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StatisticalMoments

DocTestSetup = quote
    using MultipleScattering
end

Here we are going to simulate the scattered wave for many different configurations of particles. We can then take the average and standard deviation (the moments) of the scattered wave. In statistical mechanics this process is called ensemble average.

Region and particles properties

First we choose the region to place particles and the receiver position:

using MultipleScattering
bottomleft = [0.0;-25.0]
topright = [50.0;25.0]
shape = Box([bottomleft, topright])
x = [-10.0,0.0]

# output


using Plots
plot(shape);
scatter!([x[1]],[x[2]], label="");
plot_shape = annotate!([(x[1], x[2] -2., "Receiver")])

Plot of shape and receiver

Next we fill this shape with a random (uniform distribution) configuration of particles:

volfrac = 0.05
radius = 1.0

particles = random_particles(Acoustic(2; ρ=0.0, c=0.0), Circle(radius);
        region_shape = shape,
        volume_fraction = volfrac,
        seed=2
);

length(particles)

# output
40

To see the position of the chosen particles:

plot(plot_shape)
plot!(particles);
plot!()

Plot particles

Scattering a plane-wave from these particles

ωs = LinRange(0.01,1.0,100)
plane_wave = plane_source(Acoustic(1.0, 1.0, 2);
    direction = [1.0,0.0], position = x);
plot(run(particles, plane_wave,x,ωs))

The moments of the scattered wave

Now we will do simulations for particles placed in many different configurations and take the moments:

results = map(1:20) do i
    particles = random_particles(Acoustic(2; ρ=0.0, c=0.0), Circle(radius);
            region_shape = shape,
            volume_fraction = volfrac,
            seed=i
    )
    run(FrequencySimulation(particles, plane_wave), x, ωs)
end

# package Plots changed it's argument, the below no longer works..
# num_moments = 3
# plot(results; field_apply = real, num_moments = num_moments)
# plot!(xlabel="wavenumbers", title="Moments of the real part")

Moments of the real part the scattered waves

Calculate the moments of the scattered wave in time

time_simulations = frequency_to_time.(results)
time_simulations[1].t # the time_arr chosen will be based on the discrete Fourier transform of simulations[1].k_arr
# real_time_moments = StatisticalMoments(time_simulations; response_apply=real) # moments of the real part
# plot(real_time_moments,xlims=(0,300));
# plot!(xlabel="time", title="Moments of the real part of the time wave")

Moments of the real part the scattered waves in time

References

A. L. Gower, R. M. Gower, J. Deakin, W. J. Parnell, I. D. Abrahams, Learning about random media from near-surface backscattering: using machine learning to measure particle size and concentration, arXiv preprint, (2018)1801.05490