gyrator

It is not essential, however, to have both the transformer and gyrator.

Models like the Gyrator are geared toward skiers who love to ride bumps.

Larger value inductors may be simulated by use of gyrator circuits.

The gyrator is a necessary element in analysis because it is not reciprocal.

Unlike the four conventional elements, the gyrator is non-reciprocal.

A gyrator can be used to transform a load capacitance into an inductance.

The gyrator is useful to simulate the effect of an inductor without using a coil.

The last pair present the gyrator axioms and the middle axiom links the two pairs.

From the governing equations, the instantaneous power into the gyrator is identically zero.

There are many applications where it is not possible to use a gyrator to replace an inductor:

Although a gyrator is characterized by its resistance value, it is a lossless component.

The gyrator, on the other hand, maps a voltage at one port to a current at the other.

A gyrator relates flow to effort.

At low frequencies and low powers, the behaviour of the gyrator can be reproduced by a small op-amp circuit.

In typical applications, both the inductance and the resistance of the gyrator are much greater than that of a physical inductor.

Since gyrators use active circuits, they only function as a gyrator within the power supply range of the active element.

A gyrator's transient response is limited by the bandwidth of the active device in the circuit and by the power supply.

From his mouth gushed the syllables of Phandaal's Gyrator Spell.

An important property of a gyrator is that it inverts the current-voltage characteristic of an electrical component or network.

An ideal gyrator is a linear two port device which couples the current on one port to the voltage on the other and vice versa.

In the circuit shown, one port of the gyrator is between the input terminal and ground, while the other port is terminated with the capacitor.

Although the gyrator was conceived as a fifth linear element, its adoption makes both the ideal transformer and either the capacitor or inductor redundant.

An ideal gyrator is similar to an ideal transformer in being a linear, lossless, passive, memoryless two-port device.

The primary application for a gyrator is to reduce the size and cost of a system by removing the need for bulky, heavy and expensive inductors.

Tellegen invented a circuit symbol for the gyrator and suggested a number of ways in which a practical gyrator might be built.