Home

dispersiekernel

Dispersiekernel, or dispersion kernel, is a function used to describe the spreading of a signal, wave, or probability distribution caused by dispersion in a medium or system. In physics and engineering, it is often the impulse response (or Green's function) of a dispersive linear time-invariant system. The kernel defines how a single impulse input is transformed into a broadened output by the medium’s frequency-dependent behavior, and sometimes by amplitude changes as well.

Mathematically, if x(t) is the input and y(t) is the output, y(t) equals the convolution of x

Dispersiekernels are used to model optical pulse propagation, seismic wave propagation, and other wave phenomena, as

Practically, a dispersiekernel is determined from material properties, experimental measurements, or theoretical dispersion relations, and is

See also: impulse response, Green's function, dispersion relation, kernel density estimation, diffusion kernel, deconvolution.

with
h,
where
h(t)
is
the
dispersiekernel.
In
the
frequency
domain,
Y(ω)
=
H(ω)X(ω)
with
H(ω)
=
|H(ω)|
e^{i
φ(ω)};
dispersion
arises
when
the
phase
φ(ω)
varies
nonlinearly
with
frequency,
causing
different
frequency
components
to
accumulate
different
delays
and
thus
temporal
or
spatial
broadening.
well
as
to
perform
deconvolution
or
smoothing
in
signal
processing.
In
statistics
or
data
analysis,
related
kernels
can
describe
spreading
of
mass
or
events
over
time
or
space,
though
the
term
is
more
common
in
physics
and
engineering
contexts.
often
computed
via
Fourier
methods
or
numerical
simulation.
Its
shape—width,
symmetry,
and
tails—governs
the
extent
and
character
of
the
dispersion.