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mastu_solps_from_mdsplus.py
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# Copyright 2014-2017 United Kingdom Atomic Energy Authority
#
# Licensed under the EUPL, Version 1.1 or – as soon they will be approved by the
# European Commission - subsequent versions of the EUPL (the "Licence");
# You may not use this work except in compliance with the Licence.
# You may obtain a copy of the Licence at:
#
# https://joinup.ec.europa.eu/software/page/eupl5
#
# Unless required by applicable law or agreed to in writing, software distributed
# under the Licence is distributed on an "AS IS" basis, WITHOUT WARRANTIES OR
# CONDITIONS OF ANY KIND, either express or implied.
#
# See the Licence for the specific language governing permissions and limitations
# under the Licence.
import matplotlib.pyplot as plt
import numpy as np
from cherab.core.atomic.elements import carbon, deuterium
from cherab.solps import load_solps_from_mdsplus
plt.ion()
mds_server = 'solps-mdsplus.aug.ipp.mpg.de:8001'
ref_number = 69636
xl, xu = (0.0, 2.0)
yl, yu = (-2.0, 2.0)
sim = load_solps_from_mdsplus(mds_server, ref_number)
plasma = sim.create_plasma()
mesh = sim.mesh
vessel = mesh.vessel
d0 = plasma.composition.get(deuterium, 0)
d1 = plasma.composition.get(deuterium, 1)
c0 = plasma.composition.get(carbon, 0)
c1 = plasma.composition.get(carbon, 1)
c2 = plasma.composition.get(carbon, 2)
c3 = plasma.composition.get(carbon, 3)
c4 = plasma.composition.get(carbon, 4)
c5 = plasma.composition.get(carbon, 5)
c6 = plasma.composition.get(carbon, 6)
te_samples = np.zeros((500, 500))
ne_samples = np.zeros((500, 500))
d0_samples = np.zeros((500, 500))
d1_samples = np.zeros((500, 500))
c0_samples = np.zeros((500, 500))
c1_samples = np.zeros((500, 500))
c2_samples = np.zeros((500, 500))
c3_samples = np.zeros((500, 500))
c4_samples = np.zeros((500, 500))
c5_samples = np.zeros((500, 500))
c6_samples = np.zeros((500, 500))
d0_velocity = np.zeros((500, 500))
d1_velocity = np.zeros((500, 500))
xrange = np.linspace(xl, xu, 500)
yrange = np.linspace(yl, yu, 500)
for i, x in enumerate(xrange):
for j, y in enumerate(yrange):
ne_samples[j, i] = plasma.electron_distribution.density(x, 0.0, y)
te_samples[j, i] = plasma.electron_distribution.effective_temperature(x, 0.0, y)
d0_samples[j, i] = d0.distribution.density(x, 0.0, y)
d1_samples[j, i] = d1.distribution.density(x, 0.0, y)
c0_samples[j, i] = c0.distribution.density(x, 0.0, y)
c1_samples[j, i] = c1.distribution.density(x, 0.0, y)
c2_samples[j, i] = c2.distribution.density(x, 0.0, y)
c3_samples[j, i] = c3.distribution.density(x, 0.0, y)
c4_samples[j, i] = c4.distribution.density(x, 0.0, y)
c5_samples[j, i] = c5.distribution.density(x, 0.0, y)
c6_samples[j, i] = c6.distribution.density(x, 0.0, y)
# magnitude of velocity vector
d0_velocity[j, i] = d0.distribution.bulk_velocity(x, 0.0, y).length
d1_velocity[j, i] = d1.distribution.bulk_velocity(x, 0.0, y).length
mesh.plot_triangle_mesh()
plt.title('mesh geometry')
plt.figure()
plt.imshow(ne_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("electron density")
plt.figure()
plt.imshow(te_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("electron temperature")
plt.figure()
plt.imshow(d0_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("D0 density")
plt.figure()
plt.imshow(d1_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("DI density")
plt.figure()
plt.imshow(c0_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CI density")
plt.figure()
plt.imshow(c1_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CII density")
plt.figure()
plt.imshow(c2_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CIII density")
plt.figure()
plt.imshow(c3_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CIV density")
plt.figure()
plt.imshow(c4_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CV density")
plt.figure()
plt.imshow(c5_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CVI density")
plt.figure()
plt.imshow(c6_samples, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("CVII density")
plt.figure()
plt.imshow(d0_velocity, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("D0 velocity")
plt.figure()
plt.imshow(d1_velocity, extent=[xl, xu, yl, yu], origin='lower')
plt.colorbar()
plt.xlim(xl, xu)
plt.ylim(yl, yu)
plt.title("D1 velocity")
plt.ioff()
plt.show()