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diskretisering

Diskretisering, or discretization, is the process of transforming a continuous mathematical model into a discrete one suitable for computation. It replaces continuous domains, variables, and operators with a finite set of points and algebraic relations. Discretization can be applied in time, space, or both, and it is a central step in numerical methods for solving differential equations and dynamic systems.

Spatial discretization replaces a continuum with a mesh or grid. Common methods include finite difference (regular

Key concerns are discretization error, stability, and convergence. Truncation error arises from approximating derivatives or integrals.

grids),
finite
element
(unstructured
meshes
with
variational
formulation),
finite
volume
(conserving
fluxes
across
control
volumes),
and
spectral
methods
(global
basis
functions).
Temporal
discretization
replaces
continuous
time
with
a
sequence
of
time
steps,
using
explicit
or
implicit
schemes
such
as
Euler,
Runge–Kutta,
or
backward
differentiation
formulas.
Often
both
dimensions
are
discretized,
yielding
a
system
of
algebraic
equations.
Stability
conditions
(for
example
CFL
conditions
in
hyperbolic
problems)
determine
whether
errors
grow
or
decay.
Consistency
and
convergence
describe
how
the
discrete
solution
approaches
the
continuous
solution
as
the
mesh
size
or
time
step
decreases.
Applications
span
fluid
dynamics,
heat
conduction,
structural
mechanics,
electromagnetism,
and
image
processing.
Choosing
an
appropriate
discretization
involves
trade-offs
between
accuracy,
computational
cost,
and
problem
features
such
as
irregular
geometry
or
sharp
gradients.
Adaptive
mesh
refinement
and
error
estimation
are
common
tools
to
improve
efficiency.