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.
using TestParticle
using StaticArrays
using Chairmarks
function setup_spherical_field(ns = 16)
r = logrange(0.1, 10.0, length = ns)
r_uniform = range(0.1, 10.0, length = ns)
θ = range(0, π, length = ns)
ϕ = range(0, 2π, length = ns)
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 = build_interpolator(StructuredGrid, B, r, θ, ϕ)
A_field_nu = build_interpolator(StructuredGrid, A, r, θ, ϕ)
B_field = build_interpolator(StructuredGrid, B, r_uniform, θ, ϕ)
A_field = build_interpolator(StructuredGrid, A, r_uniform, θ, ϕ)
return B_field_nu, A_field_nu, B_field, A_field
end
function setup_cartesian_field(ns = 16)
x = range(-10, 10, length = ns)
y = range(-10, 10, length = ns)
z = range(-10, 10, length = ns)
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 = build_interpolator(B, x, y, z)
A_field = build_interpolator(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 = build_interpolator(RectilinearGrid, B, x, y, z)
A_field = build_interpolator(RectilinearGrid, A, x, y, z)
return B_field, A_field
end
function setup_time_dependent_field(ns = 16)
x = range(-10, 10, length = ns)
y = range(-10, 10, length = ns)
z = range(-10, 10, length = ns)
# Create two time snapshots
B0 = zeros(3, length(x), length(y), length(z))
B0[3, :, :, :] .= 1.0 # Bz = 1 at t=0
B1 = zeros(3, length(x), length(y), length(z))
B1[3, :, :, :] .= 2.0 # Bz = 2 at t=1
times = [0.0, 1.0]
function loader(i)
if i == 1
# For demonstration, we assume we load from disk here
return build_interpolator(CartesianGrid, B0, x, y, z)
elseif i == 2
return build_interpolator(CartesianGrid, B1, x, y, z)
else
error("Index out of bounds")
end
end
# B_field_t(x, t)
B_field_t = LazyTimeInterpolator(times, loader)
return B_field_t
end
function setup_mixed_precision_field(ns = 11, order = 1, bc = FillExtrap(NaN); coeffs = OnTheFly())
x = range(0.0f0, 10.0f0, length = ns)
y = range(0.0f0, 10.0f0, length = ns)
z = range(0.0f0, 10.0f0, length = ns)
B = fill(0.0f0, 3, ns, ns, ns)
B[3, :, :, :] .= 1.0f-8
itp = build_interpolator(B, x, y, z, order, bc; coeffs)
return itp
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();
B_td = setup_time_dependent_field();
itp_f32 = setup_mixed_precision_field();
loc = SA[1.0, 1.0, 1.0];
loc_f32 = SA[1.0f0, 1.0f0, 1.0f0];
loc_f64 = 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
Input Location
For spherical data, the input location is still in Cartesian coordinates!
julia> @be B_sph_nu($loc)
Benchmark: 3117 samples with 209 evaluations
min 138.675 ns (2 allocs: 64 bytes)
median 140.833 ns (2 allocs: 64 bytes)
mean 142.931 ns (2 allocs: 64 bytes)
max 279.225 ns (2 allocs: 64 bytes)
julia> @be A_sph_nu($loc)
Benchmark: 3162 samples with 274 evaluations
min 105.303 ns (2 allocs: 48 bytes)
median 106.912 ns (2 allocs: 48 bytes)
mean 108.207 ns (2 allocs: 48 bytes)
max 247.708 ns (2 allocs: 48 bytes)Uniform spherical interpolation
julia> @be B_sph($loc)
Benchmark: 3132 samples with 208 evaluations
min 139.058 ns (2 allocs: 64 bytes)
median 141.269 ns (2 allocs: 64 bytes)
mean 143.149 ns (2 allocs: 64 bytes)
max 322.264 ns (2 allocs: 64 bytes)
julia> @be A_sph($loc)
Benchmark: 3033 samples with 266 evaluations
min 107.906 ns (2 allocs: 48 bytes)
median 116.492 ns (2 allocs: 48 bytes)
mean 115.849 ns (2 allocs: 48 bytes)
max 258.620 ns (2 allocs: 48 bytes)Uniform Cartesian interpolation
julia> @be B_car($loc)
Benchmark: 1541 samples with 466 evaluations
min 61.315 ns (2 allocs: 64 bytes)
median 90.824 ns (2 allocs: 64 bytes)
mean 331.233 ns (2 allocs: 64 bytes, 0.06% gc time)
max 381.855 μs (2 allocs: 64 bytes, 99.87% gc time)
julia> @be A_car($loc)
Benchmark: 3217 samples with 475 evaluations
min 58.783 ns (2 allocs: 48 bytes)
median 60.764 ns (2 allocs: 48 bytes)
mean 61.516 ns (2 allocs: 48 bytes)
max 101.436 ns (2 allocs: 48 bytes)Non-uniform Cartesian interpolation
julia> @be B_car_nu($loc)
Benchmark: 3166 samples with 479 evaluations
min 58.355 ns (2 allocs: 64 bytes)
median 60.823 ns (2 allocs: 64 bytes)
mean 61.692 ns (2 allocs: 64 bytes)
max 105.273 ns (2 allocs: 64 bytes)
julia> @be A_car_nu($loc)
Benchmark: 3206 samples with 487 evaluations
min 57.725 ns (2 allocs: 48 bytes)
median 59.721 ns (2 allocs: 48 bytes)
mean 60.479 ns (2 allocs: 48 bytes)
max 109.076 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).
Mixed precision interpolation
Numerical field data from files is often stored in Float32. TestParticle supports constructing interpolators from Float32 data and ranges, which can then be queried with both Float32 and Float64 location vectors.
julia> @be itp_f32($loc_f32)
Benchmark: 3215 samples with 517 evaluations
min 54.530 ns (2 allocs: 64 bytes)
median 55.830 ns (2 allocs: 64 bytes)
mean 56.654 ns (2 allocs: 64 bytes)
max 126.497 ns (2 allocs: 64 bytes)
julia> @be itp_f32($loc_f64)
Benchmark: 2375 samples with 459 evaluations
min 61.880 ns (2 allocs: 64 bytes)
median 91.444 ns (2 allocs: 64 bytes)
mean 86.204 ns (2 allocs: 64 bytes)
max 726.710 ns (2 allocs: 64 bytes)Memory usage analysis
Large numerical field arrays can consume significant amounts of memory. It's important that interpolators are memory-efficient during both construction and storage.
For linear interpolation (order=1), construction is near zero-allocation because it creates a wrapper around a reinterpreted view of your existing array.
For higher-order interpolation (order = 3), FastInterpolations.jl provides two modes: OnTheFly() and PreCompute(). By default, OnTheFly() is used, which calculates interpolation coefficients during each query. This approach is memory-efficient as it does not require additional storage beyond the input data. Alternatively, PreCompute() precalculates and stores coefficients in an additional array of the same size, enabling faster
We can measure this difference using @be.
julia> # Order 1: Minimal allocations (Uses a view)
@be setup_mixed_precision_field(11, 1)
Benchmark: 1 sample with 1 evaluation
7.742 μs (8 allocs: 31.781 KiB)
julia> # Order 3: Minimal allocations (Uses a view)
@be setup_mixed_precision_field(11, 3)
Benchmark: 1365 samples with 5 evaluations
min 3.433 μs (14 allocs: 32.109 KiB)
median 4.713 μs (14 allocs: 32.109 KiB)
mean 14.303 μs (14 allocs: 32.109 KiB, 0.14% gc time)
max 7.291 ms (14 allocs: 32.109 KiB, 97.32% gc time)Comparing the ratios relative to the original array size illustrates the overhead:
julia> B = fill(0.0f0, 3, 11, 11, 11);
julia> size_B = Base.summarysize(B) # Original 4D field array size
16036
julia> size_itp1 = Base.summarysize(itp_f32) # Total size for order=1 (Essentially the input array size)
16196
julia> itp_f32_q = setup_mixed_precision_field(11, 3) # Total size for order=3
(::TestParticle.FieldInterpolator{FastInterpolations.HeteroInterpolantND{Float32, StaticArraysCore.SVector{3, Float32}, 3, Tuple{FastInterpolations._CachedRange{Float32}, FastInterpolations._CachedRange{Float32}, FastInterpolations._CachedRange{Float32}}, Tuple{FastInterpolations.ScalarSpacing{Float32}, FastInterpolations.ScalarSpacing{Float32}, FastInterpolations.ScalarSpacing{Float32}}, Tuple{FastInterpolations.CardinalInterp{Float64}, FastInterpolations.CardinalInterp{Float64}, FastInterpolations.CardinalInterp{Float64}}, Tuple{FillExtrap{StaticArraysCore.SVector{3, Float32}}, FillExtrap{StaticArraysCore.SVector{3, Float32}}, FillExtrap{StaticArraysCore.SVector{3, Float32}}}, Tuple{FastInterpolations.AutoSearch, FastInterpolations.AutoSearch, FastInterpolations.AutoSearch}, Array{StaticArraysCore.SVector{3, Float32}, 3}}}) (generic function with 2 methods)
julia> size_itp3 = Base.summarysize(itp_f32_q)
16220
julia> # Ratios relative to raw data
size_itp1 / size_B
1.0099775505113495
julia> size_itp3 / size_B
1.0114741830880518As a rule of thumb, linear interpolation and cubic interpolation with OnTheFly() coefficients have nearly zero memory overhead (ratio ≈ 1.0), as they both operate directly on the input data. When supported, cubic interpolation with PreCompute() coefficients increases the memory footprint by
On-the-fly vs Precomputed coefficients
Cubic interpolation (order = 3) requires high-order coefficients. By default, TestParticle uses OnTheFly() coefficients, which are calculated at query time. This saves memory but increases evaluation time. For maximum performance, you can use PreCompute(), which stores the coefficients in an additional array.
Status in v0.4.8
Support for PreCompute() with local Hermite cubic interpolation is currently under development and not yet available in FastInterpolations.jl v0.4.8.
julia> # Benchmark evaluation time
itp_fly = setup_mixed_precision_field(11, 3; coeffs = OnTheFly());
julia> # itp_pre = setup_mixed_precision_field(11, 3; coeffs = PreCompute()); # Not yet supported in v0.4.8
@be itp_fly($loc_f64)
Benchmark: 3261 samples with 46 evaluations
min 624.630 ns (2 allocs: 64 bytes)
median 639.652 ns (2 allocs: 64 bytes)
mean 647.557 ns (2 allocs: 64 bytes)
max 1.189 μs (2 allocs: 64 bytes)
julia> # Compare total object size
Base.summarysize(itp_fly)
16220As shown, OnTheFly() preserves memory efficiency while providing higher-order accuracy. Once available, PreCompute() will offer a faster alternative for memory-abundant systems.
Time-dependent field interpolation
For time-dependent fields, we can use LazyTimeInterpolator. It takes a list of time points and a loader function that returns a spatial interpolator for a given time index. The interpolator will linearly interpolate between the two nearest time points.
julia> @be B_td($loc, 0.5)
Benchmark: 3117 samples with 145 evaluations
min 197.469 ns (2 allocs: 64 bytes)
median 203.614 ns (2 allocs: 64 bytes)
mean 206.337 ns (2 allocs: 64 bytes)
max 378.090 ns (2 allocs: 64 bytes)Related API
TestParticle.build_interpolator Function
build_interpolator(gridtype, A, grids..., order::Int=1, bc=FillExtrap(NaN))
build_interpolator(A, grids..., order::Int=1, bc=FillExtrap(NaN))Return a function for interpolating field array A on the given grids.
Arguments
gridtype:CartesianGrid,RectilinearGridorStructuredGrid. Usually determined by the number of grids.A: field array. For vector field, the first dimension should be 3 if it's not an SVector wrapper.order::Int=1: order of interpolation in [0,1,3].bc=FillExtrap(NaN): boundary condition type fromFastInterpolations.jl.FillExtrap(NaN): Fill with NaN (default).ClampExtrap(): Clamp (flat extrapolation).WrapExtrap(): Exclusive periodic wrapping ().
coeffs=OnTheFly(): coefficient strategy for cubic interpolation (order=3). Default isOnTheFly().
Notes
- The input array
Amay be modified in-place for memory optimization.
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. The grid vectors must be sorted. 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 [0,1,3].bc=FillExtrap(NaN): boundary condition type fromFastInterpolations.jl.species=Proton: particle species.q=nothing: particle charge.m=nothing: particle mass.gridtype:CartesianGrid,RectilinearGrid,StructuredGrid.