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microbarometers

A microbarometer is a compact pressure sensor designed to measure ambient atmospheric pressure, typically using MEMS (microelectromechanical systems) technology. These devices are characterized by their small size, low power consumption, and the ability to integrate directly with electronic systems in smartphones, wearables, drones, and other portable instruments. Microbarometers can measure absolute pressure relative to a vacuum, or be configured as gauge or differential sensors.

Most microbarometers rely on a microfabricated diaphragm whose deflection in response to pressure changes is detected

Performance characteristics vary with design, but microbarometers are generally designed to resolve small pressure changes with

Applications span consumer electronics (smartphones, wearables), navigation and altitude sensing in drones and vehicles, and miniature

by
an
electrical
readout.
The
common
sensing
principles
are
capacitive,
piezoresistive,
and
resonant.
In
capacitive
MEMS
barometers,
pressure-induced
diaphragm
movement
changes
the
capacitance
between
the
diaphragm
and
a
fixed
electrode.
Piezoresistive
devices
detect
strain
in
the
diaphragm
or
a
bridge
circuit,
while
resonant
devices
monitor
shifts
in
a
resonant
frequency
caused
by
pressure.
Some
devices
use
optical
or
other
transduction
methods,
but
capacitive
and
resonant
MEMS
are
the
prevailing
approaches
for
mainstream
microbarometers.
fast
response
times
and
to
operate
over
the
range
of
roughly
300
to
1100
hPa
to
cover
typical
weather
and
altitude
scenarios.
They
often
exhibit
sensitivity
to
temperature
and
long-term
drift,
requiring
calibration
and
temperature
compensation
for
precise
measurements
in
meteorological
or
scientific
use.
meteorological
or
research
instruments.
The
main
advantages
are
small
size,
low
cost,
and
low
power,
while
limitations
include
temperature
sensitivity,
drift,
and
sometimes
lower
absolute
accuracy
compared
with
larger,
lab-grade
sensors.