Field Interpolation
A robust field interpolation is the prerequisite for pushing particles. This example demonstrates the construction of scalar/vector field interpolators for Cartesian/Spherical grids. If the field is analytic, you can directly pass the generated function to prepare.
import TestParticle as TP
using StaticArrays
using Chairmarks
function setup_spherical_field()
r = logrange(0.1, 10.0, length = 16)
r_uniform = range(0.1, 10.0, length = 16)
θ = range(0, π, length = 16)
ϕ = range(0, 2π, length = 16)
B₀ = 1e-8 # [nT]
B = zeros(3, length(r), length(θ), length(ϕ)) # vector
A = zeros(length(r), length(θ), length(ϕ)) # scalar
for (iθ, θ_val) in enumerate(θ)
sinθ, cosθ = sincos(θ_val)
B[1, :, iθ, :] .= B₀ * cosθ
B[2, :, iθ, :] .= -B₀ * sinθ
A[:, iθ, :] .= B₀ * sinθ
end
B_field_nu = TP.getinterp(TP.StructuredGrid, B, r, θ, ϕ)
A_field_nu = TP.getinterp_scalar(TP.StructuredGrid, A, r, θ, ϕ)
B_field = TP.getinterp(TP.StructuredGrid, B, r_uniform, θ, ϕ)
A_field = TP.getinterp_scalar(TP.StructuredGrid, A, r_uniform, θ, ϕ)
return B_field_nu, A_field_nu, B_field, A_field
end
function setup_cartesian_field()
x = range(-10, 10, length = 16)
y = range(-10, 10, length = 16)
z = range(-10, 10, length = 16)
B = zeros(3, length(x), length(y), length(z)) # vector
B[3, :, :, :] .= 10e-9
A = zeros(length(x), length(y), length(z)) # scalar
A[:, :, :] .= 10e-9
B_field = TP.getinterp(B, x, y, z)
A_field = TP.getinterp_scalar(A, x, y, z)
return B_field, A_field
end
function setup_cartesian_nonuniform_field()
x = logrange(0.1, 10.0, length = 16)
y = range(-10, 10, length = 16)
z = range(-10, 10, length = 16)
B = zeros(3, length(x), length(y), length(z)) # vector
B[3, :, :, :] .= 10e-9
A = zeros(length(x), length(y), length(z)) # scalar
A[:, :, :] .= 10e-9
B_field = TP.getinterp(TP.RectilinearGrid, B, x, y, z)
A_field = TP.getinterp_scalar(TP.RectilinearGrid, A, x, y, z)
return B_field, A_field
end
B_sph_nu, A_sph_nu, B_sph, A_sph = setup_spherical_field();
B_car, A_car = setup_cartesian_field();
B_car_nu, A_car_nu = setup_cartesian_nonuniform_field();
loc = SA[1.0, 1.0, 1.0];3-element StaticArraysCore.SVector{3, Float64} with indices SOneTo(3):
1.0
1.0
1.0Gridded spherical interpolation
julia> @be B_sph_nu($loc)
Benchmark: 3128 samples with 78 evaluations
min 374.423 ns (2 allocs: 64 bytes)
median 377.756 ns (2 allocs: 64 bytes)
mean 381.865 ns (2 allocs: 64 bytes)
max 644.154 ns (2 allocs: 64 bytes)
julia> @be A_sph_nu($loc)
Benchmark: 3124 samples with 88 evaluations
min 332.557 ns (2 allocs: 48 bytes)
median 334.841 ns (2 allocs: 48 bytes)
mean 339.021 ns (2 allocs: 48 bytes)
max 911.830 ns (2 allocs: 48 bytes)Uniform spherical interpolation
julia> @be B_sph($loc)
Benchmark: 3154 samples with 213 evaluations
min 135.606 ns (2 allocs: 64 bytes)
median 137.300 ns (2 allocs: 64 bytes)
mean 139.019 ns (2 allocs: 64 bytes)
max 296.329 ns (2 allocs: 64 bytes)
julia> @be A_sph($loc)
Benchmark: 3180 samples with 285 evaluations
min 100.470 ns (2 allocs: 48 bytes)
median 102.789 ns (2 allocs: 48 bytes)
mean 103.867 ns (2 allocs: 48 bytes)
max 192.782 ns (2 allocs: 48 bytes)Uniform Cartesian interpolation
julia> @be B_car($loc)
Benchmark: 3207 samples with 401 evaluations
min 71.130 ns (2 allocs: 64 bytes)
median 72.828 ns (2 allocs: 64 bytes)
mean 73.627 ns (2 allocs: 64 bytes)
max 131.968 ns (2 allocs: 64 bytes)
julia> @be A_car($loc)
Benchmark: 2581 samples with 463 evaluations
min 61.886 ns (2 allocs: 48 bytes)
median 80.430 ns (2 allocs: 48 bytes)
mean 78.848 ns (2 allocs: 48 bytes)
max 539.674 ns (2 allocs: 48 bytes)Non-uniform Cartesian interpolation
julia> @be B_car_nu($loc)
Benchmark: 3129 samples with 98 evaluations
min 298.827 ns (2 allocs: 64 bytes)
median 300.969 ns (2 allocs: 64 bytes)
mean 304.155 ns (2 allocs: 64 bytes)
max 461.469 ns (2 allocs: 64 bytes)
julia> @be A_car_nu($loc)
Benchmark: 3154 samples with 100 evaluations
min 291.950 ns (2 allocs: 48 bytes)
median 293.260 ns (2 allocs: 48 bytes)
mean 296.872 ns (2 allocs: 48 bytes)
max 509.050 ns (2 allocs: 48 bytes)Based on the benchmarks, for the same grid size, gridded interpolation (StructuredGrid with non-uniform ranges, RectilinearGrid) is 2x slower than uniform mesh interpolation (StructuredGrid with uniform ranges, CartesianGrid).
Related API
TestParticle.getinterp Function
getinterp(::Type{<:CartesianGrid}, A, gridx, gridy, gridz, order::Int=1, bc::Int=1)Return a function for interpolating field array A on the grid given by gridx, gridy, and gridz.
Arguments
order::Int=1: order of interpolation in [1,2,3].bc::Int=1: type of boundary conditions, 1 -> NaN, 2 -> periodic, 3 -> Flat.dir::Int: 1/2/3, representing x/y/z direction.
Notes
The input array A may be modified in-place for memory optimization.
TestParticle.getinterp_scalar Function
getinterp_scalar(::Type{<:CartesianGrid}, A, gridx, gridy, gridz, order::Int=1, bc::Int=1)Return a function for interpolating scalar array A on the grid given by gridx, gridy, and gridz. Currently only 3D arrays are supported.
Arguments
order::Int=1: order of interpolation in [1,2,3].bc::Int=1: type of boundary conditions, 1 -> NaN, 2 -> periodic, 3 -> Flat.dir::Int: 1/2/3, representing x/y/z direction.
TestParticle.prepare Function
prepare(args...; kwargs...) -> (q2m, m, E, B, F)
prepare(E, B, F = ZeroField(); kwargs...)
prepare(grid::CartesianGrid, E, B, F = ZeroField(); kwargs...)
prepare(x, E, B, F = ZeroField(); dir = 1, kwargs...)
prepare(x, y, E, B, F = ZeroField(); kwargs...)
prepare(x, y, z, E, B, F = ZeroField(); kwargs...)
prepare(B; E = ZeroField(), F = ZeroField(), kwargs...)Return a tuple consists of particle charge-mass ratio for a prescribed species of charge q and mass m, mass m for a prescribed species, analytic/interpolated EM field functions, and external force F.
Prescribed species are Electron and Proton; other species can be manually specified with m and q keywords or species = Ion(m̄, q̄), where m̄ and q̄ are the mass and charge numbers respectively.
Direct range input for uniform grid in 1/2/3D is supported. For 1D grid, an additional keyword dir is used for specifying the spatial direction, 1 -> x, 2 -> y, 3 -> z. For 3D grid, the default grid type is CartesianGrid. To use StructuredGrid (spherical) grid, an additional keyword gridtype is needed. For StructuredGrid (spherical) grid, dimensions of field arrays should be (Br, Bθ, Bϕ).
Keywords
order::Int=1: order of interpolation in [1,2,3].bc::Int=1: type of boundary conditions, 1 -> NaN, 2 -> periodic.species=Proton: particle species.q=nothing: particle charge.m=nothing: particle mass.gridtype:CartesianGrid,RectilinearGrid,StructuredGrid.