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Implement injection of particles from the embedded boundary #5208

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20d1fba
Implement changes by Maya Zeldin in a separate commit
RemiLehe Sep 3, 2024
add9df0
Add a few TODOs
RemiLehe Sep 3, 2024
e56d748
Add test example
RemiLehe Sep 4, 2024
1f24d50
Revert "Implement changes by Maya Zeldin in a separate commit"
RemiLehe Sep 15, 2024
8897ccd
Merge branch 'development' into injection_from_eb
RemiLehe Sep 15, 2024
d9a1c86
Move test
RemiLehe Sep 15, 2024
1ef9bc4
Find boxes that overlap with the EB
RemiLehe Sep 15, 2024
00328ce
Scale the number of particles per cell
RemiLehe Sep 15, 2024
3888459
Cleanup
RemiLehe Sep 15, 2024
89c684f
Minor refactoring of refined injection for AddPlasmaFlux
RemiLehe Sep 15, 2024
2e0779d
Merge branch 'simplify_fine_injectionwq' into injection_from_eb
RemiLehe Sep 15, 2024
09e1174
Some code refactoring
RemiLehe Sep 15, 2024
f7b3e92
Scale emitting flux by the area of the boundary
RemiLehe Sep 16, 2024
3c00605
Additional simplification
RemiLehe Sep 16, 2024
f16b01c
Minor fixes
RemiLehe Sep 16, 2024
b6310ae
Merge branch 'simplify_fine_injectionwq' into injection_from_eb
RemiLehe Sep 16, 2024
6d06352
Implement rotation of momentum
RemiLehe Sep 16, 2024
2c05fe6
Fix initialization
RemiLehe Sep 16, 2024
6fe4b13
Update Examples/Tests/flux_injection/inputs_test_3d_flux_injection_fr…
RemiLehe Sep 16, 2024
9ecd54a
Update test
RemiLehe Sep 16, 2024
1d0722c
Merge branch 'injection_from_eb' of github.com:RemiLehe/WarpX into in…
RemiLehe Sep 16, 2024
c123e14
Fix parallelization issue
RemiLehe Sep 16, 2024
04d5a5e
Temporarily deactivate checksum
RemiLehe Sep 16, 2024
1a57716
Check velocity distribution
RemiLehe Sep 16, 2024
a408735
Add one more test for perpendicular direction
RemiLehe Sep 16, 2024
b203a53
Add code for the 3rd direction
RemiLehe Sep 16, 2024
ce63bca
Use pointers
RemiLehe Sep 17, 2024
6ed49a3
Fix code when EB is not present
RemiLehe Sep 17, 2024
97cab47
Merge branch 'development' into injection_from_eb
RemiLehe Sep 17, 2024
c24849c
Merge branch 'development' into injection_from_eb
RemiLehe Oct 1, 2024
a728163
Fix clang-tidy error
RemiLehe Oct 1, 2024
e17ba4f
Avoid HIP errors
RemiLehe Oct 1, 2024
6847ba4
Add 2D test
RemiLehe Oct 1, 2024
780a7fd
Merge branch 'development' into injection_from_eb
RemiLehe Oct 8, 2024
890fc01
Add input script
RemiLehe Oct 8, 2024
c03b385
Move function to .H
RemiLehe Oct 8, 2024
4143ae9
Add 2D/RZ implementation
RemiLehe Oct 8, 2024
f5128d0
Move test script
RemiLehe Oct 8, 2024
a8468bd
Generalize analysis script for 3D, 2D, RZ
RemiLehe Oct 8, 2024
0516797
Correct input script
RemiLehe Oct 8, 2024
1a2bb35
Fix 2D bug
RemiLehe Oct 8, 2024
7f141f5
Add RZ test
RemiLehe Oct 8, 2024
568df9a
Fix RZ bug
RemiLehe Oct 8, 2024
312d6f1
Fix RZ bug
RemiLehe Oct 9, 2024
913f8ee
Change parameter for tests to pass
RemiLehe Oct 9, 2024
b364a3c
Leverage base input file
RemiLehe Oct 9, 2024
fdc4d1b
Add checksums
RemiLehe Oct 9, 2024
c0368af
Reactivate checksum test
RemiLehe Oct 9, 2024
f3bc86c
Fix compilation tests
RemiLehe Oct 9, 2024
57e29d9
Fix clang-tidy error
RemiLehe Oct 9, 2024
b56c3f9
Update checksum
RemiLehe Oct 9, 2024
3b68f69
Merge branch 'development' into injection_from_eb
RemiLehe Oct 9, 2024
5a7b468
Merge branch 'development' into injection_from_eb
RemiLehe Oct 10, 2024
1d723c0
Fix const-ness
RemiLehe Oct 10, 2024
de16bfa
Add documentation
RemiLehe Oct 10, 2024
b7f6f50
Update comment
RemiLehe Oct 10, 2024
404f262
Update comment
RemiLehe Oct 10, 2024
09703f5
Correct const-ness
RemiLehe Oct 10, 2024
249be0b
Incorporate review comments
RemiLehe Oct 10, 2024
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13 changes: 9 additions & 4 deletions Docs/source/usage/parameters.rst
Original file line number Diff line number Diff line change
Expand Up @@ -971,16 +971,21 @@ Particle initialization
The ``external_file`` option is currently implemented for 2D, 3D and RZ geometries, with record components in the cartesian coordinates ``(x,y,z)`` for 3D and RZ, and ``(x,z)`` for 2D.
For more information on the `openPMD format <https://github.com/openPMD>`__ and how to build WarpX with it, please visit :ref:`the install section <install-developers>`.

* ``NFluxPerCell``: Continuously inject a flux of macroparticles from a planar surface.
* ``NFluxPerCell``: Continuously inject a flux of macroparticles from a surface. The emitting surface can be chosen to be either a plane
defined by the user (using some of the parameters listed below), or the embedded boundary (see :ref:`Embedded Boundary Conditions <running-cpp-parameters-eb>`).
This requires the additional parameters:

* ``<species_name>.flux_profile`` (see the description of this parameter further below)

* ``<species_name>.surface_flux_pos`` (`double`, location of the injection plane [meter])
* ``<species_name>.inject_from_embedded_boundary`` (`0` or `1`, default `0` ; whether to inject from the embedded boundary or from a user-specified plane.
When injecting from the embedded boundary, the momentum distribution specified by the user along ``z`` (see e.g. ``uz_m``, ``uz_th`` below) is interpreted
as the momentum distribution along the local normal to the embedded boundary.)

* ``<species_name>.flux_normal_axis`` (`x`, `y`, or `z` for 3D, `x` or `z` for 2D, or `r`, `t`, or `z` for RZ. When `flux_normal_axis` is `r` or `t`, the `x` and `y` components of the user-specified momentum distribution are interpreted as the `r` and `t` components respectively)
* ``<species_name>.surface_flux_pos`` (only used when injecting from a plane, `double`, location of the injection plane [meter])

* ``<species_name>.flux_direction`` (`-1` or `+1`, direction of flux relative to the plane)
* ``<species_name>.flux_normal_axis`` (only used when injecting from a plane, `x`, `y`, or `z` for 3D, `x` or `z` for 2D, or `r`, `t`, or `z` for RZ. When `flux_normal_axis` is `r` or `t`, the `x` and `y` components of the user-specified momentum distribution are interpreted as the `r` and `t` components respectively)

* ``<species_name>.flux_direction`` (only used when injecting from a plane, `-1` or `+1`, direction of flux relative to the plane)

* ``<species_name>.num_particles_per_cell`` (`double`)

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30 changes: 30 additions & 0 deletions Examples/Tests/flux_injection/CMakeLists.txt
Original file line number Diff line number Diff line change
Expand Up @@ -20,3 +20,33 @@ add_warpx_test(
diags/diag1000120 # output
OFF # dependency
)

add_warpx_test(
test_3d_flux_injection_from_eb # name
3 # dims
2 # nprocs
inputs_test_3d_flux_injection_from_eb # inputs
analysis_flux_injection_from_eb.py # analysis
diags/diag1000010 # output
OFF # dependency
)

add_warpx_test(
test_rz_flux_injection_from_eb # name
RZ # dims
2 # nprocs
inputs_test_rz_flux_injection_from_eb # inputs
analysis_flux_injection_from_eb.py # analysis
diags/diag1000010 # output
OFF # dependency
)

add_warpx_test(
test_2d_flux_injection_from_eb # name
2 # dims
2 # nprocs
inputs_test_2d_flux_injection_from_eb # inputs
analysis_flux_injection_from_eb.py # analysis
diags/diag1000010 # output
OFF # dependency
)
161 changes: 161 additions & 0 deletions Examples/Tests/flux_injection/analysis_flux_injection_from_eb.py
Original file line number Diff line number Diff line change
@@ -0,0 +1,161 @@
#!/usr/bin/env python3
#
# Copyright 2024 Remi Lehe
#
# This file is part of WarpX.
#
# License: BSD-3-Clause-LBNL

"""
This script tests the emission of particles from the embedded boundary.
(In this case, the embedded boundary is a sphere in 3D and RZ, a cylinder in 2D.)
We check that the embedded boundary emits the correct number of particles, and that
the particle distributions are consistent with the expected distributions.
"""

import os
import re
import sys

import matplotlib.pyplot as plt
import numpy as np
import yt
from scipy.constants import c, m_e
from scipy.special import erf

sys.path.insert(1, "../../../../warpx/Regression/Checksum/")
import checksumAPI

yt.funcs.mylog.setLevel(0)

# Open plotfile specified in command line
fn = sys.argv[1]
ds = yt.load(fn)
ad = ds.all_data()
t_max = ds.current_time.item() # time of simulation

# Extract the dimensionality of the simulation
with open("./warpx_used_inputs", "r") as f:
warpx_used_inputs = f.read()
if re.search("geometry.dims = 2", warpx_used_inputs):
dims = "2D"
elif re.search("geometry.dims = RZ", warpx_used_inputs):
dims = "RZ"
elif re.search("geometry.dims = 3", warpx_used_inputs):
dims = "3D"

# Total number of electrons expected:
# Simulation parameters determine the total number of particles emitted (Ntot)
flux = 1.0 # in m^-2.s^-1, from the input script
R = 2.0 # in m, radius of the sphere
if dims == "3D" or dims == "RZ":
emission_surface = 4 * np.pi * R**2 # in m^2
elif dims == "2D":
emission_surface = 2 * np.pi * R # in m
Ntot = flux * emission_surface * t_max

# Parameters of the histogram
hist_bins = 50
hist_range = [-0.5, 0.5]


# Define function that histograms and checks the data
def gaussian_dist(u, u_th):
return 1.0 / ((2 * np.pi) ** 0.5 * u_th) * np.exp(-(u**2) / (2 * u_th**2))


def gaussian_flux_dist(u, u_th, u_m):
normalization_factor = u_th**2 * np.exp(-(u_m**2) / (2 * u_th**2)) + (
np.pi / 2
) ** 0.5 * u_m * u_th * (1 + erf(u_m / (2**0.5 * u_th)))
result = (
1.0
/ normalization_factor
* np.where(u > 0, u * np.exp(-((u - u_m) ** 2) / (2 * u_th**2)), 0)
)
return result


def compare_gaussian(u, w, u_th, label=""):
du = (hist_range[1] - hist_range[0]) / hist_bins
w_hist, u_hist = np.histogram(u, bins=hist_bins, weights=w / du, range=hist_range)
u_hist = 0.5 * (u_hist[1:] + u_hist[:-1])
w_th = Ntot * gaussian_dist(u_hist, u_th)
plt.plot(u_hist, w_hist, label=label + ": simulation")
plt.plot(u_hist, w_th, "--", label=label + ": theory")
assert np.allclose(w_hist, w_th, atol=0.07 * w_th.max())


def compare_gaussian_flux(u, w, u_th, u_m, label=""):
du = (hist_range[1] - hist_range[0]) / hist_bins
w_hist, u_hist = np.histogram(u, bins=hist_bins, weights=w / du, range=hist_range)
u_hist = 0.5 * (u_hist[1:] + u_hist[:-1])
w_th = Ntot * gaussian_flux_dist(u_hist, u_th, u_m)
plt.plot(u_hist, w_hist, label=label + ": simulation")
plt.plot(u_hist, w_th, "--", label=label + ": theory")
assert np.allclose(w_hist, w_th, atol=0.05 * w_th.max())


# Load data and perform check

plt.figure()

if dims == "3D":
x = ad["electron", "particle_position_x"].to_ndarray()
y = ad["electron", "particle_position_y"].to_ndarray()
z = ad["electron", "particle_position_z"].to_ndarray()
elif dims == "2D":
x = ad["electron", "particle_position_x"].to_ndarray()
y = np.zeros_like(x)
z = ad["electron", "particle_position_y"].to_ndarray()
elif dims == "RZ":
theta = ad["electron", "particle_theta"].to_ndarray()
r = ad["electron", "particle_position_x"].to_ndarray()
x = r * np.cos(theta)
y = r * np.sin(theta)
z = ad["electron", "particle_position_y"].to_ndarray()
ux = ad["electron", "particle_momentum_x"].to_ndarray() / (m_e * c)
uy = ad["electron", "particle_momentum_y"].to_ndarray() / (m_e * c)
uz = ad["electron", "particle_momentum_z"].to_ndarray() / (m_e * c)
w = ad["electron", "particle_weight"].to_ndarray()

# Check that the total number of particles emitted is correct
Ntot_sim = np.sum(w)
print("Ntot_sim = ", Ntot_sim)
print("Ntot = ", Ntot)
assert np.isclose(Ntot_sim, Ntot, rtol=0.01)

# Check that none of the particles are inside the EB
# A factor 0.98 is applied to accomodate
# the cut-cell approximation of the sphere
assert np.all(x**2 + y**2 + z**2 > (0.98 * R) ** 2)

# Check that the normal component of the velocity is consistent with the expected distribution
r = np.sqrt(x**2 + y**2 + z**2)
nx = x / r
ny = y / r
nz = z / r
u_n = ux * nx + uy * ny + uz * nz # normal component
compare_gaussian_flux(u_n, w, u_th=0.1, u_m=0.07, label="u_n")

# Pick a direction that is orthogonal to the normal direction, and check the distribution
vx = ny / np.sqrt(nx**2 + ny**2)
vy = -nx / np.sqrt(nx**2 + ny**2)
vz = 0
u_perp = ux * vx + uy * vy + uz * vz
compare_gaussian(u_perp, w, u_th=0.01, label="u_perp")

# Pick the other perpendicular direction, and check the distribution
# The third direction is obtained by the cross product (n x v)
wx = ny * vz - nz * vy
wy = nz * vx - nx * vz
wz = nx * vy - ny * vx
u_perp2 = ux * wx + uy * wy + uz * wz
compare_gaussian(u_perp2, w, u_th=0.01, label="u_perp")

plt.tight_layout()
plt.savefig("Distribution.png")

# Verify checksum
test_name = os.path.split(os.getcwd())[1]
checksumAPI.evaluate_checksum(test_name, fn)
42 changes: 42 additions & 0 deletions Examples/Tests/flux_injection/inputs_base_from_eb
Original file line number Diff line number Diff line change
@@ -0,0 +1,42 @@
# Maximum number of time steps
max_step = 10

# The lo and hi ends of grids are multipliers of blocking factor
amr.blocking_factor = 8

# Maximum allowable size of each subdomain in the problem domain;
# this is used to decompose the domain for parallel calculations.
amr.max_grid_size = 8

# Maximum level in hierarchy (for now must be 0, i.e., one level in total)
amr.max_level = 0

# Deactivate Maxwell solver
algo.maxwell_solver = none
warpx.const_dt = 1e-9

# Embedded boundary
warpx.eb_implicit_function = "-(x**2+y**2+z**2-2**2)"

# particles
particles.species_names = electron
algo.particle_shape = 3

electron.charge = -q_e
electron.mass = m_e
electron.injection_style = NFluxPerCell
electron.inject_from_embedded_boundary = 1
electron.num_particles_per_cell = 100
electron.flux_profile = parse_flux_function
electron.flux_function(x,y,z,t) = "1."
electron.momentum_distribution_type = gaussianflux
electron.ux_th = 0.01
electron.uy_th = 0.01
electron.uz_th = 0.1
electron.uz_m = 0.07

# Diagnostics
diagnostics.diags_names = diag1
diag1.intervals = 10
diag1.diag_type = Full
diag1.fields_to_plot = none
Original file line number Diff line number Diff line change
@@ -0,0 +1,13 @@
FILE = inputs_base_from_eb

# number of grid points
amr.n_cell = 16 16

# Geometry
geometry.dims = 2
geometry.prob_lo = -4 -4
geometry.prob_hi = 4 4

# Boundary condition
boundary.field_lo = periodic periodic
boundary.field_hi = periodic periodic
Original file line number Diff line number Diff line change
@@ -0,0 +1,13 @@
FILE = inputs_base_from_eb

# number of grid points
amr.n_cell = 16 16 16

# Geometry
geometry.dims = 3
geometry.prob_lo = -4 -4 -4
geometry.prob_hi = 4 4 4

# Boundary condition
boundary.field_lo = periodic periodic periodic
boundary.field_hi = periodic periodic periodic
Original file line number Diff line number Diff line change
@@ -0,0 +1,15 @@
FILE = inputs_base_from_eb

# number of grid points
amr.n_cell = 8 16

# Geometry
geometry.dims = RZ
geometry.prob_lo = 0 -4
geometry.prob_hi = 4 4

# Boundary condition
boundary.field_lo = none periodic
boundary.field_hi = pec periodic

electron.num_particles_per_cell = 300
Original file line number Diff line number Diff line change
@@ -0,0 +1,11 @@
{
"lev=0": {},
"electron": {
"particle_momentum_x": 6.990772711451971e-19,
"particle_momentum_y": 5.4131306169803364e-20,
"particle_momentum_z": 6.997294931789925e-19,
"particle_position_x": 35518.95120597846,
"particle_position_y": 35517.855675902414,
"particle_weight": 1.25355e-07
}
}
Original file line number Diff line number Diff line change
@@ -0,0 +1,12 @@
{
"lev=0": {},
"electron": {
"particle_momentum_x": 4.371688233196277e-18,
"particle_momentum_y": 4.368885079657374e-18,
"particle_momentum_z": 4.367429424105371e-18,
"particle_position_x": 219746.94401890738,
"particle_position_y": 219690.7015248918,
"particle_position_z": 219689.45580938633,
"particle_weight": 4.954974999999999e-07
}
}
Original file line number Diff line number Diff line change
@@ -0,0 +1,12 @@
{
"lev=0": {},
"electron": {
"particle_momentum_x": 6.734984863106283e-19,
"particle_momentum_y": 6.786279785869023e-19,
"particle_momentum_z": 1.0527983828124758e-18,
"particle_position_x": 53309.270966506396,
"particle_position_y": 53302.3776094842,
"particle_theta": 58707.74469425615,
"particle_weight": 4.991396867417661e-07
}
}
2 changes: 2 additions & 0 deletions Source/Initialization/PlasmaInjector.H
Original file line number Diff line number Diff line change
Expand Up @@ -131,6 +131,8 @@ public:
int flux_normal_axis;
int flux_direction; // -1 for left, +1 for right

bool m_inject_from_eb = false; // whether to inject from the embedded boundary

bool radially_weighted = true;

std::string str_flux_function;
Expand Down
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