예제 #1
0
import numpy as np
import matplotlib.pyplot as plt
from mayavi import mlab
from raysect.core import World, Point3D, Vector3D
from cherab.core.math import ConstantVector3D

from vita.modules.cherab import FieldlineTracer, Euler

# the world scene-graph
world = World()

b_field = ConstantVector3D(Vector3D(0, 1.5, 0))

field_tracer = FieldlineTracer(b_field, method=Euler(step_size=0.001))

start_point = Point3D(0, 0, 0)
end_point, trajectory = field_tracer.trace(world,
                                           start_point,
                                           save_trajectory=True,
                                           max_steps=1000)

num_segments = len(trajectory)
x = np.zeros(num_segments)
y = np.zeros(num_segments)
z = np.zeros(num_segments)
for ith_position, position in enumerate(trajectory):
    x[ith_position] = position.x
    y[ith_position] = position.y
    z[ith_position] = position.z

mlab.plot3d(x, y, z, tube_radius=0.0005, color=(1, 0, 0))
예제 #2
0
                                            "centre_column_tiles_upper_45")
centre_column_tiles_upper_45 = import_ply(centre_column_tiles_upper_45,
                                          scaling=0.001,
                                          name="centre_column_tiles_upper_45")
meshes["centre_column_tiles_upper_45"] = centre_column_tiles_upper_45
for i in range(8):
    centre_column_tiles_upper_45.instance(parent=world,
                                          transform=rotate_z(i * 45),
                                          name="centre_column_tiles_upper_45")

########################
# load the equilibrium #
eq002 = get_resource("ST40", "equilibrium", "eq002")
fiesta = Fiesta(eq002)
b_field = fiesta.b_field
field_tracer = FieldlineTracer(b_field, method=RK2(step_size=0.0001))


def get_lcfs_radius():

    equilibrium = fiesta.to_cherab_equilibrium()
    psin2d = equilibrium.psi_normalised

    def psin(r, offset=0):
        return psin2d(r, 0) - 1 + offset

    r_lcfs = brentq(psin, 0.7, 0.9, args=(0, ))

    return r_lcfs

예제 #3
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(1, 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.
footprint.calculate_heat_flux_density("lfs")
예제 #4
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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.
# footprint.calculate_heat_flux_density("lfs")
예제 #5
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config_file = get_resource("ST40-IVC2", "configuration", 'st40_ivc2_config')
load_wall_configuration(config_file, world)

eq002 = get_resource("ST40", "equilibrium", "eq002")
fiesta = Fiesta(eq002)
b_field = fiesta.b_field

seed_points = [
    Point3D(0.507, 0, 0),
    Point3D(0.6, 0, 0),
    Point3D(0.7, 0, 0),
    Point3D(0.733, 0, -0.01)
]

field_tracer = FieldlineTracer(b_field, method=RK4(step_size=0.0001))

end_point, _, trajectory1 = field_tracer.trace(world,
                                               seed_points[0],
                                               save_trajectory=True,
                                               max_length=3)
end_point, _, trajectory2 = field_tracer.trace(world,
                                               seed_points[1],
                                               save_trajectory=True,
                                               max_length=5)
end_point, _, trajectory3 = field_tracer.trace(world,
                                               seed_points[2],
                                               save_trajectory=True,
                                               max_length=15)
end_point, _, trajectory4 = field_tracer.trace(world,
                                               seed_points[3],
예제 #6
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centre_column_tiles_upper_45 = import_ply(centre_column_tiles_upper_45,
                                          scaling=0.001,
                                          name="centre_column_tiles_upper_45")
for i in range(8):
    centre_column_tiles_upper_45.instance(parent=world,
                                          transform=rotate_z(i * 45),
                                          name="centre_column_tiles_upper_45")

eq002 = get_resource("ST40", "equilibrium", "eq002")
fiesta = Fiesta(eq002)
b_field = fiesta.b_field

1.08333333
seed_point = Point3D(0.733, 0, -0.01)

field_tracer_rk2 = FieldlineTracer(b_field, method=RK2(step_size=0.0001))
field_tracer_rk4 = FieldlineTracer(b_field, method=RK4(step_size=0.0001))

_, _, trajectory_rk2 = field_tracer_rk2.trace(world,
                                              seed_point,
                                              save_trajectory=True,
                                              max_length=15)
_, _, trajectory_rk4 = field_tracer_rk4.trace(world,
                                              seed_point,
                                              save_trajectory=True,
                                              max_length=15)

rk2_radial_trajectory = np.zeros((trajectory_rk2.shape[0], 2))
for i in range(trajectory_rk2.shape[0]):
    r = np.sqrt(trajectory_rk2[i, 0]**2 + trajectory_rk2[i, 1]**2)
    rk2_radial_trajectory[i, 0] = r
예제 #7
0
    r = sqrt(x**2 + y**2)
    phi = np.arctan2(y, x)

    b_mag = 1 / r

    b_vec = Vector3D(r * np.cos(phi), r * np.sin(phi), 0)
    b_vec = b_vec.transform(rotate_z(90))
    b_vec = b_vec.normalise() * b_mag

    return b_vec


world = World()
b_field = PythonVectorFunction3D(vectorfunction3d)

field_tracer1 = FieldlineTracer(b_field, method=RK2(step_size=0.0001))
field_tracer2 = FieldlineTracer(b_field, method=RK4(step_size=0.0001))

mlab.plot3d([0, 0.5, 1], [0, 0, 0], [0, 0, 0],
            tube_radius=0.001,
            color=(1, 0, 0))
mlab.plot3d([0, 0, 0], [0, 0.5, 1], [0, 0, 0],
            tube_radius=0.001,
            color=(0, 1, 0))
mlab.plot3d([0, 0, 0], [0, 0, 0], [0, 0.5, 1],
            tube_radius=0.001,
            color=(0, 0, 1))

seed_point = Point3D(1, 0, 0)
end_point, _, trajectory1 = field_tracer1.trace(world,
                                                seed_point,
예제 #8
0
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 = []
trajectories = []
for i in range(n):
    end_point, _, trajectory = field_tracer.trace(world,
                                                  seed_points[i],
                                                  save_trajectory=True,
                                                  max_length=10)
    trajectories.append(trajectory)
    end_points.append(end_point)

# mlab.plot3d([0, 0.005, 0.001], [0, 0, 0], [0, 0, 0], tube_radius=0.0005, color=(1, 0, 0))
# mlab.plot3d([0, 0, 0], [0, 0.005, 0.001], [0, 0, 0], tube_radius=0.0005, color=(0, 1, 0))
# mlab.plot3d([0, 0, 0], [0, 0, 0], [0, 0.005, 0.001], tube_radius=0.0005, color=(0, 0, 1))