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pulseshaping

Pulseshaping is the design of the temporal envelope of transmitted pulses to control the spectral occupancy of a signal and to minimize intersymbol interference (ISI) in communication systems. In digital communications, information is carried by a sequence of symbols that are mapped to waveforms; the chosen pulse shape determines the signal bandwidth and how strongly adjacent symbols interfere with each other. The aim is to approach the Nyquist criterion for zero ISI, so that the combined response of the transmitter, channel, and receiver yields clean symbol sampling at the receiver.

Theoretical basis centers on ensuring that pulses spaced by the symbol interval T do not cause interference

Common pulse shapes include raised cosine (RC) and root raised cosine (RRC). The RC shape has a

Implementation typically uses finite impulse response (FIR) or equivalent filters in digital transceivers, with design choices

at
the
sampling
instants.
In
practice,
this
is
achieved
by
shaping
each
symbol
with
a
pulse
p(t)
whose
Fourier
spectrum
confines
energy
within
a
desired
bandwidth
while
satisfying
sampling
properties
that
cancel
ISI
at
symbol
times
when
combined
with
a
suitable
receiver
filter.
controllable
roll-off
factor
that
sets
excess
bandwidth
beyond
the
minimum
Nyquist
bandwidth.
The
RRC
shape
is
used
in
pairs
(
transmitter
and
receiver)
so
that
their
cascade
yields
a
raised
cosine
response,
providing
practical
zero-ISI
behavior
with
finite-length
filters.
Gaussian
pulse
shaping
is
used
in
some
modulation
schemes
(notably
in
GMSK)
for
its
good
spectral
efficiency,
though
it
does
not
achieve
ideal
zero-ISI
by
itself.
Sinc
pulses
are
the
theoretical
ideal
but
have
infinite
duration
and
are
impractical.
reflecting
trade-offs
between
bandwidth
efficiency,
out-of-band
emissions,
and
resilience
to
channel
distortion.
Pulseshaping
is
fundamental
in
many
domains,
including
wireless,
wired
digital
communications,
and
optical
systems.