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coarseWDM

CoarseWDM, short for coarse wavelength-division multiplexing, is a form of wavelength-division multiplexing used in optical fiber networks that carries multiple data streams on separate, widely spaced wavelengths. It aims to simplify hardware and reduce cost by using broader channel spacing and more tolerant filtering than dense WDM approaches. In many contexts, coarseWDM is effectively synonymous with the commonly deployed coarse WDM (CWDM) technology.

Technically, coarseWDM relies on a relatively wide wavelength grid. Typical channel spacings are around 20 nanometers,

Implementation generally involves point-to-point links or small-mesh topologies using standard optical transceivers compatible with CWDM grids.

Advantages of coarseWDM include lower capital and operating costs, reduced engineering and maintenance complexity, and greater

and
standard
CWDM
wavelengths
span
roughly
from
1271
to
1611
nanometers,
allowing
up
to
about
18
channels
in
a
single
fiber.
The
wide
spacing
relaxes
the
precision
requirements
for
lasers,
filters,
and
temperature
stabilization,
enabling
the
use
of
simpler,
lower-cost
transceivers
and
components.
Because
of
this,
coarseWDM
is
often
favored
for
metro
and
regional
networks
where
cost
and
simplicity
are
prioritized
over
maximum
channel
count.
The
approach
supports
uncooled
laser
diodes
and
non-narrowband
filters,
contributing
to
lower
equipment
complexity
and
maintenance.
It
is
commonly
deployed
in
access
and
metropolitan
networks,
where
reach
is
moderate
and
the
emphasis
is
on
economical
scalability.
tolerance
to
environmental
variations.
Limitations
center
on
spectral
efficiency
and
capacity:
fewer
channels
are
available
than
in
dense
WDM
systems,
and
network
scalability
can
be
constrained
by
the
fixed
channel
grid
and
potential
crosstalk
if
not
properly
managed.
It
is
most
suitable
when
network
size,
budget,
and
simplicity
outweigh
the
need
for
extremely
high
throughput.