Wafer (electronics)

The wave impedance of an electromagnetic wave is the ratio of the transverse components of the electric and magnetic fields (the transverse components being those at right angles to the direction of propagation). For a transverse-electric-magnetic (TEM) plane wave traveling through a homogeneous medium, the wave impedance is everywhere equal to the intrinsic impedance of the medium. In particular, for a plane wave travelling through empty space, the wave impedance is equal to the impedance of free space. The symbol Z is used to represent it and it is expressed in units of ohms. The symbol η (eta) may be used instead of Z for wave impedance to avoid confusion with electrical impedance.

The wave impedance is given by

${\displaystyle Z=\frac{E_0^{-}(x)}{H_0^{-}(x)}}$

where ${\displaystyle E_0^{-}(x)}$ is the electric field and ${\displaystyle H_0^{-}(x)}$ is the magnetic field, in phasor representation.

In terms of the parameters of an electromagnetic wave and the medium it travels through, the wave impedance is given by

${\displaystyle Z=\sqrt{\frac{j\omega \mu }{\sigma +j\omega \epsilon }}}$

where μ is the magnetic permeability, ε is the electric permittivity and σ is the electrical conductivity of the material the wave is travelling through. In the equation, j is the imaginary unit, and ω is the angular frequency of the wave. In the case of a dielectric (where the conductivity is zero), the equation reduces to

${\displaystyle Z=\sqrt{\frac{\mu }{\epsilon }}.}$

As usual for any electrical impedance, the ratio is defined only for the frequency domain and never in the time domain.

Wave impedance in free space

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In free space the wave impedance of plane waves is:

${\displaystyle Z_0=\sqrt{\frac{{\mu }_0}{{ϵ}_0}}}$

and:

${\displaystyle c_0=\frac{1}{\sqrt{{\mu }_0{ϵ}_0}}}$

hence, to the same accuracy as the 1983 definition of c, the value in ohms is:

${\displaystyle Z_0={\mu }_0{c}_0=376.730313}$

Wave impedance in an unbounded dielectric

In a perfect dielectric, ${\displaystyle \mu =4\pi \times 10^{-7}}$ H/m and ${\displaystyle \epsilon ={\epsilon }_r\times 8.854\times 10^{-12}}$ F/m. So, the value of wave impedance in a perfect dielectric is

${\displaystyle Z\approx \frac{377}{\sqrt{{\epsilon }_r}}\mathrm{\Omega }}$.

In a perfect dielectric, the wave impedance can be found by dividing Z₀ by the square root of the dielectric constant. In anything else, the formula becomes larger and a complex number is the result.

Wave impedance in a waveguide

For any waveguide in the form of a hollow metal tube, (such as rectangular guide, circular guide, or double-ridge guide), the wave impedance of a travelling wave is dependent on the frequency ${\displaystyle f}$, but is the same throughout the guide. For transverse electric (TE) modes of propagation the wave impedance is

${\displaystyle Z=\frac{Z_0}{\sqrt{1-{\left(\frac{f_c}{f}\right)}^2}}\text{(TE modes)},}$

where f_c is the cut-off frequency of the mode, and for (TM) modes

${\displaystyle Z=Z_0\sqrt{1-{\left(\frac{f_c}{f}\right)}^2}\text{(TM modes)}}$

Above the cut-off (f > f_c), the impedance is real (resistive) and the wave carries energy. Below cut-off the impedance is imaginary (reactive) and the wave is evanescent. These expressions neglect the effect of resistive loss in the walls of the waveguide. For a waveguide entirely filled with a homogeneous dielectric medium, similar expressions apply, but with the wave impedance of the medium replacing Z₀. The presence of the dielectric also modifies the cut-off frequency f_c.

For a waveguide or transmission line containing more than one type of dielectric medium (such as microstrip), the wave impedance will in general vary over the cross-section of the line.

References

Template:FS1037C MS188

See also

• Characteristic impedance
• Impedance (disambiguation)