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multifidelity

Multifidelity is an approach in computational science and engineering that combines information from models or data sources with different levels of accuracy and cost. The central idea is to use inexpensive, low-fidelity models to guide and accelerate the use of expensive, high-fidelity models, achieving accurate predictions with reduced computational expense.

Common techniques include multifidelity surrogate modeling, such as co-kriging or autoregressive models that relate high-fidelity outputs

Applications span aerospace, automotive, energy, and physical sciences. They are used in design optimization, uncertainty quantification,

Benefits include substantial cost savings and faster convergence, as long as fidelities are correlated and the

to
low-fidelity
ones
plus
a
correction
term.
Kennedy
and
O’Hagan
introduced
the
co-kriging
framework,
while
multifidelity
Monte
Carlo
methods
use
control
variates
across
fidelities
to
reduce
variance.
Other
methods
include
MFMC,
multi-fidelity
optimization,
and
Bayesian
calibration.
parameter
estimation,
and
machine
learning
where
simulations
or
experiments
are
costly.
In
practice,
a
workflow
may
build
a
hierarchy
of
models,
learn
a
statistical
relationship
between
fidelities,
and
progressively
sample
the
most
informative
points
across
levels.
discrepancy
between
levels
can
be
modeled.
Limitations
include
model
misspecification,
diminishing
returns
with
poorly
correlated
models,
and
added
methodological
complexity
or
overhead.