Dielectric complex reluctance is a scalar measurement of a passive dielectric circuit (or element within that circuit) dependent on sinusoidal

voltage Voltage, also known as electric pressure, electric tension, or (electric) potential difference, is the difference in electric potential between two points. In a static electric field, it corresponds to the work needed per unit of charge t ...

and sinusoidal electric induction flux, and this is determined by deriving the ratio of their complex ''effective'' amplitudes. The units of dielectric complex reluctance are

F^

(inverse Farads - see Daraf) ef. 1-3 :

Z_\epsilon = \frac = \frac = z_\epsilon e^

As seen above, dielectric complex reluctance is a phasor represented as ''uppercase Z epsilon'' where: :

\dot U

and

\dot _m

represent the voltage (complex effective amplitude) :

\dot Q

and

\dot _m

represent the electric induction flux (complex effective amplitude) :

z_\epsilon

, ''lowercase z epsilon'', is the real part of dielectric reluctance The "lossless"

dielectric reluctance Dielectric reluctance is a scalar measurement of a passive dielectric circuit (or element within that circuit) dependent on voltage and electric induction flux, and this is determined by deriving the ratio of their amplitudes. The units of dielectr ...

, ''lowercase z epsilon'', is equal to the absolute value (modulus) of the dielectric complex reluctance. The argument distinguishing the "lossy" dielectric complex reluctance from the "lossless" dielectric 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 unit The imaginary unit or unit imaginary number () is a solution to the quadratic equation x^2+1=0. Although there is no real number with this property, can be used to extend the real numbers to what are called complex numbers, using addition a ...

\beta

is the phase of voltage *

\alpha

is the phase of electric induction flux *

\phi

is the phase difference The "lossy" dielectric complex reluctance represents a dielectric circuit element's resistance to not only electric induction flux but also to ''changes'' in electric induction 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 dielectric circuits, a dielectric material has a dielectric complex reluctance equal to: :

Z_\epsilon = \frac \frac

Where: *

l

is the length of the circuit element *

S

is the cross-section of the circuit element *

\dot {\epsilon} \epsilon_0

is the ''complex dielectric permeability''

References

# Hippel A. R. Dielectrics and Waves. – N.Y.: JOHN WILEY, 1954. # Popov V. P. The Principles of Theory of Circuits. – M.: Higher School, 1985, 496 p. (In Russian). # Küpfmüller K. Einführung in die theoretische Elektrotechnik, Springer-Verlag, 1959. Electric and magnetic fields in matter

See also

References