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Normconserving

Normconserving is an expression used in numerical analysis and computational physics to describe methods or constructs that preserve a specified norm under discrete approximation or evolution. In numerical analysis, norm-conserving schemes are designed to maintain the norm of a solution, such as the L2 norm for time-dependent problems or the L1 norm for mass conservation, across time steps or spatial discretizations. This property supports stability and physical fidelity, and is achieved in various ways, including unitary time integrators for linear equations, and conservative discretizations for advection, diffusion, or wave propagation. Spectral and finite-difference methods are often formulated to conserve chosen norms or invariants.

In quantum chemistry and condensed matter physics, the term is widely used in the context of norm-conserving

Applications and trade-offs: norm-conserving methods tend to be robust and physically faithful but may impose stricter

pseudopotentials.
These
are
effective
core
potentials
that
reproduce,
outside
a
defined
core
region,
the
norm
(integrated
charge)
of
the
all-electron
valence
wavefunctions.
Developed
to
maintain
scattering
properties
and
transferability,
norm-conserving
pseudopotentials
enable
efficient
calculations
by
removing
core
electrons
while
preserving
physical
accuracy.
Notable
families
include
the
Troullier-Martins
and
Hamann-type
pseudopotentials;
alternatives
such
as
ultrasoft
pseudopotentials
and
projector
augmented-wave
methods
relax
the
norm
condition
for
efficiency.
construction
or
larger
basis
sets,
whereas
norm-relaxing
methods
can
offer
computational
savings
at
some
cost
to
strict
norm
preservation.