Difference between revisions of "Inductance" - New World Encyclopedia

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An electric current ${\displaystyle i}$ flowing around a circuit produces a magnetic field and hence a magnetic flux ${\displaystyle \Phi }$ through the circuit. The ratio of the magnetic flux to the current is called the inductance, or more accurately self-inductance of the circuit. The term was coined by Oliver Heaviside in February 1886. It is customary to use the symbol ${\displaystyle L}$ for inductance, possibly in honor of the physicist Heinrich Lenz. The quantitative definition of the inductance is therefore

${\displaystyle L={\frac {\Phi }{i}}.}$

It follows that the SI units for inductance are webers per ampere. In honor of Joseph Henry, the unit of inductance has been given the name henry (H): 1H = 1Wb/A.

In the above definition, the magnetic flux ${\displaystyle \Phi }$ is that caused by the current flowing through the circuit concerned. There may, however, be contributions from other circuits. Consider for example two circuits ${\displaystyle C_{1}}$, ${\displaystyle C_{2}}$, carrying the currents ${\displaystyle i_{1}}$, ${\displaystyle i_{2}}$. The magnetic fluxes ${\displaystyle \Phi _{1}}$ and ${\displaystyle \Phi _{2}}$ in ${\displaystyle C_{1}}$ and ${\displaystyle C_{2}}$, respectively, are given by

${\displaystyle \displaystyle \Phi _{1}=L_{11}i_{1}+L_{12}i_{2},}$

${\displaystyle \displaystyle \Phi _{2}=L_{21}i_{1}+L_{22}i_{2}.}$

According to the above definition, ${\displaystyle L_{11}}$ an ${\displaystyle L_{22}}$ are the self-inductances of ${\displaystyle C_{1}}$ and ${\displaystyle C_{2}}$, respectively. It can be shown (see below) that the other two coefficients are equal: ${\displaystyle L_{12}=L_{21}=M}$, where ${\displaystyle M}$ is called the mutual inductance of the pair or circuits.

Inductance of a solenoid

A solenoid is a long, thin coil, i.e. a coil whose length is much greater than the diameter. Under these conditions, and without any magnetic material used, the magnetic flux density ${\displaystyle B}$ within the coil is practically constant and is given by

${\displaystyle \displaystyle B=\mu _{0}Ni/l}$

where ${\displaystyle \mu _{0}}$ is the permeability of free space (4π × 10^-7 H/m), ${\displaystyle N}$ the number of turns, ${\displaystyle i}$ the current and ${\displaystyle l}$ the length of the coil. Ignoring end effects the magnetic flux through the coil is obtained by multiplying the flux density ${\displaystyle B}$ by the cross-section area ${\displaystyle A}$ and the number of turns ${\displaystyle N}$:

${\displaystyle \displaystyle \Phi =\mu _{0}N^{2}iA/l,}$

from which it follows that the inductance of a solenoid is given by:

${\displaystyle \displaystyle L=\mu _{0}N^{2}A/l.}$

This, and the inductance of more complicated shapes, can be derived from Maxwell's equations. For rigid air-core coils, inductance is a function of coil geometry and number of turns, and is independent of current.

Similar analysis applies to a solenoid with a magnetic core, but only if the length of the coil is much greater than the product of the relative permeability of the magnetic core and the diameter. That limits the simple analysis to low-permeability cores, or extremely long thin solenoids. Although rarely useful, the equations are,

${\displaystyle \displaystyle B=\mu _{0}\mu _{r}Ni/l}$

where ${\displaystyle \mu _{r}}$ the relative permeability of the material within the solenoid,

${\displaystyle \displaystyle \Phi =\mu _{0}\mu _{r}N^{2}iA/l,}$

from which it follows that the inductance of a solenoid is given by:

${\displaystyle \displaystyle L=\mu _{0}\mu _{r}N^{2}A/l.}$

Note that since the permeability of ferromagnetic materials changes with applied magnetic flux, the inductance of a coil with a ferromagnetic core will generally vary with current.

Inductance of a circular loop

The inductance of a circular conductive loop made of a circular conductor can be determined using

${\displaystyle L={r\mu _{0}\mu _{r}\left(\ln {\frac {8r}{a}}-2+Y\right)}}$

where

μ₀ and μ_r are the same as above

r is the radius of the loop

a is the radius of the conductor

Y is a constant. Y=0 when the current flows in the surface of the wire (skin effect), Y=1/4 when the current is homogeneous across the wire.

Inductance for any shaped loop

Consider a current loop ${\displaystyle \delta S}$ with current i(t). According to Biot-Savart law, current i(t) sets up a magnetic flux density at r:

${\displaystyle \mathbf {B} (\mathbf {r} ,t)={\frac {\mu _{0}\mu _{r}i(t)}{4\pi }}\int _{\delta S}{\frac {d\mathbf {l} \times \mathbf {\hat {r}} }{r^{2}}}}$

Now magnetic flux through the surface S the loop encircles is:

${\displaystyle \Phi (t)=\int _{S}\mathbf {B} (\mathbf {r} ,t)\cdot d\mathbf {A} ={\frac {\mu _{0}\mu _{r}i(t)}{4\pi }}\int _{S}\int _{\delta S}{\frac {d\mathbf {l} \times \mathbf {\hat {r}} }{r^{2}}}\cdot d\mathbf {A} =Li(t)}$

From where we get the expression for inductance of the current loop:

${\displaystyle L={\frac {\mu _{0}\mu _{r}}{4\pi }}\int _{S}\int _{\delta S}{\frac {d\mathbf {l} \times \mathbf {\hat {r}} }{r^{2}}}\cdot d\mathbf {A} }$

where

μ₀ and μ_r are the same as above

${\displaystyle d\mathbf {l} }$ is the differential length vector of the current loop element

${\displaystyle \mathbf {\hat {r}} }$ is the unit displacement vector from the current element to the field point r

${\displaystyle r}$ is the distance from the current element to the field point r

${\displaystyle d\mathbf {A} }$ differential vector element of surface area A, with infinitesimally small magnitude and direction normal to surface S

As we see here, the geometry and material properties (if material properties are same in surface ${\displaystyle S}$ and the material is linear) of the current loop can be expressed with single scalar quantity L.

Inductance of a coaxial line

Let the inner conductor have radius ${\displaystyle r_{i}}$ and permeability ${\displaystyle \mu _{i}}$, let the dielectric between the inner and outer conductor have permeability ${\displaystyle \mu _{d}}$, and let the outer conductor have inner radius ${\displaystyle r_{o1}}$, outer radius ${\displaystyle r_{o2}}$, and permeability ${\displaystyle \mu _{o}}$. Assume that a DC current ${\displaystyle I}$ flows in opposite directions in the two conductors, with uniform current density. The magnetic field generated by these currents points in the axial direction and is a function of radius ${\displaystyle r}$; it can be computed using Ampère's Law:

${\displaystyle 0\leq r\leq r_{i}:B(r)={\frac {\mu _{i}Ir}{2\pi r_{i}^{2}}}}$

${\displaystyle r_{i}\leq r\leq r_{o1}:B(r)={\frac {\mu _{d}I}{2\pi r}}}$

${\displaystyle r_{o1}\leq r\leq r_{o2}:B(r)={\frac {\mu _{o}I}{2\pi r}}\left({\frac {r_{o2}^{2}-r^{2}}{r_{o2}^{2}-r_{o1}^{2}}}\right)}$

The flux per unit length ${\displaystyle l}$ in the region between the conductors can be computed by drawing a surface with surface normal pointing axially:

${\displaystyle {\frac {d\phi _{d}}{dl}}=\int _{r_{i}}^{r_{o1}}B(r)dr={\frac {\mu _{d}I}{2\pi }}\ln {\frac {r_{o1}}{r_{i}}}}$

Inside the conductors, L can be computed by equating the energy stored in an inductor, ${\displaystyle {\frac {1}{2}}LI^{2}}$, with the energy stored in the magnetic field:

${\displaystyle {\frac {1}{2}}LI^{2}=\int _{V}{\frac {B^{2}}{2\mu }}dV}$

For a cylindrical geometry with no ${\displaystyle l}$ dependence, the energy per unit length is

${\displaystyle {\frac {1}{2}}L'I^{2}=\int _{r_{1}}^{r_{2}}{\frac {B^{2}}{2\mu }}2\pi r~dr}$

where ${\displaystyle L'}$ is the inductance per unit length. For the inner conductor, the integral on the right-hand-side is ${\displaystyle {\frac {\mu _{i}I^{2}}{16\pi }}}$; for the outer conductor it is ${\displaystyle {\frac {\mu _{o}I^{2}}{4\pi }}\left({\frac {r_{o2}^{2}}{r_{o2}^{2}-r_{o1}^{2}}}\right)^{2}\ln {\frac {r_{o2}}{r_{o1}}}-{\frac {\mu _{o}I^{2}}{8\pi }}\left({\frac {r_{o2}^{2}}{r_{o2}^{2}-r_{o1}^{2}}}\right)-{\frac {\mu _{o}I^{2}}{16\pi }}}$

Solving for ${\displaystyle L'}$ and summing the terms for each region together gives a total inductance per unit length of:

${\displaystyle L'={\frac {\mu _{i}}{8\pi }}+{\frac {\mu _{d}}{2\pi }}\ln {\frac {r_{o1}}{r_{i}}}+{\frac {\mu _{o}}{2\pi }}\left({\frac {r_{o2}^{2}}{r_{o2}^{2}-r_{o1}^{2}}}\right)^{2}\ln {\frac {r_{o2}}{r_{o1}}}-{\frac {\mu _{o}}{4\pi }}\left({\frac {r_{o2}^{2}}{r_{o2}^{2}-r_{o1}^{2}}}\right)-{\frac {\mu _{o}}{8\pi }}}$

However, for a typical coaxial line application we are interested in passing (non-DC) signals at frequencies for which the resistive skin effect cannot be neglected. In most cases, the inner and outer conductor terms are negligible, in which case one may approximate

${\displaystyle {\frac {dL}{dl}}\approx {\frac {\mu _{d}}{2\pi }}\ln {\frac {r_{o1}}{r_{i}}}}$

Properties of inductance

The equation relating inductance and flux linkages can be rearranged as follows:

${\displaystyle \lambda =Li\,}$

Taking the time derivative of both sides of the equation yields:

${\displaystyle {\frac {d\lambda }{dt}}=L{\frac {di}{dt}}+i{\frac {dL}{dt}}\,}$

In most physical cases, the inductance is constant with time and so

${\displaystyle {\frac {d\lambda }{dt}}=L{\frac {di}{dt}}}$

By Faraday's Law of Induction we have:

${\displaystyle {\frac {d\lambda }{dt}}=-{\mathcal {E}}=v}$

where ${\displaystyle {\mathcal {E}}}$ is the Electromotive force (emf) and ${\displaystyle v}$ is the induced voltage. Note that the emf is opposite to the induced voltage. Thus:

${\displaystyle {\frac {di}{dt}}={\frac {v}{L}}}$

or

${\displaystyle i(t)={\frac {1}{L}}\int _{0}^{t}v(\tau )d\tau +i(0)}$

These equations together state that, for a steady applied voltage v, the current changes in a linear manner, at a rate proportional to the applied voltage, but inversely proportional to the inductance. Conversely, if the current through the inductor is changing at a constant rate, the induced voltage is constant.

The effect of inductance can be understood using a single loop of wire as an example. If a voltage is suddenly applied between the ends of the loop of wire, the current must change from zero to non-zero. However, a non-zero current induces a magnetic field by Ampère's law. This change in the magnetic field induces an emf that is in the opposite direction of the change in current. The strength of this emf is proportional to the change in current and the inductance. When these opposing forces are in balance, the result is a current that increases linearly with time where the rate of this change is determined by the applied voltage and the inductance.

Phasor circuit analysis and impedance

Using phasors, the equivalent impedance of an inductance is given by:

${\displaystyle Z_{L}=V/I=jL\omega \,}$

where

${\displaystyle X_{L}=L\omega \,}$ is the inductive reactance,

${\displaystyle \omega =2\pi f\,}$ is the angular frequency,

L is the inductance,

f is the frequency, and

j is the imaginary unit.

Coupled inductors

When the magnetic flux produced by an inductor links another inductor, these inductors are said to be coupled. Coupling is often undesired but in many cases, this coupling is intentional and is the basis of the transformer. When inductors are coupled, there exists a mutual inductance that relates the current in one inductor to the flux linkage in the other inductor. Thus, there are three inductances defined for coupled inductors:

${\displaystyle L_{11}}$ - the self inductance of inductor 1

${\displaystyle L_{22}}$ - the self inductance of inductor 2

${\displaystyle L_{12}=L_{21}}$ - the mutual inductance associated with both inductors

When either side of the transformer is a tuned circuit, the amount of mutual inductance between the two windings determines the shape of the frequency response curve. Although no boundaries are defined, this is often referred to as loose-, critical-, and over-coupling. When two tuned circuits are loosely coupled through mutual inductance, the bandwidth will be narrow. As the amount of mutual inductance increases, the bandwidth continues to grow. When the mutual inductance is increased beyond a critical point, the peak in the response curve begins to drop, and the center frequency will be attenuated more strongly than its direct sidebands. This is known as overcoupling.

Vector field theory derivations

Mutual inductance

The circuit diagram representation of mutually inducting inductors.

The two vertical lines between the inductors indicate a solid core that the wires of the inductor are wrapped around. "n:m" shows the ratio between the number of windings of the left inductor to windings of the right inductor. This picture also shows the dot convention.

Mutual inductance is the concept that the current through one inductor can induce a voltage in another nearby inductor. It is important as the mechanism by which transformers work, but it can also cause unwanted coupling between conductors in a circuit.

The mutual inductance, M, is also a measure of the coupling between two inductors. The mutual inductance by circuit i on circuit j is given by the double integral Neumann formula

${\displaystyle M_{ij}={\frac {\mu _{0}}{4\pi }}\oint _{C_{i}}\oint _{C_{j}}{\frac {\mathbf {ds} _{i}\cdot \mathbf {ds} _{j}}{|\mathbf {R} _{ij}|}}}$

See a derivation of this equation.

The mutual inductance also has the relationship:

${\displaystyle M_{21}=N_{1}N_{2}P_{21}\!}$

where

${\displaystyle M_{21}}$ is the mutual inductance, and the subscript specifies the relationship of the voltage induced in coil 2 to the current in coil 1.

${\displaystyle N_{1}}$ is the number of turns in coil 1,

${\displaystyle N_{2}}$ is the number of turns in coil 2,

${\displaystyle P_{21}}$ is the permeance of the space occupied by the flux.

The mutual inductance also has a relationship with the coefficient of coupling. The coefficient of coupling is always between 1 and 0, and is a convenient way to specify the relationship between a certain orientation of inductor with arbitrary inductance:

${\displaystyle M=k{\sqrt {L_{1}L_{2}}}\!}$

where

k is the coefficient of coupling and 0 ≤ k ≤ 1,

${\displaystyle L_{1}}$ is the inductance of the first coil, and

${\displaystyle L_{2}}$ is the inductance of the second coil.

Once this mutual inductance factor M is determined, it can be used to predict the behavior of a circuit:

${\displaystyle V=L_{1}{\frac {dI_{1}}{dt}}+M{\frac {dI_{2}}{dt}}}$

where

V is the voltage across the inductor of interest,

${\displaystyle L_{1}}$ is the inductance of the inductor of interest,

${\displaystyle dI_{1}/dt}$ is the derivative, with respect to time, of the current through the inductor of interest,

${\displaystyle M}$ is the mutual inductance and

${\displaystyle dI_{2}/dt}$ is the derivative, with respect to time, of the current through the inductor that is coupled to the first inductor.

When one inductor is closely coupled to another inductor through mutual inductance, such as in a transformer, the voltages, currents, and number of turns can be related in the following way:

${\displaystyle V_{s}=V_{p}{\frac {N_{s}}{N_{p}}}}$

where

${\displaystyle V_{s}}$ is the voltage across the secondary inductor,

${\displaystyle V_{p}}$ is the voltage across the primary inductor (the one connected to a power source),

${\displaystyle N_{s}}$ is the number of turns in the secondary inductor, and

${\displaystyle N_{p}}$ is the number of turns in the primary inductor.

Conversely the current:

${\displaystyle I_{s}=I_{p}{\frac {N_{p}}{N_{s}}}}$

where

${\displaystyle I_{s}}$ is the current through the secondary inductor,

${\displaystyle I_{p}}$ is the current through the primary inductor (the one connected to a power source),

${\displaystyle N_{s}}$ is the number of turns in the secondary inductor, and

${\displaystyle N_{p}}$ is the number of turns in the primary inductor.

Note that the power through one inductor is the same as the power through the other. Also note that these equations don't work if both transformers are forced (with power sources).

Self-inductance

Self-inductance, denoted L, is the usual inductance one talks about with an inductor. Formally the self-inductance of a wire loop would be given by the above equation with i =j. However, ${\displaystyle 1/|\mathbf {R} |}$ now gets singular and the finite radius ${\displaystyle a}$ and the distribution of the current in the wire must be taken into account. There remain the contribution from the integral over all points where ${\displaystyle |\mathbf {R} |\geq a/2}$ and a correction term,

${\displaystyle M_{ij}=M_{jj}=L_{jj}=L_{j}=L=\left({\frac {\mu _{0}}{4\pi }}\oint _{C}\oint _{C'}{\frac {\mathbf {ds} \cdot \mathbf {ds} '}{|\mathbf {R} |}}\right)_{|\mathbf {R} |\geq a/2}+{\frac {\mu _{0}}{2\pi }}lY}$

Here ${\displaystyle a}$ and ${\displaystyle l}$ denote radius and length of the wire, and ${\displaystyle Y}$ is a constant that depends on the distribution of the current in the wire: ${\displaystyle Y=0}$ when the current flows in the surface of the wire (skin effect), ${\displaystyle Y=1/4}$ when the current is homogeneous across the wire. Here is a derivation of this equation.

Physically, the self-inductance of a circuit represents the back-emf described by Faraday's law of induction.

Usage

The flux ${\displaystyle \Phi _{i}\ \!}$ through the i-th circuit in a set is given by:

${\displaystyle \Phi _{i}=\sum _{j}M_{ij}I_{j}=L_{i}I_{i}+\sum _{j\neq i}M_{ij}I_{j}\,}$

so that the induced emf, ${\displaystyle {\mathcal {E}}}$, of a specific circuit, i, in any given set can be given directly by:

${\displaystyle E=-{\frac {d\Phi _{i}}{dt}}=-{\frac {d}{dt}}\left(L_{i}I_{i}+\sum _{j\neq i}M_{ij}I_{j}\right)=-\left({\frac {dL_{i}}{dt}}I_{i}+{\frac {dI_{i}}{dt}}L_{i}\right)-\sum _{j\neq i}\left({\frac {dM_{ij}}{dt}}I_{j}+{\frac {dI_{j}}{dt}}M_{ij}\right)}$

See also

• Electromagnetic induction
• Inductor
• Dot convention
• Alternating current
• Electricity
• Gyrator
• RLC circuit
• RL circuit
• LC circuit
• Leakage inductance
• SI electromagnetism units
• Eddy current
• Transformer

References

ISBN links support NWE through referral fees

• Grover, Frederick W. 2004. Inductance Calculations. Mineola, NY: Dover Publications. ISBN 0486495779.
• Griffiths, David J. 1998. Introduction to Electrodynamics (3rd ed.). Upper Saddle River, NJ: Prentice Hall. ISBN 0-13-805326-X
• Wangsness, Roald K. 1986. Electromagnetic Fields. Hoboken, NJ: Wiley. ISBN 0-471-81186-6.
• Hughes, Edward. 2002. Electrical & Electronic Technology (8th ed.). Upper Saddle River, NJ: Prentice Hall. ISBN 0-582-40519-X.
• Küpfmüller K. 1973. Einführung in die theoretische Elektrotechnik. Berlin, DE: Springer-Verlag. ISBN 3540060219.
• Heaviside O. 1892. Electrical Papers. New York, NY: Macmillan.