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Unexpected behavior with 2D M4 solver #662
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Hello, the |
Thanks, Is the reason for this limitation known? Is there anything specific to the laser module? |
The M4 solver was added in #486 |
Hello, I don't understand your point source was static? In that case the field was computed with the Poisson solver. |
Hi. This is what I tried. There seems to be no problem with light propagating in the y-direction, at least for the internal region.
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Interesting, the isotropic propagation seems to work as expected. |
This is the time evolution I got (the color bar range is not the same as the figure above).
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Thank you, my theory at the moment is that the boundary conditions are not adapted to the
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Hi, I tried different interpolation orders (2 and 4), different boundary conditions (SM and PML), and different polarization (polarization_phi = 0 and pi/2) with 1 downward propagating laser (name list at the bottom). In MF_Solver2D_Yee.cpp, the y index runs from 1 to ny_d-2: for( unsigned int y = 1; y < ny_d - 1; ++y ) {
Bz2D[x * ny_d + y] += dt_ov_dy * ( Ex2D[x * ny_p + y] - Ex2D[x * ny_p + y - 1] ) -
dt_ov_dx * ( Ey2D[x * ny_d + y] - Ey2D[( x - 1 ) * ny_d + y] );
} This is the same for the Cowan solver, and the Bouchard solver updates y=1 and ny_d-2 as special cases. Whereas in MF_Solver2D_M4.cpp, the y index is from 2 to ny_d-3: for (unsigned int j=2 ; j<ny_d-2 ; j++) {
(*Bz2D)(i,j) += Ay * ((*Ex2D)(i,j)-(*Ex2D)(i,j-1))
+ By * ((*Ex2D)(i+1,j)-(*Ex2D)(i+1,j-1) + (*Ex2D)(i-1,j)-(*Ex2D)(i-1,j-1))
+ Dy * ((*Ex2D)(i,j+1)-(*Ex2D)(i,j-2))
+ Ax * ((*Ey2D)(i-1,j)-(*Ey2D)(i,j))
+ Bx * ((*Ey2D)(i-1,j+1)-(*Ey2D)(i,j+1) + (*Ey2D)(i-1,j-1)-(*Ey2D)(i,j-1))
+ Dx * ((*Ey2D)(i-2,j)-(*Ey2D)(i+1,j));
} j =1 and ny_d-2 are not updated in the MF solver for M4 (and Grassi solver as well?). This is the name list I used import math
micrometer = 7.75701890
femtosecond = 2.32549576
a0 = 9.79333075
pduration = 160.*femtosecond/math.sqrt(2.*math.log(2.))
pwidth = 40.*femtosecond
pcenter = 80.*femtosecond/math.sqrt(2.*math.log(2.))
nx = 1280
dx = 60.*micrometer/nx
nt = 10800
dt = 540.*femtosecond/nt
npatch = 128
output = nt/18
Main(
geometry = "2Dcartesian",
interpolation_order = 4,
#interpolation_order = 2,
number_of_timesteps = nt,
timestep = dt,
cell_length = [dx, dx],
number_of_cells = [nx, nx],
number_of_patches = [npatch, npatch],
patch_arrangement = "hilbertian",
EM_boundary_conditions = [["silver-muller"]],
#EM_boundary_conditions = [["PML"]],
maxwell_solver = "M4"
#maxwell_solver = "Yee"
)
LaserGaussian2D(
box_side = "ymax",
a0 = a0,
omega = 1.,
focus = [10.*micrometer, 10.*micrometer],
waist = 10.*micrometer,
incidence_angle = 0.,
polarization_phi = 0.,
#polarization_phi = math.pi/2.,
ellipticity = 0.,
time_envelope = tgaussian(duration=pduration, fwhm=pwidth, center=pcenter)
)
DiagScalar(
every = output
)
DiagFields(
every = output,
fields = ["Bx_m","By_m","Bz_m","Ex","Ey","Ez"]
) |
I don't know why those indices are like this in the |
The problems with a laser can be solved by adding these lines (which I copied from the Bouchard solver) to the // at Ymin+dy - treat using simple discretization of the curl (will be overwritten if not at the ymin-border)
for (unsigned int i=0 ; i<nx_p ; i++) {
(*Bx2D)(i,1) += dt_ov_dy * ( (*Ez2D)(i,0) - (*Ez2D)(i,1) );
}
// at Ymax-dy - treat using simple discretization of the curl (will be overwritten if not at the ymax-border)
for (unsigned int i=0 ; i<nx_p ; i++) {
(*Bx2D)(i,ny_d-2) += dt_ov_dy * ( (*Ez2D)(i,ny_d-3) - (*Ez2D)(i,ny_d-2) );
}
// at Ymin+dy - treat using simple discretization of the curl (will be overwritten if not at the ymin-border)
for (unsigned int i=2 ; i<nx_d-2 ; i++) {
(*Bz2D)(i,1) += dt_ov_dx * ( (*Ey2D)(i-1,1) - (*Ey2D)(i,1) )
+ dt_ov_dy * ( (*Ex2D)(i,1) - (*Ex2D)(i,0) );
}
// at Ymax-dy - treat using simple discretization of the curl (will be overwritten if not at the ymax-border)
for (unsigned int i=2 ; i<nx_d-2 ; i++) {
(*Bz2D)(i,ny_d-2) += dt_ov_dx * ( (*Ey2D)(i-1,ny_d-2) - (*Ey2D)(i,ny_d-2) )
+ dt_ov_dy * ( (*Ex2D)(i,ny_d-2) - (*Ex2D)(i,ny_d-3) );
}
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Thank you! We'll test these changes and in case add them to the code. |
Hi, I found a possible bug in the 2D M4 solver.
The script I ran was
The Bz plot I got is
This is different than the expected behavior because there should be two identical laser pulses entering from Xmin and Ymax.
By changing the solver to Yee
maxwell_solver = "Yee"
, I got the following resultThis is the expected result.
I looked at the code src/ElectroMagnSolver/MF_Solver2D_M4.cpp and found that special treatment in Ymin and Ymax is absent.
In MF_Solver2D_Bouchard.cpp, there are lines after comment
//at Ymin+dy - treat using simple discretization of the curl
. (and for Ymax too).Also, both Y and Z boundaries seem to be treated specially in MF_Solver3D_M4.
It is just a simple guess, but could it be one of the reasons for the unexpected behavior?
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