Exemplo n.º 1
0
from vita.modules.equilibrium.fiesta import Fiesta
from vita.modules.projection.projection2D.field_line.field_line import FieldLine
from vita.modules.projection.projection2D.field_line.map_field_lines import map_field_lines
from vita.modules.utils.getOption import getOption

if __name__ == "__main__":
    #FILEPATH = '/home/jmbols/Postdoc/ST40/Programme 1/Equilibrium/eq001_limited.mat'
    #FILEPATH = '/media/jmbols/Data/jmbols/ST40/Programme 3/Equilibrium/eq_0002.mat'
    FILEPATH = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
   #HESEL_FILE_PATH = '/media/jmbols/Data/jmbols/ST40/Programme 1/n_inner_bnd_scan/ST40.00001.03.h5'
    #HESEL_FILE_PATH = '/media/jmbols/Data/jmbols/ST40/Programme 3/Te(i)_grad_scan/ST40.00003.20.h5'

    #FILE = h5py.File(HESEL_FILE_PATH, 'r')
    #HESEL_PARAMS = HESELparams(FILE)
    #FILE.close()
    FIESTA = Fiesta(FILEPATH)

    FIELD_LINE = FieldLine(FIESTA)
    MID_PLANE_LOC = FIESTA.get_midplane_lcfs()[1]

    X_AFTER_LCFS = np.linspace(0, 10, 100)*1e-3 + MID_PLANE_LOC

#    I_AFTER_LCFS = np.where(HESEL_PARAMS.xaxis >= 0)[0]
#    X_AFTER_LCFS = HESEL_PARAMS.xaxis[I_AFTER_LCFS] + MID_PLANE_LOC

    FIELD_LINES = map_field_lines(X_AFTER_LCFS, FIESTA)
#    save_as_pickle(FIELD_LINES, 'eq_0002')

    plt.plot(FIELD_LINE.fiesta_equil.r_limiter, FIELD_LINE.fiesta_equil.z_limiter)
    for I in X_AFTER_LCFS:
        plt.plot(FIELD_LINES[I]['R'], FIELD_LINES[I]['Z'])
Exemplo n.º 2
0
from vita.modules.equilibrium.fiesta import Fiesta
from vita.utility import get_resource


# the world scene-graph
world = World()

##########################
# add machine components #

config_file = get_resource("ST40-IVC1", "configuration", 'st40_ivc1_config')
load_wall_configuration(config_file, world)


eq002 = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
fiesta = Fiesta(eq002)
b_field = fiesta.b_field
lcfs = fiesta.get_midplane_lcfs()[1]


seed_points = [
    Point3D(0.75, 0, 0),
    Point3D(lcfs + 0.001, 0, 0),
    Point3D(lcfs + 0.01, 0, 0),
    Point3D(lcfs + 0.02, 0, -0.01)
]


field_tracer = FieldlineTracer(b_field, method=RK2(step_size=0.0001))

end_point, _, trajectory1 = field_tracer.trace(world, seed_points[0], save_trajectory=True, max_length=15)
Exemplo n.º 3
0
    fx = np.array([divertor_map[i]["f_x"] for i in x_axis])

    power = x_axis * footprint._q / (r_div * (fx / np.cos(angles)))

    return [r_div, z_div, power]


##########################
# add machine components #

config_file = get_resource("ST40-IVC1", "configuration", 'st40_ivc1_config')

########################
# load the equilibrium #
eq = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
fiesta = Fiesta(eq)

##############################
# setup the heatflux profile #

# specify and load heatflux profile
lcfs = fiesta.get_midplane_lcfs(psi_p=1.00001)[1]
footprint = Eich(1.0e-3, 0.0001e-3, r0_lfs=lcfs)  # lambda_q=2.5, S=0.5

x = np.linspace(-1, 10, 100) * 1e-3
footprint.set_coordinates(x)
footprint.calculate_heat_flux_density("lfs")

POINT_A = Point2D(0.345941, -0.593439)
POINT_B = Point2D(0.51091, -0.757166)
power_profile = sample_power_at_surface(POINT_A, POINT_B, fiesta, footprint)
Exemplo n.º 4
0
# -*- coding: utf-8 -*-
"""
Created on Sun Oct 20 18:28:22 2019

@author: Daniel.Ibanez
"""
import numpy as np
from matplotlib import pyplot as plt

from vita.modules.equilibrium.fiesta import Fiesta
from vita.modules.projection.projection2D.field_line.field_line import FieldLine
from vita.utility import get_resource
from vita.modules.utils.getOption import getOption

R200 = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
FIESTA = Fiesta(R200)
field_line =  FieldLine(FIESTA)

R = FIESTA.get_midplane_lcfs()[1]
r0 = 0.45
rf = R+0.01
midplane_range = np.linspace(r0,rf,3)
points = []
lengths = []
for r in midplane_range:
    points.append( [r,0,0] )
    lengths.append( 60 - (r-r0)*120 )
print(lengths)
field_line_dict = []
for idx, val in enumerate(points):
    field_line_dict.append(field_line.follow_field_in_plane(val, lengths[idx], break_at_limiter=False) )
Exemplo n.º 5
0
Created on Sun Oct 20 18:28:22 2019

@author: Daniel.Ibanez
"""
import numpy as np
from matplotlib import pyplot as plt
import math

from vita.modules.projection.projection2D.field_line.field_line import FieldLine
from vita.modules.equilibrium.fiesta import Fiesta
from vita.modules.utils import intersection
from vita.utility import get_resource
from vita.modules.utils.getOption import getOption

R200 = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
FIESTA = Fiesta(R200)
field_line = FieldLine(FIESTA)
R = field_line.fiesta_equil.get_midplane_lcfs()[1]
r0 = R + 0.001
rf = R + 0.012
midplane_range = np.linspace(r0, rf, 3)
points = []
lengths = []
for r in midplane_range:
    points.append([r, 0, 0])
    lengths.append(60 - (r - r0) * 120)
print(lengths)
field_line_dict = []
for idx, val in enumerate(points):
    field_line_dict.append(
        field_line.follow_field_in_plane(val,
Exemplo n.º 6
0
from vita.modules.equilibrium.fiesta import Fiesta
from vita.utility import get_resource

# the world scene-graph
world = World()

##########################
# add machine components #

config_file = get_resource("ST40-IVC1", "configuration", 'st40_ivc1_config')
load_wall_configuration(config_file, world)

########################
# load the equilibrium #
eq007 = get_resource("ST40-IVC1", "equilibrium", "eq_006_3T_export")
fiesta = Fiesta(eq007)
b_field = fiesta.b_field
field_tracer = FieldlineTracer(b_field, method=RK2(step_size=0.0001))
equilibrium = fiesta.to_cherab_equilibrium()
psin2d = equilibrium.psi_normalised

##############################
# setup the heatflux profile #

# specify and load heatflux profile
# footprint = Eich(3, 0.0001)  # lambda_q=2.5, S=0.5
#
# x = np.linspace(-1, 10, 100)
# footprint.set_coordinates(x)
# footprint.s_disconnected_dn_max = 2.1
# footprint.fx_in_out = 5.
Exemplo n.º 7
0
# the world scene-graph
world = World()


##########################
# add machine components #

config_file = get_resource("ST40-IVC1", "configuration", 'st40_ivc1_config')
load_wall_configuration(config_file, world)


########################
# load the equilibrium #
eq007 = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
fiesta = Fiesta(eq007)
b_field = fiesta.b_field
field_tracer = FieldlineTracer(b_field, method=RK2(step_size=0.0001))
equilibrium = fiesta.to_cherab_equilibrium()
psin2d = equilibrium.psi_normalised


##############################
# setup the heatflux profile #

# specify and load heatflux profile
footprint = Eich(2.5E-3, 0.0001E-3)  # lambda_q=2.5, S=0.5

x = np.linspace(-1, 10, 100)*1E-3
footprint.set_coordinates(x)
footprint.s_disconnected_dn_max = 2.1
Exemplo n.º 8
0
import numpy as np
from mayavi import mlab
from raysect.core import Point3D, World
from raysect.primitive import import_obj
from vita.modules.projection.cherab import FieldlineTracer, RK2
from vita.modules.equilibrium.fiesta import Fiesta
from vita.utility import get_resource

# the world scene-graph
world = World()
ST40_mesh = get_resource("ST40", "mesh", "ST40_IVC")
import_obj(ST40_mesh, scaling=0.001, parent=world)

eq001 = get_resource("ST40", "equilibrium", "limited_eq001_export")
fiesta = Fiesta(eq001)
b_field = fiesta.b_field

seed_points = []

n = 20
for i in range(n):
    lcfs = 0.72677891
    seed_points.append(Point3D(lcfs + i * 0.001, 0.0, 0.0 + 0.02))

    #Point3D(0.7270, 0, 0),
    #Point3D(0.7275, 0, 0),
    #Point3D(0.7280, 0, 0)]

field_tracer = FieldlineTracer(b_field, method=RK2(step_size=0.00005))

end_points = []
Exemplo n.º 9
0
Created on Sun Oct 20 18:28:22 2019

@author: Daniel.Ibanez
"""
import numpy as np
from matplotlib import pyplot as plt
import math

from vita.modules.projection.projection2D.field_line.field_line import FieldLine
from vita.modules.equilibrium.fiesta import Fiesta
from vita.modules.utils import intersection
from vita.utility import get_resource
from vita.modules.utils.getOption import getOption

EQUIL = get_resource("ST40-IVC1", "equilibrium", "eq_006_2T_export")
FIESTA = Fiesta(EQUIL)
field_line = FieldLine(FIESTA)
R = field_line.fiesta_equil.get_midplane_lcfs()[1]
r0 = R + 0.001
rf = R + 0.012
midplane_range = np.linspace(r0, rf, 3)
points = []
lengths = []
for r in midplane_range:
    points.append([r, 0, 0])
    lengths.append(60 - (r - r0) * 120)
print(lengths)
field_line_dict = []
for idx, val in enumerate(points):
    field_line_dict.append(
        field_line.follow_field_in_plane(val,