Magnetic complex reluctance (

SI Unit The International System of Units, known by the international abbreviation SI in all languages and sometimes Pleonasm#Acronyms and initialisms, pleonastically as the SI system, is the modern form of the metric system and the world's most wid ...

: H⁻¹) is a measurement of a passive

magnetic circuit A magnetic circuit is made up of one or more closed loop paths containing a magnetic flux. The flux is usually generated by permanent magnets or electromagnets and confined to the path by magnetic cores consisting of ferromagnetic materials li ...

(or element within that circuit) dependent on sinusoidal magnetomotive force (

: At· Wb⁻¹) and sinusoidal magnetic flux (

: T· m²), and this is determined by deriving the ratio of their complex ''effective'' amplitudes. ef. 1-3

Z_\mu = \frac = \frac = z_\mu e^

As seen above, magnetic complex reluctance is a phasor represented as ''uppercase Z mu'' where: *

\dot N

and

\dot _m

represent the magnetomotive force (complex effective amplitude) *

\dot \Phi

and

\dot _m

represent the magnetic flux (complex effective amplitude) *

z_\mu

, ''lowercase z mu'', is the real part of magnetic complex reluctance The "lossless"

magnetic reluctance Magnetic reluctance, or magnetic resistance, is a concept used in the analysis of magnetic circuits. It is defined as the ratio of magnetomotive force (mmf) to magnetic flux. It represents the opposition to magnetic flux, and depends on the geom ...

, ''lowercase z mu'', is equal to the absolute value (modulus) of the magnetic complex reluctance. The argument distinguishing the "lossy" magnetic complex reluctance from the "lossless" magnetic reluctance is equal to the natural number

e

raised to a power equal to:

j\phi = j\left(\beta - \alpha\right)

Where: *

j

is the imaginary number *

\beta

is the phase of the magnetomotive force *

\alpha

is the phase of the magnetic flux *

\phi

is the phase difference The "lossy" magnetic complex reluctance represents a magnetic circuit element's resistance to not only magnetic flux but also to ''changes'' in magnetic flux. When applied to harmonic regimes, this formality is similar to

Ohm's Law Ohm's law states that the current through a conductor between two points is directly proportional to the voltage across the two points. Introducing the constant of proportionality, the resistance, one arrives at the usual mathematical equatio ...

in ideal AC circuits. In magnetic circuits, magnetic complex reluctance is equal to:

Z_\mu = \frac \frac

Where: *

l

is the length of the circuit element *

S

is the cross-section of the circuit element *

\dot  \mu_0

is the complex magnetic permeability

References

*Bull B. K. ''The Principles of Theory and Calculation of the Magnetic Circuits''. – M.-L.: Energy, 1964, 464 p. (In Russian). *Arkadiew W. Eine ''Theorie des elektromagnetischen Feldes in den ferromagnetischen Metallen''. – Phys. Zs., H. 14, No 19, 1913, S. 928–934. * Küpfmüller K. ''Einführung in die theoretische Elektrotechnik'', Springer-Verlag, 1959. {{Refend Magnetic circuits Electrical analogies