tree.exnode'),
        group_name)

    # Export flow element
    field_name = 'flow'
    export_elem_field(
        get_default_output_path(
            'Output/Ventilation/ventilation_fields.exelem'), group_name,
        field_name)

    # Export element field for radius
    ne_radius = get_ne_radius()
    field_name = 'radius'
    export_1d_elem_field(
        ne_radius,
        get_default_output_path(
            'Output/Ventilation/ventilation_radius_field.exelem'), group_name,
        field_name)

    # Export terminal solution
    export_terminal_solution(
        get_default_output_path('Output/Ventilation/terminal.exnode'),
        group_name)
def main():
    set_diagnostics_on(False)

    #define model geometry and indices
    perfusion_indices()

    #Read in geometry files
    define_node_geometry(get_default_geometry_path('Small.ipnode'))
    define_1d_elements(get_default_geometry_path('Small.ipelem'))
    append_units()

    #define radius by Strahler order
    s_ratio=1.5
    inlet_rad=12.0
    order_system = 'strahler'
    order_options = 'all'
    name = 'inlet'
    define_rad_from_geom(order_system, s_ratio, name, inlet_rad, order_options,'')

    #Call solve
    evaluate_prq()

    #export geometry
    group_name = 'perf_model'
    export_1d_elem_geometry(get_default_output_path('Output/Perfusion/small.exnode'), group_name)
    export_node_geometry(get_default_output_path('Output/Perfusion/small.exelem'), group_name)

    # export element field for radius
    field_name = 'radius_perf'
    ne_radius = get_ne_radius()
    export_1d_elem_field(ne_radius, get_default_output_path('Output/Perfusion/radius_perf.exelem'), name, field_name)

    # export element field for flow
    field_name = 'flow_perf'
    export_1d_elem_field(7, get_default_output_path('Output/Perfusion/flow_perf.exelem'), name, field_name)

    # export node field for pressure
    field_name = 'pressure_perf'
    export_node_field(1,get_default_output_path('Output/Perfusion/pressure_perf.exnode'), name, field_name)

    # export terminal solution
    export_terminal_perfusion(get_default_output_path('Output/Perfusion/terminals.exnode'), 'terminal_q')
def main():
    set_diagnostics_on(False)

    # Read settings
    ventilation_indices()

    define_node_geometry(get_default_geometry_path('SmallTree.ipnode'))
    define_1d_elements(get_default_geometry_path('SmallTree.ipelem'))
    define_rad_from_file(get_default_geometry_path('SmallTree.ipfiel'))
    append_units()

    # Set the working directory to the this files directory and then reset after running simulation.
    file_location = os.path.dirname(os.path.abspath(__file__))
    cur_dir = os.getcwd()
    os.chdir(file_location)

    # Run simulation.
    evaluate_vent()

    # Set the working directory back to it's original location.
    os.chdir(cur_dir)

    # Output results
    # Export airway nodes and elements
    group_name = 'vent_model'
    export_1d_elem_geometry(get_default_output_path('Output/Ventilation/small_tree.exelem'), group_name)
    export_node_geometry(get_default_output_path('Output/Ventilation/small_tree.exnode'), group_name)

    # Export flow element
    field_name = 'flow'
    export_elem_field(get_default_output_path('Output/Ventilation/ventilation_fields.exelem'), group_name, field_name)

    # Export element field for radius
    ne_radius = get_ne_radius()
    field_name = 'radius'
    export_1d_elem_field(ne_radius, get_default_output_path('Output/Ventilation/ventilation_radius_field.exelem'), group_name, field_name)

    # Export terminal solution
    export_terminal_solution(get_default_output_path('Output/Ventilation/terminal.exnode'), group_name)
Exemple #5
0
import sys
import os
from PySide import QtGui
from src.view import View
from src.scene import Scene

from aether.diagnostics import set_diagnostics_on
from aether.indices import define_problem_type
from aether.geometry import *
from aether.exports import *
from aether.growtree import grow_tree

set_diagnostics_on(False)
define_problem_type('grow_tree')


def loadAirway(ipnode, ipelem):
    exnode = os.path.splitext(ipnode)[0] + '.exnode'
    exelem = os.path.splitext(ipelem)[0] + '.exelem'

    define_node_geometry(ipnode)
    define_1d_elements(ipelem)
    export_node_geometry(exnode, 'airway')
    export_1d_elem_geometry(exelem, 'airway')

    airwayModel.load(exnode, exelem)


def loadSurface(ipnode, ipelem):
    node = os.path.splitext(ipnode)[0]
    elem = os.path.splitext(ipelem)[0]
Exemple #6
0
def main():
    set_diagnostics_on(False)
    patientid = 'lung005'
    protocal = 'baseline_cropped/GTV'

    density_tag = raw_input('Do you want to read density file? [yes/no]')
    constriction_tag = raw_input(
        'Do you want to constrict the airways? [yes/no]')
    densitytag = False
    constrictiontag = False
    if density_tag.lower() == "yes":
        densitytag = True
    else:
        densitytag = False
    if constriction_tag.lower() == "yes":
        constrictiontag = True
    else:
        constrictiontag = False

    # Read settings
    ventilation_indices()

    define_node_geometry(
        get_default_geometry_path('AirwayTree_VF.ipnode', patientid, protocal))
    define_1d_elements(
        get_default_geometry_path('AirwayTree_VF.ipelem', patientid, protocal))
    #define_rad_from_geom('horsfield', 1.16, 'inlet', 6.7)
    define_rad_from_file(
        get_default_geometry_path('AirwayTree_VF.ipfiel', patientid, protocal))
    append_units()
    if densitytag == True:
        #read density file
        cc_dir = get_default_output_path('unit_cc.txt', patientid, protocal)
        get_terminal_density_from_file(
            get_default_geometry_path(
                'AirwayTree_VF_node_with_density_GTV.txt', patientid,
                protocal), cc_dir)
        # v_dir = solve_volume_from_cc(cc_dir)
        # set_volume_fromrv(v_dir)
    if constrictiontag == True:
        constriction_dir = get_default_geometry_path('ElemToClose.txt',
                                                     patientid, protocal)
        set_constriction_from_file(constriction_dir)

    # Set the working directory to the this files directory and then reset after running simulation.
    file_location = os.path.dirname(os.path.abspath(__file__))
    cur_dir = os.getcwd()
    os.chdir(file_location)
    #print(file_location)

    # Run simulation.
    evaluate_vent()

    # Set the working directory back to it's original location.
    os.chdir(cur_dir)

    # Output results
    # Export airway nodes and elements
    group_name = 'vent_model'
    export_1d_elem_geometry(
        get_default_output_path('AirwayTree_VF.exelem', patientid, protocal),
        group_name)
    export_node_geometry(
        get_default_output_path('AirwayTree_VF.exnode', patientid, protocal),
        group_name)

    # Export flow element
    field_name = 'flow'
    export_elem_field(
        get_default_output_path('ventilation_fields.exelem', patientid,
                                protocal), group_name, field_name)

    # Export element field for radius
    ne_radius = get_ne_radius()
    field_name = 'radius'
    export_1d_elem_field(
        ne_radius,
        get_default_output_path('ventilation_radius_field.exelem', patientid,
                                protocal), group_name, field_name)

    # Export terminal solution
    export_terminal_solution(
        get_default_output_path('terminal.exnode', patientid, protocal),
        group_name)

    # Export bin results
    export_bin_results(
        get_default_output_path('bin_results.txt', patientid, protocal), 20)