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Add emission due to CX with neutral hydrogen to the TotalRadiatedPower model #455

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1 change: 1 addition & 0 deletions CHANGELOG.md
Original file line number Diff line number Diff line change
Expand Up @@ -16,6 +16,7 @@ New:
* **Beam dispersion calculation has changed from sigma(z) = sigma + z * tan(alpha) to sigma(z) = sqrt(sigma^2 + (z * tan(alpha))^2) for consistancy with the Gaussian beam model. Attention!!! The results of BES and CX spectroscopy are affected by this change. (#414)**
* Improved beam direction calculation to allow for natural broadening of the BES line shape due to beam divergence. (#414)
* Add kwargs to invert_regularised_nnls to pass them to scipy.optimize.nnls. (#438)
* Add the power radiated in spectral lines due to charge exchange with thermal neutral hydrogen to the TotalRadiatedPower model. (#370)

Bug fixes:
* Fix deprecated transforms being cached in LaserMaterial after laser.transform update (#420)
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2 changes: 1 addition & 1 deletion cherab/core/atomic/rates.pxd
Original file line number Diff line number Diff line change
Expand Up @@ -84,7 +84,7 @@ cdef class _RadiatedPower:
readonly Element element
readonly int charge

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999


cdef class LineRadiationPower(_RadiatedPower):
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2 changes: 1 addition & 1 deletion cherab/core/atomic/rates.pyx
Original file line number Diff line number Diff line change
Expand Up @@ -263,7 +263,7 @@ cdef class _RadiatedPower:
"""
return self.evaluate(electron_density, electron_temperature)

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
"""
Evaluate the radiated power at the given plasma conditions.

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4 changes: 3 additions & 1 deletion cherab/core/model/plasma/total_radiated_power.pxd
Original file line number Diff line number Diff line change
Expand Up @@ -18,7 +18,7 @@


from cherab.core.atomic.elements cimport Element
from cherab.core.atomic.rates cimport LineRadiationPower, ContinuumPower
from cherab.core.atomic.rates cimport LineRadiationPower, ContinuumPower, CXRadiationPower
from cherab.core.plasma cimport PlasmaModel
from cherab.core.species cimport Species

Expand All @@ -30,7 +30,9 @@ cdef class TotalRadiatedPower(PlasmaModel):
Element _element
int _charge
Species _line_rad_species, _recom_species
list _hydrogen_species
LineRadiationPower _plt_rate
ContinuumPower _prb_rate
CXRadiationPower _prc_rate

cdef int _populate_cache(self) except -1
66 changes: 64 additions & 2 deletions cherab/core/model/plasma/total_radiated_power.pyx
Original file line number Diff line number Diff line change
Expand Up @@ -20,9 +20,40 @@
from raysect.optical cimport Spectrum, Point3D, Vector3D
from cherab.core cimport Plasma, AtomicData
from cherab.core.utility.constants cimport RECIP_4_PI
from cherab.core.atomic.elements import hydrogen, deuterium, tritium


cdef class TotalRadiatedPower(PlasmaModel):
r"""
Emitter that calculates total power radiated by a given ion, which includes:

- line power due to electron impact excitation,
- continuum and line power due to recombination and Bremsstrahlung,
- line power due to charge exchange with thermal neutral hydrogen and its isotopes.

The emission calculated by this model is spectrally unresolved,
which means that the total radiated power will be spread of the entire
observable spectral range.

.. math::
\epsilon_{\mathrm{total}} = \frac{1}{4 \pi \Delta\lambda} \left(
n_{Z_\mathrm{i}} n_\mathrm{e} C_{\mathrm{excit}}(n_\mathrm{e}, T_\mathrm{e}) +
n_{Z_\mathrm{i} + 1} n_\mathrm{e} C_{\mathrm{recomb}}(n_\mathrm{e}, T_\mathrm{e}) +
n_{Z_\mathrm{i} + 1} n_\mathrm{hyd} C_{\mathrm{cx}}(n_\mathrm{e}, T_\mathrm{e}) \right)

where :math:`n_{Z_\mathrm{i}}` is the target species density;
:math:`n_{Z_\mathrm{i} + 1}` is the recombining species density;
:math:`n_{\mathrm{hyd}}` is the total density of all hydrogen isotopes;
:math:`C_{\mathrm{excit}}, C_{\mathrm{recomb}}, C_{\mathrm{cx}}` are the radiated power
coefficients in :math:`W m^3` due to electron impact excitation, recombination
+ Bremsstrahlung and charge exchange with thermal neutral hydrogen, respectively;
:math:`\Delta\lambda` is the observable spectral range.

:param Element element: The atomic element/isotope.
:param int charge: The charge state of the element/isotope.
:param Plasma plasma: The plasma to which this emission model is attached. Default is None.
:param AtomicData atomic_data: The atomic data provider for this model. Default is None.
"""

def __init__(self, Element element, int charge, Plasma plasma=None, AtomicData atomic_data=None):

Expand All @@ -42,7 +73,9 @@ cdef class TotalRadiatedPower(PlasmaModel):

cdef:
int i
double ne, ni, ni_upper, te, plt_radiance, prb_radiance
double ne, ni, ni_upper, nhyd, te
double plt_radiance, prb_radiance, prc_radiance
Species hyd_species

# cache data on first run
if not self._cache_loaded:
Expand All @@ -60,22 +93,37 @@ cdef class TotalRadiatedPower(PlasmaModel):

ni_upper = self._recom_species.distribution.density(point.x, point.y, point.z)

nhyd = 0
for hyd_species in self._hydrogen_species:
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nhyd += hyd_species.distribution.density(point.x, point.y, point.z)

# add emission to spectrum
if self._plt_rate and ni > 0:
plt_radiance = RECIP_4_PI * self._plt_rate.evaluate(ne, te) * ne * ni / (spectrum.max_wavelength - spectrum.min_wavelength)
else:
plt_radiance = 0

if self._prb_rate and ni_upper > 0:
prb_radiance = RECIP_4_PI * self._prb_rate.evaluate(ne, te) * ne * ni_upper / (spectrum.max_wavelength - spectrum.min_wavelength)
else:
prb_radiance = 0

if self._prc_rate and ni_upper > 0 and nhyd > 0:
prc_radiance = RECIP_4_PI * self._prc_rate.evaluate(ne, te) * nhyd * ni_upper / (spectrum.max_wavelength - spectrum.min_wavelength)
else:
prc_radiance = 0

for i in range(spectrum.bins):
spectrum.samples_mv[i] += plt_radiance + prb_radiance
spectrum.samples_mv[i] += plt_radiance + prb_radiance + prc_radiance
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return spectrum

cdef int _populate_cache(self) except -1:

cdef:
Species hyd_species
Element hyd_isotope

# sanity checks
if self._plasma is None:
raise RuntimeError("The emission model is not connected to a plasma object.")
Expand All @@ -100,6 +148,18 @@ cdef class TotalRadiatedPower(PlasmaModel):
"recombination/continuum emission, (element={}, ionisation={})."
"".format(self._element.symbol, self._charge+1))

# cache hydrogen species and CX radiation rate
self._prc_rate = self._atomic_data.cx_radiated_power_rate(self._element, self._charge+1)

self._hydrogen_species = []
for hyd_isotope in (hydrogen, deuterium, tritium):
try:
hyd_species = self._plasma.composition.get(hyd_isotope, 0)
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except ValueError:
pass
else:
self._hydrogen_species.append(hyd_species)

self._cache_loaded = True

def _change(self):
Expand All @@ -108,5 +168,7 @@ cdef class TotalRadiatedPower(PlasmaModel):
self._cache_loaded = False
self._line_rad_species = None
self._recom_species = None
self._hydrogen_species = None
self._plt_rate = None
self._prb_rate = None
self._prc_rate = None
142 changes: 142 additions & 0 deletions cherab/core/tests/test_total_radiated_power.py
Original file line number Diff line number Diff line change
@@ -0,0 +1,142 @@
# Copyright 2016-2023 Euratom
# Copyright 2016-2023 United Kingdom Atomic Energy Authority
# Copyright 2016-2023 Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas
#
# 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 unittest

import numpy as np

from raysect.core import Point3D, Vector3D
from raysect.optical import Ray, World

from cherab.core.atomic import AtomicData, LineRadiationPower, ContinuumPower, CXRadiationPower
from cherab.core.atomic import deuterium, hydrogen, nitrogen
from cherab.tools.plasmas.slab import build_constant_slab_plasma
from cherab.core.model import TotalRadiatedPower

from cherab.core.utility import EvAmuToMS, EvToJ


class ConstantLineRadiationPower(LineRadiationPower):
"""
Constant line radiation power coefficient.
"""

def __init__(self, value):
self.value = value

def evaluate(self, density, temperature):

return self.value


class ConstantContinuumPower(ContinuumPower):
"""
Constant continuum power coefficient.
"""

def __init__(self, value):
self.value = value

def evaluate(self, density, temperature):

return self.value


class ConstantCXRadiationPower(CXRadiationPower):
"""
Constant charge exchange radiation power coefficient.
"""

def __init__(self, value):
self.value = value

def evaluate(self, density, temperature):

return self.value


class MockAtomicData(AtomicData):
"""Fake atomic data for test purpose."""

def line_radiated_power_rate(self, element, charge):

return ConstantLineRadiationPower(1.e-32)

def continuum_radiated_power_rate(self, element, charge):

return ConstantContinuumPower(1.e-33)

def cx_radiated_power_rate(self, element, charge):

return ConstantCXRadiationPower(1.e-31)


class TestTotalRadiatedPower(unittest.TestCase):

def setUp(self):

self.world = World()

self.atomic_data = MockAtomicData()

plasma_species = [(deuterium, 0, 1.e18, 500., Vector3D(0, 0, 0)),
(hydrogen, 0, 1.e18, 500., Vector3D(0, 0, 0)),
(nitrogen, 6, 5.e18, 1100., Vector3D(0, 0, 0)),
(nitrogen, 7, 1.e19, 1100., Vector3D(0, 0, 0))]
self.plasma = build_constant_slab_plasma(length=1.2, width=1.2, height=1.2,
electron_density=1e19, electron_temperature=1000.,
plasma_species=plasma_species)
self.plasma.parent = self.world
self.plasma.atomic_data = self.atomic_data

def test_beam_density(self):

self.plasma.models = [TotalRadiatedPower(nitrogen, 6)]

# observing
origin = Point3D(1.5, 0, 0)
direction = Vector3D(-1, 0, 0)
ray = Ray(origin=origin, direction=direction,
min_wavelength=500., max_wavelength=550., bins=2)
radiated_power = ray.trace(self.world).total()

# validating
ne = self.plasma.electron_distribution.density(0.5, 0.5, 0.5)
n_n6 = self.plasma.composition[(nitrogen, 6)].distribution.density(0.5, 0.5, 0.5)
n_n7 = self.plasma.composition[(nitrogen, 7)].distribution.density(0.5, 0.5, 0.5)
n_h0 = self.plasma.composition[(hydrogen, 0)].distribution.density(0.5, 0.5, 0.5)
n_d0 = self.plasma.composition[(deuterium, 0)].distribution.density(0.5, 0.5, 0.5)

integration_length = 1.2

plt_rate = self.atomic_data.line_radiated_power_rate(nitrogen, 6).value
plt_radiance = 0.25 / np.pi * plt_rate * ne * n_n6 * integration_length

prb_rate = self.atomic_data.continuum_radiated_power_rate(nitrogen, 7).value
prb_radiance = 0.25 / np.pi * prb_rate * ne * n_n7 * integration_length

prc_rate = self.atomic_data.cx_radiated_power_rate(nitrogen, 7).value
prc_radiance = 0.25 / np.pi * prc_rate * (n_h0 + n_d0) * n_n7 * integration_length

test_radiated_power = plt_radiance + prb_radiance + prc_radiance

self.assertAlmostEqual(radiated_power / test_radiated_power, 1., delta=1e-8)


if __name__ == '__main__':
unittest.main()
12 changes: 6 additions & 6 deletions cherab/openadas/rates/radiated_power.pyx
Original file line number Diff line number Diff line change
Expand Up @@ -46,7 +46,7 @@ cdef class LineRadiationPower(CoreLineRadiationPower):
extrapolation_type = 'nearest' if extrapolate else 'none'
self._rate = Interpolator2DArray(np.log10(ne), np.log10(te), rate, 'cubic', extrapolation_type, INFINITY, INFINITY)

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
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# need to handle zeros, also density and temperature can become negative due to cubic interpolation
if electron_density < 1.e-300:
Expand All @@ -65,7 +65,7 @@ cdef class NullLineRadiationPower(CoreLineRadiationPower):
Needed for use cases where the required atomic data is missing.
"""

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
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return 0.0


Expand All @@ -92,7 +92,7 @@ cdef class ContinuumPower(CoreContinuumPower):
extrapolation_type = 'nearest' if extrapolate else 'none'
self._rate = Interpolator2DArray(np.log10(ne), np.log10(te), rate, 'cubic', extrapolation_type, INFINITY, INFINITY)

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
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# need to handle zeros, also density and temperature can become negative due to cubic interpolation
if electron_density < 1.e-300:
Expand All @@ -111,7 +111,7 @@ cdef class NullContinuumPower(CoreContinuumPower):
Needed for use cases where the required atomic data is missing.
"""

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
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return 0.0


Expand All @@ -137,7 +137,7 @@ cdef class CXRadiationPower(CoreCXRadiationPower):
extrapolation_type = 'linear' if extrapolate else 'none'
self._rate = Interpolator2DArray(np.log10(ne), np.log10(te), rate, 'cubic', extrapolation_type, INFINITY, INFINITY)

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
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# need to handle zeros, also density and temperature can become negative due to cubic interpolation
if electron_density < 1.e-300:
Expand All @@ -156,5 +156,5 @@ cdef class NullCXRadiationPower(CoreCXRadiationPower):
Needed for use cases where the required atomic data is missing.
"""

cdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
cpdef double evaluate(self, double electron_density, double electron_temperature) except? -1e999:
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return 0.0
2 changes: 1 addition & 1 deletion docs/source/models/radiated_power/radiated_power.rst
Original file line number Diff line number Diff line change
Expand Up @@ -2,4 +2,4 @@
Total Radiated Power
====================

Documentation for this model will go here soon...
.. autoclass:: cherab.core.model.plasma.total_radiated_power.TotalRadiatedPower
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