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inductances

Inductance is a property of electrical conductors and components that causes an electromotive force to be induced in proportion to the rate of change of current through them. It is measured in henries (H). An inductor is a component designed to provide inductance, typically consisting of a coil of wire that creates a magnetic field when current passes through it.

The defining relationships are based on flux linkage. The inductance L is equal to the flux linkage

Inductance depends on geometry and magnetic material. For a long solenoid with a core of permeability μ,

Inductors have parasitics that affect high-frequency behavior, such as equivalent series resistance (ESR), equivalent series inductance

per
unit
current,
L
=
λ
/
I,
where
λ
=
NΦ
is
the
total
flux
linkage
(N
is
the
number
of
turns
and
Φ
is
the
magnetic
flux
in
each
turn).
In
a
simple
self-inductance
scenario,
the
voltage
across
the
inductor
satisfies
v
=
L
di/dt.
When
two
coils
are
magnetically
linked,
mutual
inductance
M
describes
the
induced
voltage
in
one
coil
due
to
the
current
in
the
other:
v1
=
M
di2/dt
and
v2
=
M
di1/dt.
The
coupling
coefficient
k,
ranging
from
0
to
1,
relates
M
to
the
self-inductances
L1
and
L2
via
M
=
k
sqrt(L1
L2).
L
=
μ
N^2
A
/
l,
where
A
is
cross-sectional
area
and
l
is
length.
Materials
range
from
air
to
ferrites
and
laminated
or
powdered
iron;
cores
affect
saturation
and
losses.
Energy
stored
in
an
inductor
is
E
=
(1/2)
L
I^2.
(ESL),
and
a
self-resonant
frequency
where
parasitic
capacitance
dominates.
Applications
include
filters,
chokes
to
block
AC
or
noise,
energy
storage
in
power
supplies,
and
transformers
that
rely
on
mutual
inductance
to
transfer
energy
between
windings.