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resolutiondependency

Resolutiondependency is a property of a process in which its outputs vary with the resolution at which data are represented or processed. It is relevant whenever continuous phenomena are discretized into finite samples, pixels, grid cells, or similar representations. In practice, resolutiondependency means that changing the input or representation resolution can alter results, sometimes revealing or hiding features, artifacts, or biases that were not apparent at other scales.

Causes include discretization errors from approximating continuous equations, sampling and quantization effects, interpolation or resampling, and

Implications of resolutiondependency include the potential for non-convergent or misleading results if the resolution is insufficient.

Mitigation strategies encompass grid or parameter refinement in a controlled manner, convergence analysis and extrapolation (such

Resolutiondependency appears in diverse fields, including computational physics, CFD, climate modeling, computer graphics, GIS, and machine

aliasing
when
high-frequency
content
is
misrepresented
at
lower
resolution.
Boundary
treatments,
numerical
stability,
and
the
choice
of
algorithms
can
also
influence
how
strongly
results
depend
on
resolution.
It
motivates
the
use
of
resolution
studies
to
assess
reliability
and
to
quantify
how
errors
scale
with
resolution.
Analysts
often
seek
convergence
with
increasing
resolution
or
apply
corrections
to
account
for
residual
biases.
as
Richardson
extrapolation),
and
adaptive
methods
(for
example,
adaptive
mesh
refinement
or
multigrid
techniques).
In
imaging
and
rendering,
anti-aliasing,
upsampling
with
appropriate
filters,
or
multiresolution
techniques
can
reduce
undesirable
dependency.
In
data
visualization,
presenting
multiple
resolutions
or
using
scale-aware
representations
helps
prevent
misinterpretation.
learning.
Understanding
its
presence
and
controlling
its
effects
are
essential
for
producing
robust,
interpretable
results.