skin effect

In particular, R is heavily influenced by the skin effect.

A cable with twice the diameter will have half the skin effect resistance.

This is one effect of a greater phenomenon called the skin effect.

This phenomenon is usually described as the "skin effect".

However, properties such as core loss and conductor skin effect also increase with frequency.

Local gamma irradiation can cause skin effects without any sickness.

One reason, mentioned above is the skin effect (and the related proximity effect).

Partial coring may be used, if necessary, to eliminate surface skin effects.

Switching power supplies must pay more attention to the skin effect because it is a source of power loss.

As cable conductors increase in diameter they have less overall resistance but increased skin effect.

The difference in flow direction is believed to be a "skin effect" and not due to any deeper atmospheric processes.

Note that in the usual form for the skin effect, above, the effect of cancels out.

It can be difficult to be sure which chemicals are the cause of a subtly perceived skin effect.

Skin effect losses in the conductors can be reduced by increasing the diameter of the cable.

Skin effect is due to eddy currents set up by the AC current.

In addition to the skin effect, there is also a proximity effect, which is another source of power loss.

When larger area conductors are needed, tricks are used to minimize the skin effect.

At high frequencies there are also additional losses in the windings due to proximity and skin effect.

Self-induced eddy currents are responsible for the skin effect in conductors.

At low frequencies (such as the line frequency of 50 or 60 Hz), designers can usually ignore the skin effect.

Like skin effect, this reduces the effective cross-sectional area of the wire conducting current, increasing its resistance.

This effect (the skin effect) is used in antennas.

They include papers on skin effects and coupling between lines ("crosstalk") due to asymmetry.

Even with a low loss dielectric, capacitors are also subject to skin effect losses in their leads and plates.

Thereby, for the wire as a whole, the skin effect and associated power losses when used in high-frequency applications are reduced.