Home

Smallsignal

Small-signal analysis is a method in electronics used to analyze the linear response of circuits that contain nonlinear active devices by linearizing them around a chosen operating point, or Q-point. It uses incremental or small-signal parameters to describe how small input perturbations produce output changes.

The approach treats capacitors, resistors, inductors, and linearized models as linear elements and relies on superposition

In a bipolar junction transistor (BJT), the common small-signal model is the hybrid-pi or T-model, characterized

Small-signal analysis yields transfer functions, input and output impedances, gain, phase response, and overall frequency response.

Applications are widespread, including the design and analysis of amplifiers, filters, and RF circuits, and are

and
phasor
techniques
for
sinusoidal
inputs.
The
DC
operating
point
is
determined
by
the
bias
network,
and
once
fixed,
the
circuit
is
analyzed
in
the
frequency
domain
to
study
how
signals
of
different
frequencies
are
amplified
or
attenuated.
by
r_pi
between
base
and
emitter,
a
gm*v_pi
current
source
from
collector
to
emitter,
and
ro
as
the
output
resistance.
For
a
MOSFET,
the
small-signal
model
includes
a
transconductance
gm*v_gs,
an
output
resistance
ro,
and
parasitic
capacitances
between
terminals
(Cgs,
Cgd,
etc.).
These
models
approximate
the
device
behavior
for
small
perturbations
around
the
bias
point.
Coupling
and
bypass
capacitors,
as
well
as
source
and
load
impedances,
shape
the
circuit’s
bandwidth
and
impedance
seen
by
signals.
commonly
supported
by
circuit
simulators
performing
AC
analysis.
Limitations
include
the
restriction
to
small
perturbations
around
the
Q-point;
large-signal
or
transient
behavior,
bias
shifts,
and
temperature
effects
are
not
captured
by
the
linear
small-signal
models.